METHOD DEVELOPMENT, VALIDATION AND

DETERMINATION OF PIOGLITAZONE HCL

WITH SUCRALOSE IN RATS SERUM BY USING

HIGH PERFORMANCE LIQUID

CHROMATOGRAPHY

(HPLC/UV)

By

Lina Nasser Al –Tamimi

Under Supervision of

Prof. Tawfiq Arafat

Dr. Wael Abu Dayyih

A Thesis Submitted in Partial Fulfillment of the Requirements for

the Degree of

Master of Sciences

in Pharmaceutical Sciences

At

University of Petra

Faculty of Pharmacy and Medical Sciences

Amman-Jordan

June-2014

II

Method Development, Validation and Determination of Pioglitazone

HCl with Sucralose in Rats Serum by using High Performance Liquid

Chromatography

( HPLC/ UV)

By

Lina Nasser Al –Tamimi

A Thesis Submitted in Partial Fulfillment of the Requirements for the Degree of

Master of Science

In Pharmaceutical Sciences

At

University of Petra

Faculty of Pharmacy and Medical Sciences

Amman-Jordan

June 2014

Major supervisor

Name signature

Prof. Tawfiq Arafat ................................

Co-Supervisor

Name signature

Dr. Wael Abu Dayyih ................................

Examination Committee

Name signature

Dr. Eyad Al Mallah .................................

Dr. Nidal Al Qinnah .................................

Prof. Maher Lutfi Saleem .................................

III

Acknowledgment

I would like to express my special appreciation and thanks to my major supervisor Prof.

Tawfiq Arafat and my co-supervisor Dr. Wael Abu Dayyih, who have been tremendous

mentors for me. I would like to thank them for encouraging my research and for allowing

me to grow as a research scientist. I would also like to thank my committee members, Dr.

Eyad Al Mallah and Dr. Nidal Al Qinnah for offering all supportive needs and serving as

my committee members. I also want to thank Prof. Maher Saleem (president of Middle

East University) for his brilliant comments and suggestions and for being an external

examiner at my committee. I would like to thank Enas Al Qasem and Jumana Al Qasem

for their help and support too.

A special thanks to my family. Words cannot express how grateful I am to my parents,

thank you dad (mercy upon you), your prayer for me was what sustained me thus far. I

would like also to thank my husband Eng. Sami Nazzal and my kids who had supported

me and donated me the strength that I needed every moment to keep on my way strongly.

I would like to thank my brothers, Eng. Bader Al Tamimi, Ghassan Al Tamimi, Eng.

Tamim Al Tamimi , Bilal Al Tamimi and Chef. Yazan Al Tamimi for their infinite

encouragement, my aunt who helped me to surpass any obstacle and keep going toward

the best. I would like to thank all my friends, the best friends who supported me and

encouraged me to achieve my goal, especially Dr. Hanan Al Hourani for her distinctive

support and amiable heart.

IV

ABSTRACT

Method Development , Validation and Determination of Pioglitazone HCl with

Sucralose in Rats Serum by using High Performance Liquid Chromatography

( HPLC/ UV)

By

Lina Nasser Al -Tamimi

University of Petra, 2014

Supervisor Co-supervisor

Prof. Tawfiq Arafat Dr. Wael Abu Dayyih

A new simple, rapid, sensitive and validated method for quantification of pioglitazone

HCl in the presence of sucralose has been carried out using High Performance Liquid

Chromatography –Ultra Violet ( HPLC-UV) spectroscopy in rats serum. Mobile phase

was consisted of (51.50%) acetonitrile and (48.50%) 0.025 mM ammonium acetate with

pH of 8 , column of separation was C8 at temperature of 40 C° using injection volume of

90 µl , mobile phase flow rate was 1 ml/min and samples run time was 10 min, the

signals were monitored and analyzed at λ= 269 nm and sildenafil citrate was used as

internal standard. Overall intra-day precision and accuracy were reasonable with CV %

values range (0.16-3.54) and accuracy % range ( 98.4-107.9), while inter-day precision

and accuracy showed accepted precision with CV% range ( 0.15- 4.13) and accuracy %

range (99.35-103.99). The coefficient of correlation was 0.9991 with reasonable

sensitivity and selectivity. Over all combination effect was considerable as the serum

concentrations of pioglitazone in presence of sucralose showed a significant decrease

during all time intervals of samples pooling after pioglitazone oral administration

according to statistical analysis results, while the difference between the area under the

curve of pioglitazone time profile in presence and absence of sucralose also illustrated a

significant combination effect referring to data statistical analysis results.

V

The statistical significance seen in the combination results could be justified by the

induction effect of sucralose over the CYP3A4 liver metabolic enzyme in rats by which

pioglitazone is extensively metabolized.

Further clinical research is warranted to investigate the extent of pioglitazone-sucralose

combination interaction in humans.

VI

TABLE OF CONTENTS

No.

Subject

Page

No.

I

Chapter One : Introduction

1

1 Introduction 2

1.1 Diabetes Mellitus 2

1.2 Type 1 Diabetes Mellitus 3

1.3 Type 2 Diabetes Mellitus 3

1.4 Gestational Diabetes Mellitus (GDM) 5

1.5 Oral Antidiabetics 5

1.5.1 Insulin Sensitizers 5

1.5.2 Insulin Secretagogues 6

1.5.3 Alpha Glucosidase Inhibitors 7

VII

1.5.4 Incretin Based Therapies 7

1.6 DM Treatment Protocols 8

1.6.1 DM Type 1 Therapy 8

1.6.2 DM Type 2 Therapy 9

1.6.2.1 DM Type 2 Monotherapy 9

1.6.2.2 DM Type 2 Combination Therapy 9

1.7 Thiazolidinediones 11

1.8 Pioglitazone HCl 11

1.8.1 Pioglitazone HCl Absorption 14

1.8.2 Pioglitazone HCl Pharmacokinetics 14

1.8.3 Pioglitazone HCl Distribution 14

1.8.4 Pioglitazone HCl Metabolism 15

VIII

1.8.5 Pioglitazone HCl Excretion and Elimination 16

1.8.6 Pioglitazone HCl Adverse Reactions 16

1.8.7 Drug-Drug Interaction 17

1.8.8 Drug Metabolism and Cytochrome P450 Enzymes 18

1.8.9 Pioglitazone – Drug Interaction 20

1.8.10 Determination of Pioglitazone HCl in Pharmaceutical Preparations and

Biological Fluids( Literature Survey)

22

1.9 Sucralose 24

1.9.1 Sucralose Manufacturing 25

1.9.2 Sucralose Brand Names 25

1.9.3 Sucralose Pharmacokinetics and Metabolism 26

1.9.4 Artificial Sweeteners – Drug Interactions 26

1.10 High Performance Liquid Chromatography (HPLC) Method 27

IX

1.10.1 HPLC Definition and Principle 27

1.10.2 Types of HPLC 29

1.10.2.1 Normal Phase HPLC 29

1.10.2.2 Reversed Phase HPLC 25

1.10.2.3 Methods of Detection 29

1.10.3 Internal Standard 31

1.10.4 HPLC Instrument Calibration 31

1.10.5 Bioanalytical HPLC Method Validation Parameters Definitions ( EMEA) 32

1.10.5.1 Precision 32

1.10.5.2 Accuracy 32

1.10.5.3 Linearity 33

1.10.5.4 Range 34

X

1.10.5.5 Ruggedness 34

1.10.5.6 Limit of Detection 35

1.10.5.7 Lower limit of Quantification 35

1.10.5.8 Selectivity 35

1.10.5.9 Sensitivity 36

1.10.5.10 Recovery 36

1.10.5.11 Stability 37

1.11 Aim of the Study 39

II Chapter Two : Experimental Part 40

2 Experimental Part 41

2.1

Reagents

41

2.2

Instrumentation

42

XI

2.3

Preclinical Study

44

2.4

Preparation of Stock Solutions and Working Solutions

46

2.4.1 Preparation of Pioglitazone HCl Oral Solution 46

2.4.2

Preparation of Sodium Hydroxide Solution

46

2.4.3

Preparation of Sucralose Oral Solution

47

2.4.4

Preparation of Pioglitazone HCl Stock Solution

47

2.4.5

Preparation of Pioglitazone HCl Serial Dilutions in Methanol

48

2.4.6

Preparation of Pioglitazone HCl Standard Solutions in Serum( QC

Solutions)

49

2.4.7

Preparation of Mobile Phase

50

2.4.8

Preparation of Buffer Solution

50

2.4.9

Preparation of Internal Standard Stock

50

XII

2.4.10

Solution Preparation of Internal Standard Working Solution

50

2.4.11

Sample Preparation ( Extraction Procedure)

51

2.4.12

Method Development (Chromatographic Conditions )

51

2.5

Method Validation

54

2.5.1

Inter-day Accuracy and Precision

54

2.5.2 Intra-day Accuracy and Precision 55

2.5.3

Selectivity and Sensitivity

56

2.5.4

Linearity

56

2.5.5

Recovery

57

2.5.6

Stability

57

2.6

Statistical Analysis

59

XIII

III

Chapter Three : Results and Discussion

62

3

Results and Discussion

63

3.1

Method Validation

63

3.1.1

Inter-day Precision and Accuracy

63

3.1.2

Intra-day Precision and Accuracy

69

3.1.3

Linearity

71

3.1.4

Selectivity and Sensitivity

79

3.1.5

Recovery

84

3.1.6

Stability

87

3.2

Sucralose - Pioglitazone HCl Combination Effect on Pioglitazone HCl

Serum Levels

99

XIV

IX

Chapter Four : Conclusion

117

4.1

Conclusion

118

4.2

Appendix : Chromatograms

119

4.3 References 133

4.5 Abstract in Arabic 151

LIST OF FIGURES

Figure

No.

Caption Page

No.

1.

Pioglitazone HCl Structural Formula

12

2.

Sucralose Structural Formula

25

3.

Calibration 1

72

4.

Calibration 2

73

XV

5.

Calibration 3

74

6.

Calibration 4

75

7.

Calibration 5

76

8.

Calibration 6

77

9.

Long Term Stability Day 30 Calibration Curve

97

10.

First Day Trials Calibration Curve

100

11.

First Day Trial Serum – Plasma Time Profile Curve

101

12.

Second Day Trial Serum – Plasma Time Profile Curve

103

13.

Third Day Trial Serum – Plasma Time Profile Curve

104

14.

Dot Diagram with Error Bars for Mean Comparison of Pioglitazone HCl

Serum Concentration after 30 minutes of Drug Administration

106

15.

Dot Diagram with Error Bars for Mean Comparison of Pioglitazone HCl

Serum Concentration after 1 hour of Drug Administration

107

XVI

16.

Dot Diagram with Error Bars for Mean Comparison of Pioglitazone HCl

Serum Concentration after 2 hours of Drug Administration

108

17.

Dot Diagram with Error Bars for Mean Comparison of Pioglitazone HCl

Serum Concentration after 3 hours of Drug Administration

109

18.

Dot Diagram with Error Bars for Mean Comparison of Pioglitazone HCl

Serum Concentration after 4 hours of Drug Administration

110

19.

Dot Diagram with Error Bars for Mean Comparison of Pioglitazone HCl

Serum Concentration after 6 hours of Drug Administration

111

20.

Dot Diagram with Error Bars for Mean Comparison of Pioglitazone HCl

Serum Concentration after 8 hours of Drug Administration

112

21.

Dot Diagram with Error Bars for Mean Comparison of Pioglitazone HCl

Serum Concentration after 24 hours of Drug Administration

113

22.

Serum Concentration – Time Profile Graph ( 0-24) Hours of Oral

Administration of Drug,( PG = Pioglitazone HCl alone , PG Plus =

Pioglitazone HCl with Sucralose)

114

23.

Serum Blank Chromatogram with IS

119

24.

Serum Blank Chromatogram 1

120

25.

Serum Blank Chromatogram 2

121

26.

Serum Blank Chromatogram 3

122

XVII

27.

Serum Blank Chromatogram 4

123

28.

Serum Blank Chromatogram 5

124

29.

Serum Blank Chromatogram 6

125

30.

Piolitazone LLOQ Chromatogram ( Peak 1 for Pioglitazone HCl , Peak 2

for IS)

126

31.

Pioglitazone HCl QCL Chromatogram ( Peak 1 : Pioglitazone HCl, Peak 2

: IS)

127

32.

Pioglitazone HCl QCM Chromatogram ( Peak 1 : Pioglitazone HCl, Peak 2

: IS)

128

33.

Pioglitazone HCl QCH Chromatogram ( Peak 1 : Pioglitazone HCl, Peak 2

: IS)

129

34.

Pioglitazone HCl Zero Concentration with IS Chromatogram (Peak 2 :IS)

130

35.

Pioglitazone HCl Unknown Concentration Chromatogram after 30 minutes

Oral Administration ( Pioglitazone HCl : Peak 1 , IS : Peak 2 )

131

36.

Pioglitazone HCl Unknown Concentration Chromatogram after 3 hours of

Oral Administration ( Peak 1 : Pioglitazone HCl , Peak 2 : IS )

132

XVIII

LIST OF SCHEMES

Scheme

No.

Caption Page No.

1. PPARs Functions 10

2. HPLC Flow 28

3. UV Detector Detection Pathway 30

LIST OF TABLES

Table

No.

Caption Page No.

1. Pioglitazone HCl – Drugs Interactions 21

2. Sildenafil Citrate Information ( Internal Standard ) 42

3. Pioglitazone HCl Serial Dilutions in Methanol 48

4.

Pioglitazone HCl QC Standard Solutions in Serum

49

5.

Chromatographic and Detection Conditions

53

6.

Concentrations Used for Method Validation

54

7.

Inter- day Precision and Accuracy : Day 1

66

XIX

8. Inter- day Precision and Accuracy : Day 2 67

9.

Inter- day Precision and Accuracy : Day 3

68

10.

Intra- day Precision and Accuracy

70

11.

Linearity Calibration 1 Data 72

12.

Linearity Calibration 2 Data 73

13.

Linearity Calibration 3 Data

74

14.

Linearity Calibration 4 Data

75

15.

Linearity Calibration 5 Data

76

16.

Linearity Calibration 6 Data

77

17.

LLOQ Sensitivity Data

80

18.

QCL Sensitivity Data

81

19.

QCM Sensitivity Data

82

20.

QCH Sensitivity Data

83

21.

Pioglitazone HCl Recovery Data

85

XX

22.

Internal Standard Recovery Data

86

23.

Freeze and Thaw Stability Data

91

24.

Room Temperature Stability Data for Pioglitazone HCl in Serum

93

25.

Room Temperature Stability Data for Pioglitazone HCl in

Stock/Working Solution

94

26.

Room Temperature Stability Data for Internal Standard in

Stock/Working solution

94

27.

Long Term Stability Day 30 Calibration Data

97

28.

Long Term Stability Data of Pioglitazone in Serum

98

29.

Long Term Stability Data of Pioglitazone in Stock/Working Solution

98

30.

Long Term Stability Data of Internal Standard in Stock/Working

Solution

99

31. First Day Trials Calibration Curve Data

100

32. First Day Trial Serum Data 101

33. Second Day Trial Serum Data 103

XXI

34. Third Day Trial Serum Data 104

35. Serum Data Statistical Analysis Results 105

36. Serum Concentration – Time Profile Kinetic Parameters 115

ABBREVIATIONS

ADI Approved Daily Intake

AUC Area Under The Curve

BW By Weight

CL Clearance

Conc. Concentration

CPK Creatine Phosphokinase

CV Coefficient of Variation

XXII

CVD Cardiovascular Diseases

CYP Cytochrome P

D Day

DM Diabetes Mellitus

DPP-4 Dipeptidyl peptidase-4

EMEA European Medicines Agency

F Bioavailability

FDA Food and Drug Administration

GIT Gastrointestinal Tract

GLP-1 Glucagon-Like Peptide-1 Receptor Agonist

Gm Gram

HbA1c Hemoglobin A1c Subtype

XXIII

HCL Hydrochloric Acid

HDL High Density Lipoprotein

HPLC High Performance Liquid Chromatography

IS Internal Standard

IUPAC International Union of Pure and Applied

Chemistry

Kg Kilogram

KOH Potassium Hydroxide

L Liter

LC-MS Liquid Chromatography – Mass Spectroscopy

LLOQ Lower Limit Of Quantification

LOD Limit Of Detection

XXIV

LOQ Limit Of Quantification

MCP Mytochondrial Pyruvate Carrier

mM Milimolar

Mwt Molecular Weight

NaOH Sodium Hydroxide

PG Pioglitazone HCL

PG Plus Pioglitazone HCl Plus Sucralose

P-gp P Glycoproteins

PPARs Peroxisome Proliferator-Activated Receptors

QC Quality Control

QCH Quality Control High Concentration

QCL Quality Control Low Concentration

XXV

QCM Quality Control Medium Concentration

R² Regression Factor

RF Rate of Flow

S.C Subcutaneous

SD Standard Deviation

SOPs Standard Operating Procedures

St Standard Solution Concentration

TZDs Thiazolidinediones

RT Room Temperature

UKPDS United Kingdom Prospective Diabetes Study

USFDA United States Food and Drug Administration

UV Ultra Violet

XXVI

Vd Volume of Distribution

WHO World Health Organization

Wt Weight

1

CHAPTER ONE

INTRODUCTION

2

1. Introduction

1.1 Diabetes Mellitus

Diabetes mellitus is defined as a metabolic disorder of multiple etiologies,

characterized by hyperglycemia associated with alterations of carbohydrate, protein

and fat metabolism as a result of defect in insulin secretion and/or insulin activity

(Alberti and Zimmet, 1998).

The long term of diabetes mellitus consequences include: damage, dysfunction and

failure of various organs (Wolff, 1993; Turner et al,. 1998). Diabetes mellitus may

present with severe symptoms such as polyuria, thirst, weight loss and blurred vision

(Nathan, 1993). In severe forms, it may develop which may lead to coma and finally

death (Seshasai et al., 2011).

World Health Organization (WHO) has estimated that there are around 220

millions of diabetics around the world. Diabetes is responsible of 1.5 million of death

cases, the figure could be doubled till 2030. This disease is increasingly distributed in

the world which forces the health organizations to consider it as a critical warning that

needs a serious attention to avoid any possible threats in the future. World Health

Organization (WHO) has recognized and classified three forms of Diabetes mellitus:

type 1, type 2 and gestational diabetes (WHO 2010).

Diabetes is firstly classified as type 1 and type 2 by Sir Harold Pervival (Hary)

Himsworth and it was published in January 1936 (Himsworth, 2011).

The other subtypes of diabetes include: gestational diabetes and diabetes due to

any secondary specific cause.

3

1.2 Type 1 Diabetes Mellitus

Type 1 diabetes mellitus is primarily and specifically occur due to the loss of beta

cells at islets of Langerhans in pancreas which leads to insulin deficiency as a

consequence (Meier et al., 2005), but it can be also classified as idiopathic or

immune-mediated disease as the body immune system performs a defense mechanism

against beta cells causing its death (Rother, 2007).Type 1 diabetes can occur in both

children and adults which justifies the publically nomination of "juvenile diabetes”

because it is majorly founded in children.

Patient diagnosis with symptoms of hyperglycemia (polyuria, thirst and weight

loss) can be proceeded with a single random serum glucose test with result of 200

mg/dl or higher, without any need of measurement repetitions (Gavin et al., 1997).

It is considered as immune mediated disease in more than 90% of cases, and it is

mediated with unknown causes in less than 10% of cases (Kukreja et al., 2002).

The most serious and apparent symptoms are: rapid breathing, dryness of skin and

mouth, flushed face, fruity acetone like breath odor, nausea or vomiting, frequent

urination and stomach pain (Daneman, 2006).

It is effectively managed using insulin in order to control serum glucose levels due

to insufficient insulin levels in blood stream.

1.3 Type 2 Diabetes Mellitus

Type II diabetes mellitus is considered as a chronic endocrinal disease, which is

defined as a metabolic disorder (complex) characterized by hyperglycemia due to

inappropriate insulin secretion and action associated with insulin resistance in which

4

normal levels of insulin do not activate the glucose absorption signal (DeFronzo, 1999

; Scheen, 2007).

A high rate of glucose production by liver associated with hyperinsulinemia case

is the primary essential reason of fasting hyperglycemia incidence. After a meal,

impaired inhibition of hepatic glucose production by insulin and a decrease in the rate

of insulin-glucose uptake by muscles contribute equally to postprandial

hyperglycemia (Genuth et al., 2003).

Disease development usually occur due to genetic and environmental factors such

as high calorie diet and unhealthy lifestyle with mentionable low physical activity

(Hu et al., 2001 ; Tuomilehto et al., 2001).

Unfortunately, it can be unnoticed for years because of its invisible symptoms

which are non-existent and typically mild.

In United States, five classes of oral agents with different mechanism of action for

each, are currently available to improve glycemic control in patients with type 2

diabetes (Levetan, 2007).

A recent study that done by (UKPDS) has shown that type 2 diabetes mellitus is a

progressive disorder that can be treated initially with oral agent monotherapy but will

require an additional different oral agents, and usually in many patients, insulin

therapy will be needed to achieve targeted blood glucose levels (Miyazaki et al.,

2001; Genuth et al., 2003).

5

Glycemic control, regardless of the agent that is used will decrease the incidence

of several vascular complications such as: retinopathy, neuropathy, and nephropathy

(Patel et al., 2008).

1.4 Gestational Diabetes Mellitus

Gestational diabetes mellitus is strongly resembles Type 2 Diabetes Mellitus in

involving inadequate insulin secretion and response. Gestational diabetes is

characterized by high blood sugar levels during pregnancy in a woman without

previously diagnosed diabetes (Bellamy et al., 2009).

It is considered as a degree of glucose intolerance either with onset or during

pregnancy ( Buchanan and Xiang, 2005), treatable with appropriate medicines while

in 50% of women it may developed into Type 2 Diabetes Mellitus in future, if it is

neither treated nor controlled carefully (Langer et al., 2005).

1.5 Oral antidiabetics

Many oral antidiabetics are used either as a single or combination of two or more

antidiabetic according to diabetes type, blood glucose controlling factors. (Meltzer et

al., 1998 ; Krentz and Bailey, 2005). Healthy daytime blood sugar levels before meals

(fasting) is (80 - 120 mg/dl) and (100 - 140 mg/dl) at bedtime.

The most widely used antidiabetics are:

1.5.1 Insulin Sensitizers

This class of type 2 diabetes medications includes biguanides and thiazolidinediones.

6

Biguanides is a class of medication that is used for treatment of diabetes type 2.

Metformin is the only currently available biguanide which control the blood glucose

levels in type 2 diabetics by decreasing hepatic glucose output and increasing glucose

utilization in peripheral tissues including muscles and liver tissues via the activation

of AMP-protein kinase enzyme (Klip and Leiter, 1990 ; Bailey, 1992 and Miller et al.,

2013).

Thiazolidinediones (TZDs) are peroxisome proliferator-activated receptor gamma

(PPARγ) agonists, this class of type 2 diabetes has its pharmacological effect through

the enhancement of insulin receptors sensitivity in muscle, fat and liver tissues

(Diamant and Heine, 2003 ; Nathan et al., 2006).

1.5.2 Insulin Secretagogues

This class of medications includes sulfonylureas and glinides drugs subclasses.

The first insulin secretagogues used were sulfonylureas, its hypoglycemic effect

was discovered in Montpellier in 1945. sulfonylureas stimulate insulin secretion by

pancreatic beta cells via sensitizing them to glucose blood levels.

Sulfonylureas bind to plasma membrane sulfonylurea receptor, activation of these

receptors inhibits (ATP-sensitive K+ channels) that yields in cellular depolarization,

as a result, voltage-dependant calcium channels will be opened which leads to insulin

secretion.

On the other hand, sulfonylureas can inhibit glucagon secretion and enhances

tissues insulin sensitivity.

7

Sulfonylureas second generation members are: glipizide, glibenclamide, gliclazide,

glibornuride and glimepiride, while the first generation drugs are: tolbutamide,

chlorpropamide and carbutamide.

Glinides are compounds of insulin secretion activation activity. Their

hypoglycemic effect is faster than sulfonylureas.

Glinides available drugs are: nateglinide and repaglinide, this antidiabetic class has

an antihyperglycemic action through blocking ATP-regulated K channels leading to

depolarization and Ca influx and finally, insulin release from pancreatic beta cells will

be achieved (Luna et al., 1999 ; Malaisse, 2003).

1.5.3. Alpha Glucosidase Inhibitors

This class of type 2 antidiabetics includes: acarbose and miglitol (Van de Laar et

al., 2005), which helps to control the normal blood glucose levels in type 2 diabetics

by inhibition of intestinal alpha-glucosidase enzyme and a weak effect on pancreatic

alpha-amylase causing a reduction of monosaccharides production and absorption at

the small intestine (Ye F et al., 2003).

1.5.4. Incretin Based Therapies

This type of diabetes type 2 therapy is majorly depends on the use of two recently

approved classes: glucagon-like peptide-1 receptor agonists (GLP-1) and dipeptidyl

peptidase-4 inhibitors (DPP-4) (Drucker, 2010).

Sitagliptin, saxagliptin, and sinagliptin (approved in 2011 and are not available

yet) are oral DPP-4 inhibitors while exenatide and liraglutide are injectable GLP-1

analogs.

8

Incretin based therapies mechanism of action could be described as a potentiation

of incretin receptor signaling, as inhibition of DPP-4 enzymes will lead to an increase

in incretin and GLP-1 levels, which enhances the release of insulin and decrease the

glycogen secretary levels.

1.6 DM Treatment Protocols

1.6.1 DM Type 1 Therapy

Treatment Guidelines: (Rodbard et al., 2007).

1. Controlling of blood glucose levels as follows:

Before meals = 70–120 mg/dL

2 hours post-meals = 160 mg/dL

Bed time = 70–120 mg/dL

2. Diet and physical activity.

3. Weight management.

4. Foot care.

Insulin is the first line of treatment, it is available as S.C (subcutaneous) injections

( Fonseca and Kulkarni, 2008). Insulin types are: rapid-acting insulin, intermediate

and long-acting insulin.

9

1.6.2 DM Type 2 Therapy

1.6.2.1 DM Type 2 Monotherapy

DM type 2 monotherapy line includes: metformin, thiazolidinediones (Tan, 2000),

secretagogues, dipeptidyl-peptidase 4 inhibitors and alpha-glucosidase inhibitors

(Bennett et al., 2011).

1.6.2.2 DM type 2 Combination Therapy

Combination Therapy of DM Type 2 includes the following: (Yki-Järvinen, 2001)

Secretagogue + metformin

Secretagogue + thiazolidinedione (Kipnes et al., 2001).

Secretagogue + alpha-glucosidase inhibitor

Thiazolidinedione + metformin (Einhorn et al., 2000).

Dipeptidyl-peptidase 4 inhibitor + metformin

Dipeptidyl-peptidase 4 inhibitor + thiazolidinedione

Secretagogue + metformin + thiazolidinedione

1.7 Thiazolidinediones:

A group of potent synthetic PPAR ligands, effectively used in treatment of DM

type 2 (Nathan, 2009). These ligands have their glucose lowering effects through

mediation of insulin sensitivity in skeletal muscles (Yki-Järvinen, 2004 ; Scheen,

10

2007) and facilitating glucose uptake by binding to the PPARγ receptors ( Divakaruni

et al., 2013).

The peroxisome-proliferator–activated receptors (PPARs) are a subfamily of 48-

member nuclear-receptor which regulates gene expression as response to ligand

binding (Nathan, 2002), three types of PPARs: PPARα, PPARβ and PPARγ have

been identified to date (Braissant et al., 1996).TZDs are potent synthetic PPAR

ligands, it as it is predominantly distributed and expressed mostly in adipose tissue but

is also found in pancreatic beta cells, vascular endothelium and macropages, as shown

in scheme 1(Radhika et al., 2012).

Scheme 1: PPARs Functions

11

TZDs group members are: pioglitazone, rosiglitazone, troglitazone and

rivoglitazone.To date, the only available drugs are pioglitazone and rosiglitazone.

In January 1997, the first thiazolidinedione; troglitazone, was approved for patients

with type 2 diabetes in the United States. (FDA 1999 ; Scheen, 2007).

In March 2000, troglitazone was subsequently withdrawn from the market because

of its hepatotoxicity side effect (Diamant and Heine, 2003). The two currently

available PPARγ agonists, rosiglitazone and pioglitazone were approved in the United

States in 1999 and still be used up to date.

Patients with type 2 diabetes have an increased bladder cancer risk of 40%

(Colmers et al., 2012 ; Chapman, 2013), thiazolidinediones, especially pioglitazone

can increase this risk, but recently, a systematic review was carried out to evaluate the

bladder cancer risk with type 2 diabetics taking thiazolidinediones, the result was with

limited evidence to support this claim concerning (Clomers et al., 2012 ; Wei et al.,

2013; Bosetti et al., 2013).

1.8 Pioglitazone

Pharmacological review: it is a compound that belongs to a group named

“thiazolidinediones” family, an oral antidiabetic agent that acts by decreasing insulin

resistance (Nissen, 2007). Pioglitazone has the same mechanism of action by which

all thiazolidinediones act inside the body.Its mechanism of action made it as one of

the most effective drugs that is used in the management of type 2 diabetes mellitus

(Grossman, 2001 ; Chilcott et al., 2001), pioglitazone was marketed at USA in 1999,

nowadays, it is marketed in more than 40 countries worldwide (Sohda et al., 2002).

12

Several pharmacological studies accentuated that pioglitazone can improve the

sensitivity to insulin in muscle and adipose tissue (Smith , 2001 ; Pavo et al., 2003)

which helps in hepatic gluconeogenesis inhibition (Tan, 2000) and improves glycemic

control by reducing circulating insulin levels, (Haffner et al., 1999 ; Aronoff et al.,

2000 ; Richter et al., 2006).

Pioglitazone monotherapy is an alternative to metformin monotherapy if

metformin cannot be used (either for intolerance or for contraindications), it is also

used as a combined therapy if monotherapy with metformin is insufficient to achieve

the required HbA1c blood glucose level target, or as a tripled therapy line with other

oral antidiabetics as a complementary treatment thus, pioglitazone HCl is still

considered as effective and useful antidiabetic drug with a efficient insulin-sensitizing

action. However, the therapeutic use of pioglitazone HCl is still under monitoring and

control because of conflicting safety issues and newer drugs availability such as DPP-

4 inhibitors, glucagon-like peptide-1 receptor agonists, and sodium glucose co-

transporter 2 inhibitors, even though, none of these new drugs affects or targets

insulin resistance.

Recent studies approved that insulin-resistant patients with increased waist

circumference, low HDL cholesterol level, fatty liver or with a high risk of CVD are

almost best treated with pioglitazone (Schernthaner et al., 2013).

Physical and chemical properties: pioglitazone: [ (±)-5-[ [4-[2- (5-ethyl-2-

pyridinyl) ethoxy] phenyl] methyl] -2, 4-] thiazolidinedione monohydrochloride

(Radhika et al., 2012), it belongs to a different chemical class with different

pharmacological action than the sulfonylureas, metformin, or the α-glucosidase

inhibitors (Smith, 2001).The structural formula is as shown in figure 1.

13

Figure 1: Pioglitazone HCl Structural Formula

Pioglitazone hydrochloride is a weak acid salt of pioglitazone, organic

compound; benzoids super class of phenol ethers (Picha and Zhu, 2007), odorless

white crystalline powder with molecular formula of C19H20N2O3S•.HCl and

molecular weight of 392.90 daltons (Takeda Canada, Inc. 2012).

Chemical properties: it is soluble in dimethylformamide and dimethyl sulfoxide,

Methanol, chloroform and acetonitrile (Brahmaiah and Raju, 2012), practically

insoluble in water and ether (Lawrence, 2001).

Preparations: Tablets: 15, 30 and 45 mg with brand names of: Actos®, Glustin

®

and Actost®,

while other brand names of combination are: Actoplus Met®

(containing metformin and pioglitazone HCl), Actoplus Met®

XR (containing

metformin and pioglitazone HCl), Duetact® (containing glimepiride and

pioglitazone HCl).

Stability and storage: stable under ordinary conditions, tablets should be kept at

room temperature, 15-30°C (59-86°F) (Takeda Canada, 2012).

14

1.8.1 Pioglitazone HCl Absorption

Following oral administration in fasting, pioglitazone HCl is first measurable in

serum within 30 minutes, with peak concentrations observed within 2 hours, its site of

absorption is stomach ,food slightly delays peak serum concentration time to (3 – 4)

hours, but does not alter the extent of absorption (Budde et al., 2003).

1.8.2 Pioglitazone HCl Pharmacokinetics

Serum concentrations of total pioglitazone HCl (pioglitazone HCl plus active

metabolites) remain elevated 24 hours after once daily dosing. Steady-state serum

concentrations of pioglitazone HCl are achieved within 7 days (Nathan, 2009).

At steady-state, two of the pharmacologically active metabolites of pioglitazone

HCl: M-III and M-IV can reach serum concentrations equal to or greater than

pioglitazone HCl in healthy and type 2 diabetic rats and human (Shah and Mudaliar,

2010 ; Aquilante et al., 2013), pioglitazone HCl involves approximately 30% to 50%

of peak serum concentrations and 20% to 25% of the total area under the serum

concentration-time curve (Eckland and Danhof,

2000).

Bioavailability of pioglitazone HCl in rats serum is about 50% (Umathe et al.,

2008) while clinical studies had indicated a higher bioavailability of pioglitazone HCl

in human serum about 80% (Tornio et al., 2008).

1.8.3 Pioglitazone HCl Distribution

The mean apparent volume of distribution (Vd/F) of Pioglitazone HCl following

single oral dose of administration is 0.63 ± 0.41 (mean ± SD) L/kg of body weight. It

is extensively protein bound (> 99%) in human serum, principally to serum albumin

15

and also binds to other serum proteins too, but, with lower affinity. Metabolites M-III

and M-IV are also extensively bound (> 98%) to serum albumin (Budde et al., 2003).

1.8.4 Pioglitazone HCl Metabolism

Pioglitazone HCl is extensively metabolized by hydroxylation and oxidation via

liver CYP450 enzymatic system (Jaakkola et al., 2006), in vitro data emphasized that

multiple CYP isoforms are involved in pioglitazone HCl metabolism, mostly:

CYP2C8 and CYP3A4 (Tornio et al., 2008 ; Holstein et al., 2012).

Pioglitazone HCl metabolites M-II & M-IV (hydroxy derivatives of pioglitazone

HCl) and M-III (keto derivative of pioglitazone HCl) are pharmacologically active in

animal models of type 2 diabetes ( Tanis et al., 1996 ; Scheen, 2007), M-III and M-IV

are the principal drug-related species found in human serum following multiple

dosing (Muschler et al., 2009).

P-glycoprotein (P-gp) is a trans-membrane efflux pump, which can extrude many

drugs from the cell. It was suggested that CYP3A4 function is complementary to P-gp

function through gastrointestinal tract, CYP3A4 is a prevalent CYP3A type that

mostly expressed in the gastrointestinal tract (Canaparo et al., 2007).

Interaction between enzymes that responsible for drug metabolism and active

transporters is a substantial concept of drug pharmacokinetics. In gastrointestinal tract

mucosa; P-glycoprotein and cytochrome P450 (CYP)3A may interact via three

mechanisms(Christians et al., 2005):

1- Drugs are continuously taken up and pumped out of the enterocytes by P-

glycoprotein which increases drugs metabolism probability.

16

2- P-glycoprotein keeps intracellular concentrations of drug within the linear range of

CYP3A metabolizing capacity.

3- P-glycoprotein transports drug metabolites formed in the mucosa back into lumen

mucosa.

1.8.5 Pioglitazone HCl Excretion and Elimination

Following oral administration, 15% to 30% of pioglitazone HCl dose is retrieved

in urine. Renal elimination of pioglitazone HCl is negligible as it is excreted primarily

in forms of metabolites and their conjugates into the bile followed by elimination in

feces.

The mean serum half-life of pioglitazone HCl and total pioglitazone HCl ranges

from 3 to 7 hours and 16 to 24 hours, respectively. Pioglitazone HCl has an apparent

clearance of CL/F = 5 - 7 L/hr (Radhakrishna et al., 2002).

1.8.6 Pioglitazone HCl Adverse Reactions

The most common include: weight gain and upper respiratory tract infection, but

the less common adverse reactions are: edema, headache, fatigue, hypoglycemia,

anemia, sinusitis and pharyngitis (Shah and Mudaliar, 2010), serious life threatening

adverse reactions are: CHF, dyspnea, hepatic failure and hepatitis (Padwal, 2008 ;

Takeda Canada, Inc. 2012).

17

1.8.7 Drug– Drug Interaction

Drug interactions are very important concept in clinical research and therapeutic

drug treatment. Drug interactions can lead to many serious side effects which forces

health authorities to: terminate drug use, refuse drug approval and withdraw it from

markets (Bjornsson et al., 2003). Therefore, clinicians, pharmaceutical industries and

regulatory authorities have increased and still the attention to drug-drug interactions.

There are a number of drugs interaction mechanisms: pharmacokinetic and

pharmacodynamic interactions. In pharmacokinetic drug interactions a drug affects

the absorption, distribution, metabolism, or excretion of another drug while in

pharmacodynamic drug interactions two drugs have additive or antagonistic

pharmacologic effects (Ho and Kim, 2005).

Pharmacokinetic Drug Interactions

Inhibition of absorption: where the drugs act as binding agents which impair the

bioavailability of other drugs which will result in a reduction in the therapeutic effect

of the desired drug, in some cases, the amount of these drugs that is absorbed from the

gut may be increased or decreased by drugs that increase stomach pH.

Enzyme inhibition: as most drugs are metabolized to either inactive or less active

metabolites by liver and intestine enzymes, inhibition of this metabolism can increase

the effect of the required drug which may result in drug toxicity. This is one of the

most commonly observed clinically important mechanisms of interactions (Tanaka,

1998).

A small number of drugs are administered to patients in inactive forms. These

drugs are known as prodrugs which require activation by body enzymes in order to

18

produce their effect. Inhibition of these prodrugs metabolism may reduce the amount

of active drug and decrease the desired therapeutic effect.

Enzyme induction: as some drug are called enzyme inducers, they are capable of

increasing the drug metabolizing enzymes activity which results in a decrease in the

therapeutic effect of other drugs.

Some drugs are biotransformed into toxic metabolites by metabolizing enzymes,

enzyme inducers can increase the formation of drug toxic metabolites and increase the

hepatotoxicity risk which may lead to other organs damage (Zhou et al., 2003).

Altered renal elimination: some drugs are actively secreted into the renal tubules as

a route of elimination, any drug that may alter the renal elimination of other drug

could lead to drug toxicity (Shitara Y et al., 2005).

Pharmacodynamic Drug Interactions

Additive effects: which occurs when two or more drugs with similar

pharmacodynamic effects are given concurrently, the additive effects may result in

excessive response and toxicity.

Antagonistic effects: when drugs with opposing pharmacodynamic effects are

administered concurrently, combination may lead to reduction in the response to one

or both drugs (Eschenhagen T, 2000).

1.8.8 Drug Metabolism and Cytochrome P450 Enzymes

Liver is the major site of drug metabolism. Metabolism could inactivate drugs,

while some drug metabolites are pharmacologically active more than the parent drug.

19

Drugs are usually metabolized by oxidation, reduction, hydrolysis, hydration,

conjugation or condensation in order to make the drug easier to be excreted. The

enzymes involved in metabolism are present in many tissues but mostly in the liver.

Drug metabolism rates are individually influenced by genetic factors, coexisting

disorders such as chronic liver disorders and advanced heart failure, and drug

interactions via induction or inhibition of metabolism (Tucker et al., 2001).

Generally, metabolism occurs in 2 phases. Phase I reactions involve formation of a

new functional group by oxidation, reduction or hydrolysis, these reactions are

considered as nonsynthetic. Phase II reactions involve conjugation with an

endogenous substance and these reactions are synthetic. Synthetic reactions produce

more polar metabolites that are readily to be excreted by the kidneys (urine) and the

liver (bile). (Xu and Kong, 2005)

First pass effect: an important concept of drugs metabolic pathways, it is

responsible for the reduction in total drug bioavailability which reflects the amount of

drug that delivered to the systemic circulation, where the drug is metabolized in the

GIT tissues and liver tissues before it reaches the systemic circulation.

Cytochrome P450 represents a family of isozymes that responsible for many drugs

biotransformation via oxidative reactions. These enzymes are heme-containing

membrane proteins, which are predominantly located in the smooth endoplasmic

reticulum of several tissues. It is majorly located in liver, but it could be also found in

kidneys, skin, gastrointestinal tract, and lungs where further non hepatic metabolism

may occur (Cupp and Tracy, 1998).

20

In humans upto 21 families, 20 subfamilies and 57 genes have been described

while CYP 1, 2 and 3 represent 70% of total hepatic CYPs content which are

responsible for 94% of drugs metabolism in liver (Rendic and Carlo, 1997).

1.8.9 Pioglitazone-Drug Interaction

In vitro data demonstrated that multiple CYP isoforms are involved in the

metabolism of pioglitazone HCl, involved cytochrome P450 isoforms are CYP2C8

mainly and CYP3A4 but with lesser degree (Takeda Canada, Inc. 2012), as a result,

any simultaneous intake of drug / food which can contribute in inhibition or activation

of these isoforms may lead to serious interactions with pioglitazone HCl resulting in

pathological complications which requires intensive patients care and critical drug

monitoring (Shah and Mudaliar, 2010).

Several studies have emphasize the pioglitazone – drug interaction through

CYP2C8 hepatic isoform, strong CYP2C8 inhibitors as gemfibrozil can increase

pioglitazone HCl plasma concentrations (Deng and Wang, 2005), while CYP2C8

inducers as rifampin may decrease pioglitazone HCl concentrations (Jaakkola et al.,

2006).

On the other hand, drugs that inhibit or activate CYP3A4 also contribute with

pioglitazone metabolic interaction (Radhika et al., 2012), itraconazole can inhibit

pioglitazone metabolism through CYP 3A4 inhibition which results in pioglitazone

serum levels elevation. Querciten ; a bioflavonoid that is used for treatment of some

heart and blood vessels diseases, has the same mechanism and interactive effect with

Pioglitazone (Jaakkola et al., 2005 ; Umathe et al., 2008), table 2 summarizes some

clinically approved pioglitazone – drugs interactions.

21

Table 1: Pioglitazone HCl – Drugs Interactions

Drug Mechanism Therapeutic Effect

Gemfibrozil Gemfibrozil is potent

CYP2C8 and CYP2C9

Inhibitor.

Increased AUC, enhanced

efficacy and increased

concentration-dependent

adverse effects

of pioglitazone HCl (Deng et al., 2005).

Itraconozole Itraconazole is a weak

inhibitor of CYP3A4 and

CYP2C9.

Enhanced the anti-diabetic

effect of the pioglitazone HCl.

(Jaakkola et al., 2005).

Rifampicin Rifampicin is an inducer of

CYP2C8.

Decreased serum

concentration of

pioglitazone HCl

leading to therapeutic failure.

Quercetin Quercetin is a potent

inhibitor of CYP3A4.

increased pioglitazone HCl bioavailability of

by 75% ( Umathe et al., 2008).

Ketoconazole Inhibitor of CYP3A4 and

CYP2C8.

Increased AUC of pioglitazone HCl

22

1.8.10 Determination of Pioglitazone HCl in Pharmaceutical Preparations and

Biological Fluids (Literature Survey)

Literature survey reveals many methods that were validated to be used for

determination of pioglitazone HCl in either pharmaceutical preparations or in

biological fluids for human and animals.

HPLC is one of the most frequently used analysis method for determination of

pioglitazone HCl, Ravikanth C. has improved a validated HPLC method for

bioanalysis of pioglitazone HCl in rats serum, the stationary phase was C18 column,

the mobile phase used consisted of Methanol and Ammonium acetate buffer (pH

adjusted to 5 with ortho-phosphoric acid) in ratio of 60:40, pioglitazone HCl and

internal standard were isolated from serum by liquid-liquid extraction. The organic

phase was separated and evaporated, and the remaining residue was reconstituted with

mobile phase before injected to the HPLC system, UV detector was operated at 269

nm for pioglitazone HCl serum concentrations determination (Ravikanth et al., 2011).

Another sensitive and rapid HPLC method was designed for determination of

pioglitazone HCl is serum by Kolte B. Rosiglitazone in Methanol was used as internal

standard, acetonitrile was used for extraction, and the final prepared sample was

injected into HPLC system for analysis. UV detector was set at 269 nm for the

determination of pioglitazone HCl concentrations in serum, HPLC system consisted

of C18 column and the mobile phase consisted of phosphate buffer (pH=3),

acetonitrile and methanol in a ratio of 70:25:5 (v/v/v) (Kolte et al., 2003), HPLC

technique was also used for determination of pioglitazone HCl in bulk and

pharmaceutical formulations, a validated experiment method was done by

Radhakrishna T., C18 column eluted with a mobile phase consisting of a mixture of

23

50% (v/v) acetonitrile and 10 mM potassium dihydrogen phosphate buffer, pH was

adjusted to 6 with 0.1 M KOH, wavelength was set at 225 nm (Radhakrishna et al.,

2002).

In addition, Sripalakit P., has developed an analytical method using high-

performance liquid chromatography (HPLC) with UV (269 nm) for the determination

of pioglitazone HCl in human serum. Rosiglitazone was used as an internal standard,

a reversed-phase chromatographic separation was obtained using C18 column and a

mobile phase of methanol and acetonitrile ,mixed with phosphate buffer 10 mM (pH=

2.6) in ratio of 40:12:48 (v/v/v) using a flow rate of 1.2 ml/min (Sripalakit et al.,

2006).

A validated HPLC –UV method for separation and quantification of pioglitazone

in plasma was developed, Zhong and Williams have used C18 separation column (250

mm × 4.6 mm i.d., 5 μm particle size) with mobile phase consisting of acetonitrile-

water (40:60, v/v) and containing 3 ml / L of acetic acid in mobile phase (pH=5.5).

Ultraviolet detector was operated at 269 nm (Zhang and Williams, 1996).

A different instrumentation, liquid chromatography tandem mass spectrometry

(LC-MS/MS) is also considered as a validated method that used for detection of

pioglitazone HCl in serum, Samanthula G. has carried this method procedure

successfully (Souri et al., 2008 ; Gananadhamu et al., 2012).

24

1.9 Sucralose

A synthetic organochlorine sweetener, it is considered as one of the most common

sweeteners and excipients in the world’s food industries (Broderick, 1992) and

pharmaceutical manufacturing (Blasé and Shah, 1993).

Physical and chemical properties: chemical formula: Dichloro-,1,6-dideoxy-β-D-

fructofuranosyl-4-chloro-4-deoxy α-D-galactopyranoside (Mann et al., 2000), the

chemical structure is shown in figure 2. Sucralose is a derivative of the halogenated

sucrose, mellow, with aromatic flavor and good stability, low in calories (around 3

calories per 1 gm) which justifies frequent usage of sucralose by diabetic patients and

people who follow low calories diet, in order to avoid sweetening of drinks or food

with table sugar which has high calories content. Sucralose is 600 times sweeter than

sucrose, good in sweet taste and mouth feel (Grotz and Munro, 2009).

It is a strongly stable sweetener with steady sweetness taste, these properties

permit safe usage of sucralose under high temperatures during manufacturing

processes of food or by home consumers, in addition, sucralose has a long term

stability of storage and even at low pH media (Binns, 2003). US FDA acceptable

daily intake (ADI) of sucralose is 5 mg/kg body weight/day.

25

Figure 2: Sucralose Chemical Structure.

1.9.1 Sucralose Manufacturing

Sucralose was artificially prepared and developed by British Professor Hough L in

1970 by chlorination, and at last deacetylation of sucrose (Luo et al., 2008).

1.9.2 Sucralose Brand Names

Splenda®,

which is widely distributed all over the world as either powder in sachets

or as tablets. Researchers analyzed Splenda®

and founded it as: 1.10% Sucralose,

1.08% glucose, 4.23% moisture and 93.59% maltodextrin.

Splenda® is only 1.10% sucralose, as a solitary sweetening agent (Schiffman and

Rother, 2013), FDA’s ADI of sucralose is 5 mg/ kg body weight/day which equals

about 454.5 mg/kg/day of Splenda®.

Another sucralose containing sweetener in markets named Tropicana Slim®, it

contains sorbitol 98.8% which is extracted from corn, and sucralose 1.2% as a

sweetness fortifying agent.

(http://www.amazon.com/Tropicana-Extracted-Sweetener-Calorie-Sticks).

26

Sucralose has not any teratogenicity, discontinuity or reproductive toxicity; it also

does not have any effect on blood sugar level and insulin secretion. Therefore, it is

freely used for obese patients, patients with cardiovascular diseases and diabetics.

(Goldsmith, 2000 ; Baird et al., 2000).

1.9.3 Sucralose PHarmacokinetics and Metabolism

Several studies stated that the majority of ingested sucralose is not absorbed from

gastrointestinal tract, 70–80% of ingested sucralose is excreted in feces and remainder

is excreted in urine (John et al., 2000).

The low absorption of sucralose from GIT is unpredictable as this sweetener is an

organochlorine molecule with good lipid solubility. Sucralose half-life has been

reported from 2 to 5 hours in most studies (Roberts et al., 2000) while serum peak

concentration is achieved 2 hours after oral dose, low bioavailability of sucralose

suggests that it is mostly extruded back into intestinal lumen during first-pass

metabolism in GIT (CYP-450) metabolism system ((Roberts et al., 2000 ; Schiffman

and Rother, 2013).

1.9.4 Artificial Sweeteners – Drug Interactions

Artificial sweeteners have historically been considered as inert compounds

without physiological complications. However, recent studies suggested that some of

these sweeteners have remarkable biological effects that may impact human health

(Rocha et al., 2008), on the other hand, there are significant gaps in our current

knowledge concerning pharmacokinetics of these sweeteners and their potential for

sweetener–drug interactions. Recently, previous studies have approved that sucralose

increases the expression of the P-gp intestinal transporter proteins and induces

27

CYP3A4 enzyme activity in intestine and liver (Schiffman and Rother, 2013 ; Abou-

Donia et al., 2008) at levels that have been associated with reduced bioavailability,

pharmacokinetic and pharmacodynamic parameters of drug, it may occur if the drug

is to be metabolized by CYP3A4 enzyme and concurrently taken with sucralose at

doses that are approved by the FDA, these findings justify the need of further studies

concerning potential drug interactions and monitoring of critical parameters during

concurrent intake of two possible interacting compounds, therefore, serious studies

concerning possible interaction are highly worthwhile(Grotz and Munro, 2009).

1.10 High Performance Liquid Chromatography (HPLC) Method

1.10.1 HPLC Definition and Principle

High performance liquid chromatography technique is used as separation and

quantification method to determine amount of specific compound that have been

dissolved in appropriate solution (Zhang et al., 2014).

HPLC system is mainly constructed by combining of three major components:

stationary phase, mobile phase and analyte (Kirkland et al., 1993).

Stationary phase is a matrix which is filled in column, it is usually made of inert

materials. Polarity of analyte determines the nature of stationary phase to be either

Normal Phase or Reverse Phase (Gloo and Johnson, 1977).

Mobile phase is liquid phase which is composed of solvent that carries sample to

be tested with its components through column stationary phase, composition of

mobile phase is basically depends on stationary phase composition and sample to be

tested too.

28

In HPLC, a pump use is a necessity to enhance mobile phase passage with sample

through column in a constant rate of flow to get a uniform separation of sample

components (Tang Y, 1996).

During analysis, where the sample solution is in contact with a second solid or

liquid phase that located in column, different solutes in sample solution will interact

with stationary phase, different interaction in column will occur which helps to

separate different components from each other.

Different factors should be properly selected and adjusted to obtain the most

suitable condition of separation and quantification, such as: type of column, column

length, column diameter, mobile phase, column temperature and flow rate (Bird,

1989), as shown in scheme 2.

Scheme 2: HPLC Flow

29

1.10.2 Types of HPLC

1.10.2.1 Normal Phase HPLC

In normal phase HPLC, column is filled with tiny silica particles and non-polar

solvent such as (hexane). A typical column has an internal diameter of 4.6 mm or less,

and a length of 150 - 250 mm.

Polar compounds in the mixture which will pass through the column will stick

stronger and longer to the polar silica than non-polar compounds. The non-polar

components will pass more quickly through the column (Kirkland et al., 1993).

1.10.2.2 Reversed Phase HPLC

In reversed phase HPLC, column is filled with silica which is modified to make it

non-polar by attaching long hydrocarbon chains to its surface with either 8 or 18

carbon atoms. A polar solvent is usually used such as mixture of water and alcohol.

A strong attraction between polar solvent and polar compounds in sample mixture

will occur, mixture will pass through column, non polar compounds will pass faster

while polar compounds will take longer passage time through column as it will bind

strongly with polar solvent. Reversed phase HPLC is the most commonly used form

of HPLC (Hearn et al., 1979).

1.10.2.3 Methods of Detection

There are several methods of detecting when compound passed through column. A

common and easy method is ultra-violet absorption.

30

Many organic compounds absorb UV light at various wavelengths. a beam of UV

light passing through a stream of liquid coming out of column, as UV detector is

located on opposite side of a stream, you can get a measurement of light amount that

was absorbed.

The amount of light absorbed is correlated to amount of specific compound that is

passing through a beam at that time, as shown in scheme 3.

Scheme 3: UV Detector Detection Pathway

The output will be recorded as a series of peaks, each one representing a

compound passing through the detector and absorbing UV light, peaks are used as a

way of measuring quantities of compounds present. Supposing that a particular

compound X, if a solution is injected containing a determined amount of X into

HPLC system, amount of X is related to peak that will be formed.

The area under the peak is proportional to amount of X, this area can be calculated

automatically by the computer linked to display (Lykkesfeldt, 2001).

31

1.10.3 Internal Standard (IS)

It is defined as a chemical substance that is added in constant amounts to samples

to be tested, blanks and calibration standards, the main purpose of internal standard is

for plotting ratio between signal that obtained from sample to signal that obtained

from internal standard in order to be used as a function of analytes unknown

concentrations calculations (Adibpour et al., 2013).

Both internal standard and analytes should perform a similar but distinguishable

signals and performance by instrument during analysis which facilitates analysis

technique and enhance the analysis procedure results (Goidin et al., 2001).

The internal standard must be available in pure form, stable and eluted after

sample components.

1.10.4 HPLC Instrument Calibration

Also named instrument qualification, it is defined as a procedure that carried to

ensure if instrument performance complies with method’s requirements specifications

resulting with reliable and valid obtained results (Bliesner, 2006).

To ensure that the instrument performs satisfactorily and gives accurate and

reproducible data, the instrument must be tested on site (Miller, 2005), within specific

time intervals and after repair, it should be inspected, maintained, calibrated and

cleaned periodically according to Standard Operating Procedures (SOPs) (Ermer,

2001; Shah et al., 1992).

32

1.10.5 Bioanalytical HPLC Method Validation Parameters Definitions (EMEA)

1.10.5.1 Precision

The precision of the analytical method describes closeness of repeated individual

measures of analyte. Precision is expressed as coefficient of variation CV% (Shabir,

2003).

Precision should be demonstrated for LLOQ, low, medium and high QC samples,

within a single run and between different runs, using the same runs and data as for the

demonstration of accuracy too (Taverniers et al., 2004).

Intra-day precision: five samples at least per each concentration of calibration

(LLOQ, QCL, QCM, and QCH) should be performed in a single run. Obtained

concentration results will be then evaluated.

Inter-day precision: LLOQ, QCL, QCM, and QCH samples should be run three

times separately on three different days, then results will be evaluated (Beavis, 1998).

Precision can be calculated as a coefficient of variation, CV% is a parameter with

high value in precision expression, for intra-day and inter-day precision: CV% should

not exceed 15% of QC values, except for LLOQ to be not more than 20%.

1.10.5.2 Accuracy:

The accuracy of an analytical method describes the closeness of determined value

obtained by method to nominal concentration of analyte (expressed in percentage).

Accuracy should be carried on samples spiked with determined analyte amounts as for

quality control samples (QC samples). QC samples should be spiked independently

33

from calibration standards, using separately prepared stock solutions ( Huber, 1999 ;

González et al., 1999).

QC samples should be analyzed, then compared with calibration curve nominal

values. Accuracy should be reported in percentage form of nominal value (Peduzzi et

al., 1995).

Accuracy % is calculated as follows:

Accuracy % = (calculated value / true value) * 100%

Intra- day accuracy: it is determined by analyzing a single run of minimum 5

samples per level at a minimum of 4 concentration levels covering calibration curve

range: LLOQ, 3 times of LLOQ: (QCL), 50% of calibration curve range: (QCM), and

75% of the upper calibration curve range: (QCH), mean concentration should be

within ±15% of the nominal values of QC samples, while for the LLOQ it should be

within ±20% of the nominal values.

Inter-day accuracy: LLOQ, QCL, QCM, and QCH are analyzed and evaluated on

three different days, mean concentration should be within ±15% of nominal values of

QC samples while for LLOQ it should be within ±20% of nominal values

1.10.5.3 Linearity

It is the ability to obtain test results which are directly proportional to

concentration of analyte in sample within a given range ( Huber, 1999).

A recommended protocol for establishing linearity of analytical method which

involves 6 calibration standards or more over concentration range of interest, with

34

repeating standard calibration for 3 or more runs in a random order, a direct

proportion between response and concentrations of analytes should be existed.

( Huber, 1999 ; Shah et al., 2000).

Regression factor (R²) is a value that is used to evaluate linearity of any calibration

curve data in order to evaluate closeness between predicted and target data, the closer

data reflects best linear relationship between values with R² closer to 1.

1.10.5.4 Range

Range of analytical method is the interval between upper and lower concentrations

including these concentrations of analyte in a sample with a suitable precision,

accuracy and linearity, range is derived from linearity studies and depends on

intended procedure application ( Huber, 1999).

1.10.5.5 Ruggedness

It is a measurement of method capacity to remain unaffected by small variations in

method parameters and supplies, it donates an indication of method reliability during

normal carrying (HÄsselbarth, 1998).

It can be also described as the ability to reproduce method in different laboratories

or under different conditions without any differences in obtained results (Vander et

al., 2001).Ruggedness test is usually performed for pharmaceutical preparations and

drug industries rather than other types of samples.

35

1.10.5.6 Limit of Detection

It is the lowest amount of analyte in a sample which can be detected but not

necessarily quantified as an exact value, but also represents the amount of analyte in

sample permitting the analyte identification qualitatively without accurate and precise

quantification (Taverniers et al., 2004 ; Armbruster and Pry et al., 2008).

1.10.5.7 Lower limit of Quantification

It is the lowest amount or concentration of analyte in a sample which can be

determined quantitatively with suitable precision and accuracy (Viswanathan et al.,

2007). Lower limit of quantification (LLOQ) is always higher than the limit of

detection (LOD) and is recommended for LLOQ as 3 times of LOD and not higher

than 5% of Cmax (Taverniers et al., 2004).

1.10.5.8 Selectivity

The analytical method should be able to differentiate between analyte(s) of interest

and IS from endogenous components in matrix or other components in sample.

Normally, absence of interfering components is accepted where the response is less

than 20% of lower limit of quantification for analyte and 5% for the internal standard.

It may also be necessary to investigate the extent of any interference caused by

metabolites of drug(s), interference from degradation products formed during sample

preparation, and interference from possible co-administered medications.Co-

medications normally used in the subject population studied which may potentially

interfere should be taken into account at method validation. (Miller and Miller, 1988 ;

Kazakevich and LoBrutto, 2007)

36

1.10.5.9 Sensitivity

Sensitivity can be defined as the ability to measure analyte concentrations

accurately in presence of interfering materials such as excipients and degradation

products that may be present in sample (Medina, 2003).

Sensitivity test is usually performed by analysis of 10 repetitionss of each quality

control level then evaluating the results according to the adopted validation

guidelines.

1.10.5.10 Recovery

A parameter which describes method ability to detect distinguishingly internal

standard and drug in presence of both at the sample to be tested, and obtaining a result

with less errors and more close to the nominated value.

It is an essential component of method validation as it is important to be aware of

problems and basis on which the results reporting depend (EMEA, 2012).

Recovery test should be carried out for analyte to be tested and internal standard, at

each level of QC samples, five different times analysis should be run at least.

37

1.10.5.11 Stability

Stability evaluation should be carried out to ensure that sample preparation,

analysis and storage conditions used, do not affect analyte concentration.

Analyte stability is usually studied using the matrix in low and high QC samples,

(LLOQ and close to the ULOQ) which analyzed immediately after preparation and

after the applied evaluation storage conditions. QC samples are analyzed against a

calibration curve, prepared freshly, and the obtained results of concentrations are

compared to nominal concentrations. Mean concentration at each QC used level

should be within ±15% of nominal concentration.

Essential stability tests that should be evaluated are as follow:

Stability of stock solution and working solutions of analyte and internal

standard.

Freeze and thaw stability of analyte in matrix from freezer storage conditions

to room temperature or sample processing temperature.

Short term stability of analyte in matrix at room temperature or sample

processing temperature.

Long term stability of the analyte in matrix stored in the freezer.

Regarding the freeze and thaw stability

QC samples are stored and frozen in freezer at a determined temperature then

thawed at room or processing temperature. After complete thawing, samples are

refrozen again under same conditions. At each cycle, samples should be frozen for at

least 12 hours before thawing. Number of cycles in the freeze-thaw stability should

equal or exceed that of freeze/thaw cycles of study samples.

38

Regarding long term stability of the analyte in matrix stored in the freezer

QC samples should be stored in freezer under the same storage conditions and at

least for same duration passed by study samples. For small molecules it is considered

acceptable to apply a bracketing approach, (in case stability has been proved for

instance at -70°C and -20°C, it is not necessary to investigate stability at temperatures

in between).

39

1.11 Aim of the Study

The aim of the present study is to develop a simple, valid and rapid

chromatographic method for quantifying pioglitazone HCl in rats serum under

feasible conditions to find out an appropriate method of analysis which comply

scientific research requirements.

Study the pharmacokinetic parameters of pioglitazone HCl in rats serum fed with

sucralose simultaneously in order to examine possibility of interaction between

pioglitazone HCl and sucralose in rats.

40

CHAPTER TWO

EXPERIMENTAL PART

41

2. Experimental Part

2.1 Reagents

All reagents that were used for analysis procedures and other experimental stages

are listed with details as follow:

Reagents List

Deionized water HPLC (TEDIA, B# 7732185), USA.

Rats serum (Pooled from animals).

Methanol HPLC gradient (FULLTIME, B# 6508ET30), USA.

Acetonitrile HPLC gradient (FULLTIME, B# 6308GT30), USA.

Ammonium acetate HPLC gradient (TEDIA, B# AR-OK17), USA.

Ammonia solution (MERCK, B# K41763423047), Germany.

Sodium Hydroxide pellets Purified 40Mwt (SDFCL, Fine – Chem

limited, B# G11Z/2911/1202/08), India.

Pioglitazone HydroChloride Raw material (JPM, B# 10713180), purity

˃99%, Jordan.

Splenda®

Sucralose containing sweetener (McNeil

Nutritionals, LLC. B# S6040543973-

071494), Indonesia.

Sildenafil Citrate (YASHICA pharmaceuticals, B#

LS/026/01/10). India.

Product information in table 2.

42

Table 2: Sildenafil Citrate Information (Internal Standard)

Wt 0.065 g

Assay % 100.905

Water content % 1.00%

Counter ion % 27.70%

Equivalent wt. 0.047 g

Volume prepared 100 ml

Sildenafil Citrate Chemical Structure

2.2 Instrumentation

A) HPLC

HPLC instrument parts and laboratory instruments with tools used in analysis

procedure are mentioned in the following list:

43

HPLC System Parts

Pump (S # L-2130 VWR-HITACHI, Japan).

Autosampler thermostat (S# L-2200 VWR-HITACHI, Japan).

Column oven (S# L-2300 VWR-HITACHI, Japan).

UV detector (S# L-2420 VWR-HITACHI, Japan)

Lab Instruments and Tools

Data system (Ez Chrome VWR-HITACHI, Japan)

Analytical balance (Sartorius, Germany.

Top loading balance (Sartorius, Germany)

Centrifuge (Eppendorf mini spin, Germany)

Vortex mixer (Heidolph, Germany)

Adjustable micropipettes

(20-200), ml

(Dragon, China)

pH meter (Bante instrument, model # PHS-3BW)

Sonicater (Decon FS 100, England)

Water bath (Hetotherm BWO)

44

2.3 Preclinical Study

The study protocol was approved by the Research Committee (October;

5/10/2013) at the Faculty of Pharmacy, University of Petra, Amman, Jordan.

Adult male Sprague Dawley laboratory rats were supplied at Petra University

animal house. Rats average weight was (0.230 kg ± 0.03). Rats were placed in air-

conditioned environment with temperature of (20-25 C°) and exposed to a

photoperiod cycle (12 hour light /12 hour dark) with humidity of 50% daily. Rats

were under fasting for 24 hours, and weighed directly before the experiment. All used

rats were in healthy conditions before and after experiment as rats were monitored for

one month post analysis.

Pioglitazone HCl and sucralose test solutions were freshly prepared directly in the

laboratory before rats feeding in order to avoid any possible decomposition of either

pioglitazone HCl or sucralose.

A group consisting of total 80 healthy rats was used for the experiment. Rats were

divided into groups of 8 rats, rats then were weighed and numbered orderly.

Pioglitazone HCl and sucralose oral doses were calculated according to each rat

weight then given orally according to ordered numbers using gastric gavage.

Trials analysis was performed among 3 days according to following arrangement:

At first day of trials: two groups of rats were used for analysis ; the first one has

received water at experiment zero time, then followed by pioglitazone HCl after 1

hour of water feeding, while the second group has received sucralose at zero time of

experiment followed by pioglitazone HCl after 1 hour of sucralose feeding.

45

Time intervals of blood samples pooling were: 0, 30 min, 1 hr, 2 hr, 3 hr, 4 hr and

6 hr.

At second day of trials: two groups have received water at zero time of

experiment followed by pioglitazone after one hour, while other two groups have

received sucralose at zero time followed by pioglitazone after 1 hour of suralose

feeding.

Time intervals of blood samples pooling were: 0, 30 min, 1 hr, 2 hr, 3 hr, 4 hr, 6

hr, 8 hr and 24 hr.

At third day of trials: one groups have received water at zero time of experiment

followed by pioglitazone after one hour, while another three groups have received

sucralose at zero time followed by pioglitazone after 1 hour of suralose feeding.

Time intervals of blood samples pooling were: 0, 30 min, 1 hr, 2 hr, 3 hr, 4 hr, 6 hr

and 8 hr.

Tail tip of each rat was cut after weighing and numbering, approximately 200 µl of

blood was pooled into eppendorf tube at each time interval under the same numbering

order, after total time intervals of blood pooling is finished, samples were centrifuged

for 10 minutes (12000 rpm) in order to obtain pure serum that is needed for analysis

than frozen at -20 C°.

46

2.4 Preparation of Stock Solutions and Working Solutions

2.4.1 Preparation of Pioglitazone HCl Oral Solution:

10 mg/kg of pioglitazone HCl oral dose for rats was recommended at the

experiment.The current study was carried out with a reasonable dose of pioglitazone

for rodents (10 mg/kg). Other experiments with daily oral administration of

pioglitazone in rodents have been performed by using pioglitazone doses between 2.3

and 35 mg/kg, but with most studies 10 mg/kg.was used, it represents around 50 times

of 70 kg weighing patient who would receive a pioglitazone dose of 45-mg tablet.

(Sakai et al., 2002 ; Matsuura et al., 2004 ; Umathe et al., 2008 ; Janadri et al., 2009).

Although these doses seem disproportionate, but thiazolidinediones are eliminated

and cleared approximately 10 times faster by rats when compared with humans

because of higher CYP2C expression (Lamontagne et al., 2013).

As a result, using of 10 mg/kg dose is considered as effective dose with similar

acute therapeutic effects and corresponding bioactivities as the 45 mg / day human

daily dose of pioglitazone.

Freshly solution per day of trials was prepared : accurate weight of pioglitazone

HCl raw drug = (0.3 g) was prepared, dissolved in 0.0375 M NaOH solution to get

100 ml final solution volume.

Solution was heated to 35 C° using water bath, and sonicated for 5 minutes

sequentially till drug dissolved completely.

Pioglitazone HCl oral dose volume was calculated corresponding to each rat

weight according to the following formula:

47

Rat oral dose volume = rat weight (kg) x pioglitazone HCl experiment approved dose

(mg/kg) ÷ pioglitazone HCl solution concentration (mg/ml).

Rat oral dose = rat weight (kg) x 10 mg/kg ÷ 3 mg/ml

2.4.2 Preparation of Sodium Hydroxide Solution

0.15 g of sodium hydroxide pellets was weighed, then dissolved in distilled water

to obtain a 100 ml final solution volume of (0.0375 M).

2.4.3 Preparation of Sucralose Oral Solution

Splenda® contains 1.10% sucralose, as a solitary sweetening agent (Schiffman S. et

al., 2013), to reach the FDA’s ADI of 5 mg/kg/day of sucralose, adult human would

need to consume 454.5 mg/kg/day of Splenda®, corresponding to this calculations,

rats oral dose of sucralose was 11 mg/kg/day which equals 1000 mg /kg/day of

Splenda®. According to FDA approved daily dose, 11 mg/kg/day of sucralose is a

double dose, but it is approved in our experiment as an acute treatment in order to

reach the desired biological effects of sucralose in rats gastrointestinal system at the

required time.

Freshly prepared solution of sucralose was prepared daily, Splenda®

powder was

weighed (12.5 g), dissolved in distilled water to obtain 50 ml final solution volume of

250 mg/ml concentration of Splenda®.

Sucralose oral dose volume for each rat was calculated according to the following

formula:

Rat oral dose = rat weight (kg) x Splenda® experiment approved dose (mg/kg) ÷

Splenda® solution concentration (mg/ml).

48

Rat oral dose = rat weight (kg) x 1000 (mg/kg) ÷ 250 mg/ml

2.4.4 Preparation of Pioglitazone HCl Stock Solution

Daily prepared solutions were made by dissolving a weight of pioglitazone HCl

equals (25 mg) in 50 ml methanol to provide a solution concentration of 500 µg/ ml.

2.4.5 Preparation of Pioglitazone HCl Serial Dilutions in Methanol

Samples for standard calibration curve and method validation analysis were

prepared by taking different volumes from pioglitazone HCl stock solution, each

sample was added to sufficient volume of methanol HPLC gradient to reach 10 ml

final solution volume per sample with specific concentration per each in order to be

used for calibration and method validation analysis later, as shown in table 3 and 4.

Table 3: Pioglitazone HCl Serial Dilutions in Methanol

Serial solution (C) no.

Volume of

stock

solution

(ml)

Final

volume (ml) Final concentration (µg\ml)

C 1 0.25 10 12.5

C 2 0.75 10 37.5

C 3 2 10 100

C 4 3 10 150

C5 4 10 200

C 6 5 10 250

C7 (LLOQ) 0.25 10 12.5

C8 (QCL) 2 10 100

C9 (QCM) 4 10 200

C10 (QCH) 8 10 400

49

2.4.6 Preparation of Pioglitazone HCl Standard Solutions in Serum (QC

Solutions)

Serial dilutions of samples were prepared by taking an appropriate volume of each

concentration that is previously prepared in Methanol (as shown in table 3 and 4),

sufficient volume of serum was added to reach 5 ml final volume with corresponding

pioglitazone HCl concentration as detailed in table 4. Samples were vortexed, then

used for analysis procedure. All final standard solutions were prepared freshly and

directly before analysis. Concentrations: St1, St2, St3, St4, St5 and St6 were the

concentrations that used for calibrations, while concentrations of: St7 (LLOQ), St8

(QCL), St9 (QCM) and St10 (QCH) were the concentrations that used for method

validation analysis, as shown in table 4.

Table 4: Pioglitazone HCl QC Standard Solutions in Serum

Final standard

solution no.

Volume of

standard

(C) (ml)

Standard

solution

(C) conc.

(µg\ml)

Final

standar

d

volume

(ml)

Final concentration

(µg\ml)

St1 0.1 12.5 5 0.25

St2 0.1 37.5 5 0.75

St3 0.15 100 5 3

St4 0.167 150 5 5

St5 0.175 200 5 7

St6 0.32 250 5 16

St7 (LLOQ) 0.1 12.5 5 0.25

St8 (QCL) 0.1 100 5 2

St9 (QCM) 0.175 200 5 7

St10 (QCH) 0.16 400 5 12.8

50

2.4.7 Preparation of Mobile Phase

515 ml acetonitrile HPLC gradient was mixed with 485 ml buffer solution to get

the mobile phase with the defined ratios of the chromatographic conditions, as shown

in table 5.

2.4.8 Preparation of Buffer Solution

Amount of 1.927 g of ammonium acetate was weighed, then dissolved in 1L

distilled water, pH was adjusted to 8 by using 300 µl ammonia solution, pH=8 was

selected as pioglitazone HCl chromatographic peaks showed accepted resolution and

separation at this value.

2.4.9 Preparation of Internal Standard Stock Solution

Sildenafil citrate was used as internal standard as it has similar chemical

properities and solubility to pioglitazone HCl, it behaves quietly similar to

pioglitazone HCl during HPLC analysis, it elutes after pioglitazone at a different

retention time and sharp peaks with appropriate separation resolution. Blanks and

internal standard zero drug blanks explain and ensure sildenafil citrate suitability to be

used as IS. Sildenafil citrate stock solution was prepared freshly by weighing (65.04

mg) of sildenafil citrate which is equivalent to (46.97 mg), added into a volumetric

flask and dissolved in 100 ml methanol to provide a 469.7 µg /ml base equivalent.

2.4.10 Preparation of Internal Standard Working Solution

Internal standard solution was prepared by diluting 3 ml from stock solution with

sufficient volume of acetonitrile to obtain 100 ml final solution of(14.091) µg /ml

concentration. Sildenafil citrate information was listed in table 2.

51

2.4.11 Sample Preparation (Extraction Procedure)

Mixing of 100 µl of rats serum with 75.0 µl of IS working solution, then vortex for

30 seconds and centrifuged at 12000 rpm for 5 min. Supernatant was transferred into

rack, and 90 µl of supernatant was injected into HPLC unit.

2.4.12 Method Development (Chromatographic Conditions)

Separation column selection

Referring to previous studies that demonstrated reverse phase HPLC method for

detection of pioglitazone HCl in plasma and pharmaceutical preparations, C8 column

was selected for analysis, other studies suggested the use of C18 column and methods

were validated, C8 has the same characteristics of C18 but with difference in

hydrophobicity properties as C18 column is more hydrophobic than C8 due to higher

number of alkyl groups attached to silica, concerning separation technique: both have

same performance but with sharper peaks of separation chromatograms with C8,

which enhances analytes separation and results sharpness (Souri et al., 2008), this

finding suggested the proper selection of C8 column in our analysis procedure.

Mobile phase selection

Mobile phase selection was dependant on the following concepts:

1- Pioglitazone solvent dependant solubility.

2- Pioglitazone stability in mobile phase.

3- Pioglitazone pH dependant stability and solubility.

As detailed previously in literature survey heading, and referring to previous

studies that determined pioglitazone in serum, mobile phase was consisting of

52

solvents that has moderate to efficient pioglitazone HCl solubility, but with ratios

which enhances sample elution and avoid drug decomposition or complete

solubilization, which may interfere compounds separation and detection.

The most popularly used solvents for pioglitazone detection in plasma and serum

referring to literature surveys were: acetonitrile, methanol, water, ethyl acetate and

buffers with acidic pH.

Pioglitazone showed reasonable solubility with basic pH> 6 while many studies

claim that pioglitazone HCL could be decomposed under basic conditions with pH>8

with degradation percentage = 3.04 (Narsimha et al., 2012).

Other studies found that pH degradation was at pH=7-12 or less, with degradation

5.76% at 60min and 9.61% at 90min after drug solution preparation and under stress

conditions (Dubey, 2014), literature outcomes conclude the safe use of basic pH

values for pioglitazone HCl solutions if experimental procedure follows freshly

prepared drug solutions under normal conditions.

In our experiment, mobile phase was formulated with several solvents ratios and

pH values, it was founded to be (51.50%) acetonitrile and (48.50%) 0.025 mM

ammonium acetate, pH= 8 by which sharp peaks and reasonable resolution of

pioglitazone chromatograms were obtained.

53

UV Detector wave length selection

Referring to literature survey, several trials have been made to determine the most

precise UV wavelength at which pioglitazone can be detected, in our experiment it

was 269 nm.

Flow rate selection

1ml/min was founded as accepted rate of flow depending on peaks shapes

obtained, as it enhances mobile phase elution with uniform separation.

All chromatographic conditions were detailed in table 5.

Table 5: Chromatographic and Detection Conditions

Analytical technique HPLC

Detection method UV (269) nm

Analytical column ACE C8, 5 µm (250 x 4.6 mm i.d.)

Auto-sampler temperature 10 C°

Column temperature 40 C°

Mobile phase (51.50%) acetonitrile + (48.50%)

0.025 mM ammonium acetate

pH= 8

Injection volume 90 µl

Run time 10 min.

Flow rate 1 ml/min

Pioglitazone HCl retention time 5 min ±0.03

Internal standard sildenafil citrate

retention time

8 min ±0.01

54

2.5 Method Validation

EMEA guidelines of bioanalytical method validation were relied as validation

reference for method development.

2.5.1 Inter- day Accuracy and Precision

Inter-day accuracy and precision were determined by analyzing of 5 samples of

each QC concentration mentioned in table 6 on 3 different days with daily

randomization of samples before analysis. Evaluating of coefficient of variation CV%

was done to determine precision while accuracy% was used to determine accuracy

level.

Precision: CV% should not exceed 15% for QCL, QCM and QCH as acceptance

criteria, while it should be less than 20% for LLOQ according to EMEA guidelines.

Accuracy: mean of calculated concentrations should be within ±15% of nominated

concentrations for: QCL, QCM, and QCH, while it should be within ±20% of LLOQ

concentration.

Table 6: Concentrations Used for Method Validation

QC solution Final Concentration (µg\ml)

S1 (LLOQ) 0.25

QCL 2

QCM 7

QCH 12.8

55

2.5.2 Intra-day Accuracy and Precision

Intra–day accuracy and precision were determined by analyzing 5 samples of each

QC concentration mentioned in table 6. Evaluating of CV% values was done to

determine precision while accuracy% was employed to determine accuracy level.

Precision: CV% to be < 15% for QCL, QCM and QCH was adopted as acceptance

criteria, while it should be less than 20% for LLOQ according to EMEA guidelines.

Accuracy: mean of calculated concentrations should not exceed ±15% of

nominated concentrations of: QCL, QCM, and QCH, while it should be within ±20%

of LLOQ concentration.

Each set of samples were run simultaneously with a calibration curve samples in

order to calculate the concentrations per each, every calibration curve had a formula

which was used for concentrations calculation:

Y = a * X + b

Y= Area ratio

a = Slope of the plotted curve

X= Calculated concentration

b = Curve intercept

56

2.5.3 Selectivity and Sensitivity

Selectivity test was carried out by analysis of 6 different blanks of serum then

compared with LLOQ clarifying absence of any interfering peaks of components in

samples.

It is accepted if endogenous peak appeared in the chromatogram of blanks and

referred to either sample component or internal standard, but when response is less

than 20% of lower limit of quantification for analyte and 5% for internal standard

according to EMEA guidelines.

Sensitivity test was proceeded by analysis of 10 repetitionss of each quality

control level, mean calculated concentrations will be evaluated according to EMEA

guidelines as it should be within ± 20% for LLOQ, while it should be within ±15%

for other QC levels.

2.5.4 Linearity

Six calibration curves were designed for each group of quality control samples by

spiking of pioglitazone HCl and internal standard in serum to get standard

concentrations of (0.25, 0.75, 3, 5, 7, 16) µg/ml, samples then prepared for analysis by

extraction followed by injection for analysis.

Plotting of area ratios versus concentrations was done to perform calibration curve

for each group of samples.

R² values were calculated for each calibration in order to evaluate linearity and to

calculate concentrations at each level.

57

2.5.5 Recovery

Analyte recovery

QC samples per level were prepared in serum, and then treated to be analyzed with

compatible calibration. After obtaining calculated concentrations, mean concentration

was calculated, it must be within ± 20 for LLOQ and within ±15 for other QC

samples.

Internal standard recovery

Two groups of all QC samples with corresponding levels were prepared; the first

group was prepared with mobile phase while the other group was prepared with

serum.

After obtaining IS areas of each group per QC level, area ratios% were calculated

depending on its corresponding calibration as follows:

IS area in in serum / IS area mobile phase * 100%

2.5.6 Stability

1- Freeze and thaw stability

Three samples of (QCL and QCH) were prepared properly in serum with sufficient

final volume covering all test cycles analysis.

At zero time (FTS0): with corresponding calibration, samples were analyzed and

concentrations were calculated, then, samples were stored and frozen at -20C°.

After 12 hours (FTS1): samples were thawed at room temperature 25C° which was

the samples processing temperature during analysis stages. After complete thawing,

58

samples were analyzed again with corresponding calibration, and refrozen again for

24 hours.

After 24 hours (FTS2): samples were thawed and analyzed under same conditions.

After each cycle, concentrations were calculated referring to related calibration.

2- Room temperature stability

Room temperature stability of pioglitazone in serum and stock/working

solutions: 3 samples of (QCL and QCH) were prepared properly in serum. Another

group of QC samples were prepared in mobile phase for stock and working solution

stability, with sufficient volume depending on test requirements.

Samples were prepared and analyzed with freshly prepared calibration at zero time

and after 8 hours at room temperature of 28C°. Area ratios % per QCL and QCH were

calculated referring to related calibration.

Room temperature stability of internal standard in serum and stock/working

solutions: 3 samples of (QCL and QCH) were prepared properly in serum. Another

group of QC samples were prepared in mobile phase for stock and working solution

stability, with sufficient volume depending on test requirements.

Samples were prepared and analyzed with freshly prepared calibration at zero time

and after 8 hours at room temperature of 28C°.

In serum stability: area ratios% per QCL and QCH were calculated according to

freshly prepared combined calibration.

In working/stock solutions stability: area ratios% were calculated for each QC

sample properly.

59

3- Long term stability

Long term stability of pioglitazone in serum and working/stock solutions

3 samples of (QCL and QCH) were prepared properly in serum. Another group of

QC samples were prepared in mobile phase for stock and working solution stability,

with sufficient volume depending on test requirements.

Samples were prepared and analyzed with freshly prepared calibration at zero

time. Samples then were frozen for 30 days at temperature of -20 C°. After long term

freezing period was finished, samples were removed and thawed at room temperature.

In serum stability: concentrations per QCL and QCH were calculated according to

freshly prepared combined calibration.

In working/stock solutions stability: area ratios% were calculated for each QC

sample then evaluated.

3.2 Long term stability of internal standard in working/stock solutions: area

ratios% were calculated for each QC sample then evaluated.

2.6 Statistical Analysis

Statistic is a number that is derived from a specific data, such as mean or a

standard deviation. It is helpful when data are going to be examined to obtain a

relevant descriptive statistics.

Comparing statistics obtained from different sets of data can give an idea of

similarities or differences between sets of data.

60

Our experimental data was gathered then treated to be easily translated in to proper

computerized data structure, examining of data were carried to evaluate errors and

figures reasonability using T-test and Cohen’s d, statistical analysis tools were carried

by statistical science expert and performed using statistical package for social

sciences (SPSS) of (IBM version 20).

Confidence Interval: confidence interval determines an estimated range of values

which mostly includes unknown parameter, this estimated range is calculated from

given data, for example; a confidence interval for difference between two means

specifies a range of values where the difference between means could be found.

Confidence intervals are often calculated as 95% but producing 90%, 99% or

99.9% confidence intervals for unknown parameter is possible too.

Confidence interval width indicates a clear idea about how certain we are

concerning unknown parameter which helps to determine acceptance or rejection of

hypothesis. Cohen’s d: Cohen’s d is a measurement of effect size, which is usually

used in experiments to compare differences between two groups of data.

Cohen’s d = mean 1 – mean 2 / pooled SD

SD pooled = √ { (SD1)² + (SD2)² } ÷ 2

If Cohen’s d ˂ 0.3, effect size is considered as small, while value within (0.3-0.7)

is considered as medium effect, and exceeding ≥ 0.8 as large effect.

P value: when performing a hypothesis test in statistics, P-value helps to determine

the significance of experiment results. Hypothesis tests are used to test validity of a

claim concerning category, this claim which is on trial is called null hypothesis.

Alternative hypothesis is the one which should be approved if null hypothesis is

61

considered as untrue. The evidence is the data, and the statistics that go along with it.

All hypothesis tests use P-value to evaluate the strength of evidence.

P-value is a number between 0 and 1 and interpreted in the following way:

A small P-value (P ≤ 0.05) indicates strong evidence against null hypothesis, so you

reject it.

A large P-value (P > 0.05) indicates weak evidence against null hypothesis, so you

fail to reject it.

62

CHAPTER THREE

RESULTS AND DISCUSSION

63

3. Results and Discussion

3.1 Method Validation

3.1.1 Inter-day Precision and Accuracy

Inter-day Precision

At first day of validation: QCL showed the lowest coefficient of variation

(CV%) = 0.188 (less than 15%) which reflected acceptable precision while ST1

(LLOQ) showed the highest CV% = 1.77 which is also agreeable to be considered as

accepted (less than 20% for LLOQ) according to EMEA guidelines, both QCH and

QCM showed medium CV% values with reasonable precision equals 0.81 and 1.28

respectively, as shown in table 7.

First day validation calculated concentrations were obtained using corresponding

calibration that was run simultaneously with samples, as shown in figure 3 and table

11.

At second day of validation: QCL showed reasonable accepted precision with

CV% = 0.16, as it is less than 20 % for LLOQ, while QCH showed the least but also

reasonable precision with CV% value = 3.54 according to EMEA guidelines.

Concerning ST 1 (LLOQ) and QCM: both showed reasonable precision with CV% =

1.43 and 1.33 respectively as values were less than 20% for LLOQ and less than 15%

for QCM, as shown in table 8.

Second day validation calculated concentrations were obtained using

corresponding calibration that was run simultaneously with samples, as shown in

figure 5 and table 13.

64

At third day of validation: QCL showed the most valid precision value as it

obtained CV% value of 0.40 while QCH reflected the least precision over the third

day with accepted validity as it showed CV% value of 2.94, both QCM and

ST1(LLOQ) showed plausible precisions with CV% values less than 15% for QCM

and less than 20% for LLOQ to confirm reasonability for both, CV% values were 1.18

and 1.56 respectively, as shown in table 9.

Third day validation calculated concentrations were obtained using corresponding

calibration that was run simultaneously with samples, as shown in figure 7 and table

15.

Inter - day Accuracy

At first day of validation: QCH showed highly reasonable accuracy % = 105.6 %

and mean concentration within ± 15% of nominated value, QCL showed the least but

also accepted accuracy % = 99.45% with a mean concentration within± 15% of

nominated value indicating the passing of EMEA guidelines too.

Regarding QCM and ST1 (LLOQ), both levels showed approved accuracy as they

got accuracy% of 102.4 % and 102.8 % respectively with mean concentrations within

±15% of QCM and within ±20% of LLOQ.

First day overall accuracy % was 102.54 % which is approved according to EMEA

guidelines, as shown in table 7.

First day validation calculated concentrations were obtained using corresponding

calibration that was run simultaneously with samples, as shown in figure 3 and table

11.

65

At second day of validation: QCH showed highly reasonable accuracy % = 105.7

% while QCL showed the least but also accepted accuracy % = 101.2%.

Concerning ST1 (LLOQ) and QCM, both showed very plausible accuracy as they

got accuracy% of 102.4 % and 104.3% respectively.

Second day overall accuracy % was 103.4% with calculated concentrations mean

within permitted limits of EMEA, as shown in table 8.

Second day validation calculated concentrations were obtained using

corresponding calibration that was run simultaneously with samples, as shown in

figure 5 and table 13.

At the third day of validation: QCH showed a plausible accuracy % of 107.85

with mean concentration within ±15 % of nominated concentration, while

ST1(LLOQ) showed the least but also appreciable accuracy % = 98.4% and mean

concentration within ±20% of nominated concentration. In addition, QCL and QCM

showed very good accuracy as they got accuracy% of 102.2 % and 105.95%

respectively. Third day overall accuracy % = 103.6% considered as valid according to

EMEA guidelines, as shown in table 9.

Third day validation calculated concentrations were obtained using corresponding

calibration that was run simultaneously with samples, as shown in figure 7 and table

15.

66

Table 7: Inter- day Precision and Accuracy: Day 1

INTER- DAY ACCURACY AND PRECISION: DAY 1

Sample ID Pioglitazone

area 1

IS area

2

Area

ratio

Calculated

conc.

(µg/ml)

True

conc.

(µg/ml)

Mean SD CV% Error Accuracy

%

ST(LLOQ)

1 1

117581 477005 0.0246 0.254 0.25 0.26 0.01 1.77 0.01 102.8

ST(LLOQ)

1 2

118865 476363 0.0250 0.257 0.25

ST(LLOQ)

1 3

119333 476870 0.0250 0.258 0.25

ST(LLOQ)

1 4

121301 472719 0.0257 0.264 0.25

ST(LLOQ)

1 5

114968 470081 0.0245 0.252 0.25

ST1 (LLOQ) ± 20% = ±0.05...... (0.20 - 0.30)

QCL Day

1 1

951839 477832 0.1992 1.985 2.00 1.989 0.004 0.188 -0.01 99.45

QCL Day

1 2

950899 476217 0.1997 1.990 2.00

QCL Day

1 3

953577 476862 0.2000 1.993 2.00

QCL Day

1 4

947473 475692 0.1992 1.985 2.00

QCL Day

1 5

946498 473482 0.1999 1.992 2.00

QCL ± 15%= ±0.3...... (1.97 – 2.30)

QCM Day

1 1

3427503 472442 0.7255 7.205 7.00 7.16 0.09 1.28 0.16 102.3

QCM Day

1 2

3422696 472160 0.7249 7.200 7.00

QCM Day

1 3

3422376 471742 0.7255 7.205 7.00

QCM Day

1 4

3418429 470867 0.7260 7.210 7.00

QCM Day

1 5

3301435 468458 0.7047 7.000 7.00

QCM ±15% = ±1.05...... (5.95 - 8.050)

QCH Day

1 1

6297812 468234 1.3450 13.350 12.80 13.52 0.11 0.81 0.72 105.6

QCH Day

1 2

6381626 465840 1.3699 13.597 12.80

QCH Day

1 3

6250955 461026 1.3559 13.458 12.80

QCH Day

1 4

6184986 452207 1.3677 13.575 12.80

QCH Day

1 5

6172602 450621 1.3698 13.596 12.80

QCH ±15 %= ±1.92...... (10.88 – 14.74)

67

Table 8: Inter- day Precision and Accuracy: Day 2

INTER- DAY ACCURACY AND PRECISION: DAY 2

Sample ID Pioglitazone

area 1

IS area 2 Area

ratio

Calculated

conc.

(µg/ml)

True conc.

(µg/ml)

Mean SD CV

%

Error Accuracy

%

ST(LLOQ)

2 1

121255 486709 0.0249 0.254 0.25 0.26 0.004 1.43 0.01 102.40

ST(LLOQ)

2 2

122537 483712 0.0253 0.259 0.25

ST(LLOQ)

2 3

121916 489363 0.0249 0.254 0.25

ST(LLOQ)

2 4

125213 488775 0.0256 0.262 0.25

ST(LLOQ)

2 5

120435 486815 0.0247 0.253 0.25

ST1 (LLOQ) ± 20% = ±0.05...... (0.20 - 0.30)

QCL Day

2 1

971323 487586 0.1992 2.023 2.00 2.02 0.003 0.16 0.024 101.20

QCL Day

2 2

961354 482569 0.1992 2.023 2.00

QCL Day

2 3

960881 482985 0.1989 2.020 2.00

QCL Day

2 4

966005 483509 0.1998 2.029 2.00

QCL Day

2 5

965241 484606 0.1992 2.023 2.00

QCL ± 15%= ±0.3...... (1.97 – 2.30)

QCM Day

2 1

3504031 485146 0.7223

7.331

7.00 7.30 0.10 1.33 0.30 104.30

QCM Day

2 2

3444259 475134 0.7249

7.357

7.00

QCM Day

2 3

3478431 479926 0.7248

7.356

7.00

QCM Day

2 4

3507246 484583 0.7238 7.346

7.00

QCM Day

2 5

3460054 492446 0.7026 7.131

7.00

QCM ±15% = ±1.05...... (5.95 - 8.05)

QCH Day

2 1

6442610 489963 1.3149 13.344 12.80 13.53 0.48 3.54 0.73 105.70

QCH Day

2 2

6499104 458415 1.4177 14.388 12.8 0

QCH Day

2 3

6459534 493133 1.3099 13.293 12.80

QCH Day

2 4

6446871 491834 1.3108 13.302 12.80

QCH Day

2 5

6447860 490902 1.3135 13.33 12.80

QCH ±15% = ±1.92...... (10.88 – 14.74)

68

Table 9: Inter- day Precision and Accuracy: Day 3

INTER -DAY ACCURACY AND PRECISION: DAY 3

Sample ID Pioglitazone

area 1

IS area 2 Area ratio Calculated

conc.

(µg/ml)

True conc.

(µg/ml)

Mean SD CV

%

Error Accuracy

%

ST(LLOQ)

3 1

127844 476104 0.0269 0.247 0.25 0.25 0.004 1.56 -0.004 98.40

ST(LLOQ)

3 2

130431 478226 0.0273 0.251 0.25

ST(LLOQ)

3 3

122158 464357 0.0263 0.241 0.25

ST(LLOQ)

3 4

124118 461288 0.0269 0.247 0.25

ST(LLOQ)

3 5

122016 460724 0.0265 0.243 0.25

ST1 (LLOQ) ± 20% = ±0.05...... (0.20 - 0.30)

QCL Day

3 1

980839 478395 0.205 2.05 2.00 2.04 0.008 0.40 0.043 102.20

QCL Day

3 2

982727 479271 0.205 2.051 2.00

QCL Day

3 3

934037 459898 0.2031 2.031 2.00

QCL Day

3 4

940772 460934 0.2041 2.041 2.00

QCL Day

3 5

941802 460723 0.2044 2.044 2.00

QCL ± 15%= ±0.3...... (1.97 – 2.30)

QCM Day

3 1

3415499 462505 0.7385 7.451 7.00 7.42 0.088 1.18 0.42 105.95

QCM Day

3 2

3403102 458932 0.7415 7.482 7.00

QCM Day

3 3

3421587 463638 0.738 7.446 7.00

QCM Day

3 4

3351959 454486 0.7375 7.442 7.00

QCM Day

3 5

3301078 458575 0.7199 7.263 7.00

QCM ±15% = ±1.05...... (5.95 - 8.050)

QCH Day

3 1

6325417 461149 1.3717 13.862 12.80 13.81 0.405 2.94 1.01 107.90

QCH Day

3 2

6334111 452690 1.3992 14.141 12.8 0

QCH Day

3 3

6173948 445117 1.387 14.017 12.80

QCH Day

3 4

6213802 451902 1.375 13.896 12.80

QCH Day

3 5

4549269 350723 1.2971 13.107 12.80

QCH ±15% = ±1.92...... (10.88 – 14.74)

69

3.1.2 Intra- Day Precision and Accuracy

Intra-day Precision

A reasonable precision with CV% range of (0.15- 4.1) was achieved, all CV%

values were less than 15% for QC samples for QCL, QCM and QCH and less than

20% for LLOQ which confirms precision validity according to EMEA guidelines, as

shown in table 10.

Intra-day Accuracy

Accuracy% ranged between (99.35 - 103.99), while all calculated mean of

concentrations were within ±15% of QCM, QCH and QCL, and within ± 20% of

LLOQ, which indicates the validity of method accuracy according to EMEA

guidelines, as shown in table 10.

Intra- Day accuracy and precision calculated concentrations were obtained using

corresponding calibration that was run simultaneously with samples, as shown in

figure 3 and table 11.

70

Table 10: Intra- day Precision and Accuracy

INTRA- DAY ACCURACY AND PRECISION

Sample ID Pioglitazone

area 1

IS area

2

Area

ratio

Calculated

conc.

(µg/ml)

True conc.

(µg/ml)

Mean SD CV% Error Accuracy

%

ST(LLOQ)

1

120249 484105 0.0248 0.256 0.25 0.26 0.003 1.31 0.01 103.20

ST(LLOQ)

2

121541 481135 0.0253 0.26 0.25

ST(LLOQ)

3

120605 486736 0.0248 0.256 0.25

ST(LLOQ)

4

123770 486304 0.0255 0.262 0.25

ST(LLOQ)

5

119434 484381 0.0247 0.254 0.25

ST1 (LLOQ) ± 20% = ±0.05...... (0.20 - 0.30)

QCL

1

966488 485107 0.1992 1.986 2.00 1.99 0.003 0.15 -0.01 99.35

QCL

2

956768 480112 0.1993 1.986 2.00

QCL

3

956844 480365 0.1992 1.985 2.00

QCL

4

961728 481112 0.1999 1.992 2.00

QCL

5

960276 482162 0.1992 1.985 2.00

QCL ± 15%= ±0.3...... (1.97 – 2.30)

QCM

1

3491285 482558 0.7235 7.186 7.00 7.16 0.096 1.34 0.16 102.20

QCM

2

3430021 472448 0.726 7.211 7.00

QCM

3

3464505 477387 0.7257 7.208 7.00

QCM

4

3494237 482284 0.7245 7.196 7.00

QCM

5

3445729 489882 0.7034 6.986 7.00

QCM ±15% = ±1.05...... (5.95 - 8.05)

QCH

1

6428716 487289 1.3193 13.095 12.80 13.31 0.550 4.13 0.51 103.99

QCH

2

6484961 450279 1.4402 14.294 12.80

QCH

3

6445076 490655 1.3136 13.038 12.80

QCH

4

6433374 489376 1.3146 13.048 12.80

QCH

5

6435618 488427 1.3176 13.078 12.80

QCH ±15% = ±1.92...... (10.88 – 14.74)

71

3.1.3 Linearity

Calculating R² values for 6 calibration curves of QC samples to determine

closeness of R² value to 1 was performed, the closer value indicated highly reasonable

linearity while all R² values for 6 calibrations were with accepted fitness and

calculated concentrations of calibration levels was within ± 20% for LLOQ, and ±

15% for other QC levels.

Results indicated reasonable and valid method linearity, as shown in the following

tables and figures:

Linearity calibration 1 R² = 0.997383 See figure 3 and table 11

Linearity calibration 2 R² = 0.994147 See figure 4 and table 12

Linearity calibration 3 R² = 0.999127 See figure 5 and table 13.

Linearity calibration 4 R² = 0.996554 See figure 6 and table 14.

Linearity calibration 5 R² = 0.99955 (highest value with corresponding linearity), see

figure 7 and table 15.

Linearity calibration 6 R² = 0.996124 See figure 8 and table 16.

Six calibrations mean of linearity test was calculated. R² value = 0.9991 which

reflects valid linearity performance of method between plotted concentrations and

their responses.

72

Figure 3: Linearity Calibration 1

Table 11: Linearity Calibration 1 Data

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1 120560 296153 1490928 2587688 3378180 7666202

IS area 2 4766532 4689973 4708993 4733321 4793227 4887632

Area ratio 0.025293 0.065514 0.316613 0.546696 0.704782 1.568490

RF

0.1022

0.0842

0.1055

0.1093

0.1001

0.0980 Back calculated conc.

(µg/ml) 0.2606 0.6400 3.1500 5.4321 7.0000 15.5665

± 15% of St true value 0.0375 0.1125 0.45 0.75 1.05 2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.100824 x - 0.000986181 R²= 0.997383

0.0000000

0.2000000

0.4000000

0.6000000

0.8000000

1.0000000

1.2000000

1.4000000

1.6000000

1.8000000

0 2 4 6 8 10 12 14 16 18

Calibration 1

Conc.(µg/ml)

Are

a R

atio

73

Figure 4: Linearity Calibration 2

Table 12: Linearity Calibration 2 Data

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml)

0.25

0.75

3

5

7

16

Pioglitazone area 1 126092 316816

1536496 2609269 3665146 7156039

IS area 2

4659633

4647634

4632825

4707404 5070670

4568116

Area ratio 0.027061

0.068167 0.331650 0.554290 0.722813 1.56652

RF

0.1012

0.0892

0.1054

0.1092

0.1101

0.0880

Back calculated conc.

(µg/ml) 0.2582 0.692728 3.2097 5.3670 7.0000 15.1755

± 15% of St true value 0.0375 0.1125 0.45 0.75 1.05

2.4

-15%

+15% 0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.103200 x + 0.000412951

R²=0.994147

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Calibration 2

Conc. (µg/ml)

Are

a R

atio

74

Figure 5: Linearity Calibration 3

Table 13: Linearity Calibration 3 Data

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1

122771

305287

1509126

2618433

3275154

7431479

IS area 2

4815662

4816772

4890544

4993543

4748733

4742707

Area ratio 0.025494 0.063138 0.308580 0.524364 0.689690 1.566930

RF

0.1002

0.0896

0.1051

0.1082

0.1301

0.0955 Back calculated conc.

(µg/ml) 0.2603 0.6422 3.1328 5.3224 6.9999 15.9015

± 15% of St true value

0.0375 0.1125 0.45 0.75 1.05 2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.0985494 x - 0.000155154 R²= 0.999127

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Calibration 3

Conc.(µg/ml)

Are

a R

atio

75

Figure 6: Linearity Calibration 4

Table 14: Linearity Calibration 4 Data

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Calibration 4

Conc.(µg/ml)

Are

a R

atio

Standard solution no. St1 St2 St3 St4 St5 St6

Concentration(µg/ml)

0.25

0.75

3

5

7

16

Pioglitazone area 1 97842 293043 1477999 2550193 3326130 7357360

IS area 2

4728226

4718827

4747801

4721216

4725073

4730326

Area ratio 0.0206932 0.0621008 0.311302 0.540156 0.7039319 1.55536

RF

0.1016

0.0932

0.1021

0.1193

0.0987

0.0988

Back calculated conc.

(µg/ml) 0.2576 0.6662 3.1254 5.3838 6.9999 15.4021

± 15% of St true

value 0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15% 0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y= 0.101335 x - 0.00541304 R²=0.996554

76

Figure 7: Linearity Calibration 5

Table 15: Linearity Calibration 5 Data

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Calibration 5

Conc.(µg/ml)

Are

a R

atio

Standard solution no. St1 St2 St3 St4 St5 St6

Concentration(µg/ml)

0.25

0.75

3

5

7

16

Pioglitazone area 1

131669

315855

1461283

2133438

3268153

7318102

IS area 2 4683446

4716375

4659510

4732606

4709745

4593191

Area ratio 0.028114 0.066969 0.313613 0.450796 0.693913 1.593250

RF

0.1019

0.0841

0.1028

0.1048

0.09753

0.0979

Back calculated conc.

(µg/ml) 0.2593 0.6527 3.1498 4.5386 7.0000 16.10510

± 15% of St true value 0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.0987729 x + 0.00250227 R²=0.99955

77

Figure 8: Linearity Calibration 6

Table 16: Linearity Calibration 6 Data

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

0 2 4 6 8 10 12 14 16 18

Calibration 6

Conc.(µg/ml)

Pe

ak A

rea

Rat

io

Standard solution no. St1 St2 St3 St4 St5 St6

Concentration(µg/ml)

0.25

0.75

3

5

7

16

Pioglitazone area 1 66663 263646 1360390 2396680 3146246 6958257

IS area 2

4729226

4728827

4719710

4720616

4724973

4729326

Area ratio 0.014096 0.055753 0.288236 0.507705 0.665876 1.471300

RF

0.1014

0.0832

0.1071

0.1093

0.09771

0.09788

Back calculated conc.

(µg/ml) 0.2556 0.6867 3.0923 5.3633 6.9999 15.3342

± 15% of St true

value 0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15% 0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.0966408 x - 0.0106092 R²=0.996124

78

The following calibration represents the overall linearity performance of analysis

method.

Y= 0.0972x + 0.0099 R² = 0.9991

79

3.1.4 Selectivity and Sensitivity

Selectivity: sample preparation for HPLC analysis by protein precipitation method

was a suitable procedure, six serum blanks chromatograms showed absence of any

endogenous compounds as no corresponding peaks were founded specially at the

expected retention time of both pioglitazone HCl and internal standard.

Evaluation of selectivity was done through the comparison of the 6 serum blanks

chromatograms with the chromatogram of ST1(LLOQ), HPLC detector did not detect

any sensible peaks over the retention time of analyte and IS, as shown in blanks

chromatograms and ST1(LLOQ) chromatogram (figures: 22-30).

Sensitivity: sensitivity tests was carried out through the analysis of 10 repetitions

of each QC samples level, the mean calculated concentrations were within EMEA

guidelines values as all mean concentrations were within ±15% of QCL, QCM and

QCH with CV% values less than 15%, while it was within ±20% of LLOQ with CV%

value less than 20% as shown in tables (17-20), sensitivity test was carried out in

combination of calibration 1 for day one of validation.

80

Table 17: LLOQ Sensitivity Data

Sample ID Pioglitazone

area 1

IS area 2 Area

ratio

Calculated

concentration

(µg/ml)

True

concentration

(µg/ml)

CV%

average

ST(1) (LLOQ)

System

Precision 1 105362 5014991 0.0210

0.218

0.25

9.810

ST(1) (LLOQ)

System

Precision 2

98865

4918648 0.0201

0.209

0.25

ST(1) (LLOQ)

System

Precision 3

97770

4840107 0.0202

0.210

0.25

ST(1) (LLOQ)

System

Precision 4 97016 4861460 0.0200 0.208

0.25

ST(1) (LLOQ)

System

Precision 5 101023 5001690 0.0202 0.210

0.25

ST(1) (LLOQ)

System

Precision 6 120421 4917461 0.0245 0.253

0.25

ST(1) (LLOQ)

System

Precision 7 119278 4861460 0.0245 0.253

0.25

ST(1) (LLOQ)

System

Precision 8 123473 4918648 0.0251 0.259

0.25

ST(1) (LLOQ)

System

Precision 9 120421 4917461 0.0245 0.253

0.25

ST(1) (LLOQ)

System

Precision 10 101287 4936063 0.0205 0.213

0.25

ST1 (LLOQ) ± 20% = ±0.05...... (0.20 - 0.30)

81

Table 18: QCL Sensitivity Data

Sample ID Pioglitazone

area 1

IS area 2 Area

ratio

Calculated

concentration

(µg/ml)

True

concentration

(µg/ml)

CV%

average

QCL System

Precision 1

952025 480712 0.1980 1.974 2.00

0.156

QCL System

Precision 2

928469 467743 0.1985 1.979 2.00

QCL System

Precision 3

961432 483118 0.1990 1.984 2.00

QCL System

Precision 4

924853 466708 0.1982 1.975 2.00

QCL System

Precision 5

949735 478938 0.1983 1.977 2.00

QCL System

Precision 6

926074 466174 0.1987 1.980 2.00

QCL System

Precision 7

979325 493793 0.1983 1.977 2.00

QCL System

Precision 8

923893 464912 0.1987 1.981 2.00

QCL System

Precision 9

970168 489682 0.1981 1.975 2.00

QCL System

Precision 10

928396 467821 0.1985 1.978 2.00

QCL ± 15%= ±0.3...... (1.97 – 2.30)

82

Table 19: QCM Sensitivity Data

Sample ID Pioglitazone

area 1

IS area 2 Area

ratio

Calculated

concentration

(µg/ml)

True

concentration

(µg/ml)

CV%

average

QCM System

Precision 1

355760 493225 0.7213 7.164 7.00

0.097

QCM System

Precision 2

333112 461405 0.7220 7.170 7.00

QCM System

Precision 3

348471 483036 0.7214 7.165 7.00

QCM System

Precision 4

329734 457162 0.7213 7.163 7.00

QCM System

Precision 5

354823 491815 0.7215 7.165 7.00

QCM System

Precision 6

335025 464364 0.7215 7.166 7.00

QCM System

Precision 7

353060 489046 0.7219 7.170 7.00

QCM System

Precision 8

351195 486447 0.7220 7.170 7.00

QCM System

Precision 9

350355 484204 0.7236 7.186 7.00

QCM System

Precision 10

348780 483639 0.7212 7.162 7.00

QCM ± 15%= ±1.05...... (5.95 - 8.05)

83

Table 20: QCH Sensitivity Data

Sample ID Pioglitazone

area 1

IS area 2 Area

ratio

Calculated

concentration

(µg/ml)

True

concentration

(µg/ml)

CV%

average

QCH System

precision 1

638993 483710 1.3210 13.112 12.80

0.193

QCH System

Precision 2

638853 481211 1.3276 13.177 12.80

QCH System

Precision 3

638023 479911 1.3295 13.196 12.80

QCH System

Precision 4

640465 483803 1.3238 13.140 12.80

QCH System

Precision 5

641094 484469 1.3233 13.135 12.80

QCH System

Precision 6

641045 484439 1.3233 13.134 12.80

QCH System

Precision 7

641602 484834 1.3233 13.135 12.80

QCH System

Precision 8

641287 484118 1.3246 13.148 12.80

QCH System

Precision 9

640413 483040 1.3258 13.159 12.80

QCH System

Precision 10

641897 484962 1.3236 13.138 12.80

QCH ±15% = ±1.92...... (10.88 – 14.74)

84

3.1.5 Recovery

Analyte recovery (pioglitazone HCl)

As indicated in table 21, mean calculated concentration of pioglitazone per QC

level was within ±15% of QCL, QCM and QCH nominated values while it was within

± 20% of LLOQ nominated value which indicated accepted recovery of pioglitazone

in serum. Calibration used for calculation in figure 3 and table 11.

Figure 3: Linearity Calibration 1

Table 11: Linearity Calibration 1 Data

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1 120560 296153 1490928 2587688 3378180 7666202

IS area 2 4766532 4689973 4708993 4733321 4793227 4887632

Area ratio 0.025293 0.065514 0.316613 0.546696 0.704782 1.568490

RF

0.1022

0.0842

0.1055

0.1093

0.1001

0.0980

Back calculated conc.

(µg/ml) 0.2606 0.6400 3.1500 5.4321 7.0000 15.5665

± 15% of St true value

0.0375 0.1125 0.45 0.75 1.05 2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.100824 x – 0.000986181 R² = 0.997383

0.0000000

0.2000000

0.4000000

0.6000000

0.8000000

1.0000000

1.2000000

1.4000000

1.6000000

1.8000000

0 2 4 6 8 10 12 14 16 18

Calibration 1

Conc.(µg/ml)

Are

a R

atio

85

Table 21: Pioglitazone HCl Recovery Data

PIOGLITAZONE HCL RECOVERY DATA:

Sample ID Pioglitazone

area 1

IS area

2

Area

ratio

Calculated

conc.

(µg/ml)

True conc.

(µg/ml)

Mean SD CV

%

Error Accuracy

%

ST(LLOQ)

R1 121132 473512 0.0256 0.264

0.25

0.265

0.002

0.69

0.01

106

ST(LLOQ)

R2 122897 475679 0.0258 0.266

0.25

ST(LLOQ)

R3 117911 461679 0.0255 0.263

0.25

ST(LLOQ)

R4 119016 458502 0.0260 0.267

0.25

ST(LLOQ)

R5 117269 457995 0.0256 0.264

0.25

ST1 (LLOQ) ± 20% = ±0.05...... (0.20 – 0.30)

QCL

R1 953036 475684 0.2004 1.997

2.00

1.999

0.00

0.10

0.00

99.95

QCL

R2 957200 476657 0.2008 2.002

2.00

QCL

R 3 917393 457253 0.2006 2.000

2.00

QCL

R 4 918793 458523 0.2004 1.997

2.00

QCL

R5 919888 458289 0.2007 2.001

2.00

QCL ± 15%= ±0.3...... (1.97 – 2.30)

QCM

R1 334098 460008 0.7263 7.213

7.00

7.212

0.01

0.17

0.21

103

QCM

R 2 332098 456309 0.7278 7.228

7.00

QCM

R3 334205 461134 0.7247 7.198

7.00

QCM

R4 328220 452269 0.7257 7.208

7.00

QCM

R5 334098 460008 0.7263 7.213

7.00

QCM ±15% = ±1.05...... (5.95 – 8.05)

QCH

R 1 622801 456138 1.3654 13.552

12.80

13.63

0.12

0.87

0.83

106.5

QCH

R2 625063 458545 1.3631 13.530

12.80

QCH

R 3 626550 450146 1.3919 13.815

12.80

QCH

R4 610466 442942 1.3782 13.679

12.80

QCH

R5

614502

449332

1.3676

13.574

QCH ±15%

= ±1.92

(10.88-

14.74)

12.80

86

Internal standard recovery

Table 22 illustrates acceptable recovery ratios of sildenafil citrate between mobile

phase and serum, QCL showed the highest recovery percentage which equals 97.89%,

while QCH indicated the least recovery of 93.54 %. Figure 3 and table 11 show

calibration that used for calculations.

Table 22: Internal Standard Recovery Data

INTERNAL STANDARD RECOVERY

Sample ID. Internal

standard

in mobile

phase

area 1

Internal

standard in

serum

area 2

Area ratio:

Area 2 /

Area 1

Recovery % Mean

recovery %

ST(LLOQ) 1 501499 473512 0.944193 94.42

94.48

ST(LLOQ) 2 491865 475679 0.967093 96.71

ST(LLOQ) 3 484011 461679 0.953861 95.39

ST(LLOQ) 4 486146 458502 0.943136 94.31

ST(LLOQ)5 500169 457995 0.91568 91.57

QCL 1 480712 475684 0.989541 98.95

97.89 QCL 2 467743 476657 1.019057 101.91

QCL 3 483118 457253 0.946462 94.65

QCL 4 466708 458523 0.982462 98.25

QCL 5 478938 458289 0.956886 95.69

QCM 1 493225 460008 0.932653 93.27

96.02 QCM 2 461405 456309 0.988955 98.90

QCM 3 483036 461134 0.954658 95.47

QCM 4 457162 452269 0.989297 98.93

QCM 5 491815 460008 0.935327 93.53

QCH 1 483710 456138 0.942999 94.30

93.54

QCH 2 481211 458545 0.952898 95.29

QCH 3 479911 450146 0.937978 93.80

QCH 4 483803 442942 0.915542 91.55

QCH 5 484469 449332 0.927473 92.75

87

3.1.6 Stability

Freeze and Thaw Stability

Data obtained after each cycle analysis were used for concentrations calculations

depending on a combined calibration, all results were reasonable and accepted

according to EMEA guidelines as the mean calculated concentrations were within

±15%, QCH showed higher stability percentage at cycle 1 and cycle 2 rather than

QCL as shown in table 23.

Calibrations used for calculation were as follows:

FTS 0: at 0 hours

Figure 3: Linearity Calibration 1

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Calibration 1

Conc.(µg/ml)

Are

a R

atio

88

Table 11: Linearity Calibration 1 Data

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1 120560 296153 1490928 2587688 3378180 7666202

IS area 2 4766532 4689973 4708993 4733321 4793227 4887632

Area ratio 0.025293 0.065514 0.316613 0.546696 0.704782 1.568490

RF 0.1022

0.0842

0.1055

0.1093

0.1001

0.0980

Back calculated conc.

(µg/ml) 0.2606 0.6400 3.1500 5.4321 7.0000 15.5665

± 15% of St true value 0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.100824 x – 0.000986181 R²= 0.997383

FTS 1 at 12 hours

Figure 5: Linearity Calibration 3

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Calibration 3

Conc.(µg/ml)

Are

a R

atio

89

Table 13: Linearity Calibration 3 Data

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1

122799

122799

1509126

2618433

3275154

7431479

IS area 2

4816772

4816772

4890544

4993543

4748733

4742707

Area ratio 0.025494 0.063138 0.308580 0.524364 0.689690 1.566930

RF 0.1002

0.0896

0.1051

0.1082

0.1301

0.0955

Back calculated conc.

(µg/ml) 0.2603 0.6422 3.1328 5.3224 6.9999 15.9015

± 15% of St true value 0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.0985494 x – 0.000155154 R²= 0.999127

FTS2: at 12+24 hours.

Figure 7: Linearity Calibration 5

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Calibration 5

Conc.(µg/ml)

Are

a R

atio

90

Table 15: Linearity Calibration 5 Data

Standard solution no. St1 St2 St3 St4 St5 St6

Concentration(µg/ml)

0.25

0.75

3

5

7

16

Pioglitazone area 1 131669

315855

1461283

2133438

3268153

7318102

IS area 2 4683446

4716375

4659510

4732606

4709745

4593191

Area ratio 0.028114 0.066969 0.313613 0.450796 0.693913 1.593250

RF

0.1019

0.0841

0.1028

0.1048

0.09753

0.0979

Back calculated conc.

(µg/ml) 0.2593 0.6527 3.1498 4.5386 7.0000 16.10510

± 15% of St true value 0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.0987729 x + 0.00250227 R²=0.99955

91

Table 23: Freeze and Thaw Stability Data

QC Low (2 µg/ml)

Time Pioglitazone

area 1

IS area

2

Area

ratio

Measured

conc.

(µg/ml)

Mean Accuracy

%

Stability

%

FTS 0

0 hours

991662 4723889 0.209925 2.10

2.03

105

946089 4729311 0.200048 2.00 100

941299 4728722 0.199060 1.990 99.5

FTS 1

12 hours

924399 4719693 0.19586 1.989

1.99

99.95

98 923389 4714537 0.19586 1.988 99.90

924307 4719222 0.19586 1.989 99.95

FTS 2

12+24

hours

926216 4680693 0.19788 1.978

1.98 99.90

97.5 926046 4677711 0.19797 1.979 99.95

924940 4676612 0.19778 1.977 99.85

QCL ± 15%= ±0.3...... (1.97 – 2.30)

QC High (12.8 µg/ml)

Time Pioglitazone

area 1

IS area

2

Area

ratio

Measured

conc.

(µg/ml)

Mean Accuracy

%

Stability

%

FTS

0 hours

5928455 4716660 1.256918 12.76

12.75

99.66

5926348 4718693 1.255930 12.75 99.58

5922855 4719621 1.254943 12.74 99.53

FTS 1

12 hours

5846681 4703345 1.243090 12.56

12.61

98.13

98.9 5842460 4688773 1.246053 12.59 98.36

5882194 4690913 1.253955 12.67 98.98

FTS 2

12+24

hours

5988118 4723299 1.267783 12.58

12.58

98.28

98.7

5974591 4719982 1.265808 12.56 98.13

5993074 4723527 1.268771 12.59 98.36

QCH ±15 %= ±1.92 (10.88-14.74)

Room Temperature Stability

Room temperature stability of pioglitazone in serum and stock/working solution

Data obtained at zero time and after 8 hours at room temperature of (28C° ± 1)

confirm accepted stability of pioglitazone HCl in both,

92

In serum stability: mean calculated concentrations were within ±15% for QCL and

QCH, which illustrates reasonable stability of both QC levels, QCH showed higher

stability at room temperature rather than QCL as shown in table 24.

In stock/working solutions: as shown in table 25, QCH showed higher stability of

99.10% while QCL represented lower but also accepted stability% of 92.39.

Both stability percentages represented a reasonable stability of pioglitazone in

stock and working solution.

Room temperature stability of internal standard in stock/ working solution

Data obtained at zero time and after 8 hours at room temperature of 28C°±1

confirms accepted stability of pioglitazone HCl, stability % of area ratios between

zero and after 8 hours were accepted as shown in table 26, QCH has obtained larger

level of stability while QCL obtained reasonable stability% value of 98.86. QCL and

QCH concentrations were calculated according to the following calibration:

Figure 3: Linearity Calibration 1

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Calibration 1

Conc.(µg/ml)

Are

a R

atio

93

Table 11: Linearity Calibration 1 Data

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1 120560 296153 1490928 2587688 3378180 7666202

IS area 2 4766532 4689973 4708993 4733321 4793227 4887632

Area ratio 0.025293 0.065514 0.316613 0.546696 0.704782 1.568490

RF 0.1022

0.0842

0.1055

0.1093

0.1001

0.0980

Back calculated conc.

(µg/ml) 0.2606 0.6400 3.1500 5.4321 7.0000 15.5665

± 15% of St true value 0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.100824 x – 0.000986181 R²= 0.997383

Table 24: Room Temperature Stability Data for Pioglitazone HCl in Serum

QC Low (2 µg/ml)

Time

(hour)

Pioglitazone

area 1

IS area

2

Area

ratio

Measured

concentration

(µg/ml)

Mean Accuracy% Stability

%

0 hour 1056494 4762522 0.221835 2.21 2.10 110.5

96.7 988363 4689873 0.210744 2.10 105

945077 4709793 0.200662 2.00 100

8 hours 1002921 4736301 0.211752 2.11 2.03 105.5

952528 4795127 0.198645 1.98 99

977852 4897732 0.199654 1.99 99.5

QCL ± 15%= ±0.3...... (1.97 – 2.30)

QC High (12.8 µg/ml)

Time

(hour)

Pioglitazone

area 1

IS area

2

Area

ratio

Measured

concentration

(µg/ml)

Mean Accuracy% Stability%

0 hour 6124878 4753299 1.288553 12.79 12.79 99.9

99.5 6041041 4680913 1.290569 12.81 100.1

6071026 4718893 1.286536 12.77 99.8

8 hour 6068639 4739321 1.280487 12.71 12.73 99.3

6171882 4793527 1.287545 12.78 99.8

6248819 4887732 1.278470 12.69 99.1

QCH ±15% = ±1.92 (10.88-14.74)

94

Table 25: Room Temperature Stability Data for Pioglitazone HCl in

Stock/Working Solution

QC Low (2 µg/ml)+ QC High (12.8 µg/ml)

Sample

ID.

Pioglitazone

area at 0

hours

Pioglitazone

area at

8 hours

Area

time

8/area

time 0

Stability% Stability

average %

QCL1 1077494 969261 0.899551 89.96

92.39 QCL2 989343 879524 0.888998 88.90

QCL3 986037 969332 0.983059 98.31

QCH1 6194888 6118171 0.987616 98.76

99.10 QCH2

6081149 6065551 0.997435 99.74

QCH3 6016102 5941797 0.987649 98.76

Table 26: Room Temperature Stability Data for Internal Standard in

Stock/Working solution

QC Low (2 µg/ml)+ QC High (12.8 µg/ml)

Sample

ID.

IS area at 0

hours

IS area at

8 hours

Area time 8/

area time 0

Stability% Stability

average%

QCL1

4764523

4751442

0.997254

99.73

98.86

QCL2

4787873

4687883

0.979115

97.91

QCL3

4759792

4708790

0.989284

98.93

QCH1

4747302

4738321

0.998108

99.81

99.80

QCH2

4765027

4755167

0.997930 99.79

QCH3

4887562

4877732 0.997988 99.80

95

Long Term Stability

Long term stability of pioglitazone HCl in serum

Data was collected at zero and after 30 days, treated then concentrations were

calculated, results approve reasonable stability of piolgitazone in serum as mean

concentrations were within ±15% for QCL and QCH with accepted stability%, QCH

represented higher stability at long term test of 99.68% while QCL showed lower but

also reasonable stability % of 98.5 as shown in table 28.

Long term stability of pioglitazone HCl in stock/working solution

Data was collected at zero and after 30 days, prepared then analyzed,

concentrations were calculated and results approved reasonable stability of

pioglitazone, QCL showed higher stability percentage of 99.49 while QCH was with

lower but reasonable stability% of 98.12, as shown in table 29.

Long term stability of internal standard in stock/working solution

Area ratios of sildenafil citrate were collected at zero and after 30 days of freezing,

results approved reasonable stability of IS. Sildenafil stability was high at QCH and

QCL as shown in table 30.

Long term stability test was run using the following calibrations simultaneously:

96

Zero Time Calibration:

Figure 3: Long Term Stability Zero Time Calibration (Linearity Calibration 1)

Table 11: Long Term Stability Zero Time Calibration Data (Linearity

Calibration 1)

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1 120560 296153 1490928 2587688 3378180 7666202

IS area 2 4766532 4689973 4708993 4733321 4793227 4887632

Area ratio 0.025293 0.065514 0.316613 0.546696 0.704782 1.568490

RF 0.1022

0.0842

0.1055

0.1093

0.1001

0.0980

Back calculated conc.

(µg/ml) 0.2606 0.6400 3.1500 5.4321 7.0000 15.5665

± 15% of St true value 0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y = 0.100824 x – 0.000986181 R²= 0.997383

0.0000000

0.2000000

0.4000000

0.6000000

0.8000000

1.0000000

1.2000000

1.4000000

1.6000000

1.8000000

0 2 4 6 8 10 12 14 16 18

Calibration 1

Conc.(µg/ml)

Are

a R

atio

97

Long Term Stability Day 30 Calibration:

Figure 9: Long Term Stability Day 30 Calibration Curve

Table 27: Long Term Stability Day 30 Calibration Data

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1 112973 341691 1608632 2330399 3317295 7594075

IS area 2 4756542 4688983 4718793 4735351 4793017 4817622

Area ratio 0.023751 0.072871 0.340899 0.492128 0.69211 1.576312

RF

0.1021

0.0942

0.1035

0.1083

0.1221

0.0990

Back calculated conc.

(µg/ml) 0.249 0.745 3.453 4.980 7.000 15.931

± 15% of St true

value

0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4 y= 0.099000x-0.000900000 R²=0.998330

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Calibration at Day 30

Conc.(µg/ml)

Are

a R

atio

98

Table 28: Long Term Stability Data of Pioglitazone in Serum

QC Low (2 µg/ml)

Time

Pioglitazone

area 1

IS area 2 Area

ratio

Measured

concentration(

µg/ml)

Mean Accuracy% Stability

%

0 hour 933004 4710001 0.19809 2.01

1.99 98.72 98.50

916224 4700033 0.19494 1.98 97.25

909413 4684555 0.19413

1.97 97.74

30 days 935210 4721139 0.19809 1.97 1.96 100.50

920955 4719945 0.19512 1.95 98.91

926290 4723321 0.19611 1.95 98.50

QCL ± 15%= ±0.3...... (1.97 – 2.30)

QC High (12.8 µg/ml)

Time

Pioglitazone

area 1

IS area 2 Area

ratio

Measured

concentration

(µg/ml)

Mean Accuracy

%

Stability%

0 hour 5958805 4720444 1.26234 12.53 12.5 97.89

99.68 5934047 4719337 1.25739 12.48 97.51

5915547 4712044 1.25541 12.46 97.35

30 days 5745581 4679993 1.22769 12.41 12.46 96.95

5776574 4690110 1.23165 12.45 97.27

5788297 4673333 1.23858 12.52 97.81

QCH ±15% = ±1.92 (10.88-14.74)

Table 29: Long Term Stability Data of Pioglitazine in Stock/Working

Solution

QC Low (2 µg/ml)+ QC High (12.8 µg/ml)

Sample

ID.

Pioglitazone

area at 0

hours

Pioglitazone

area after

30 days

Area

time

30/area

time 0

Stability% Stability average

%

QCL1 935210 930001 0.99443 99.44 99.49

QCL2 920955 919330 0.998236 99.82

QCL3 926290 918997 0.992127 99.21

QCH1 5958805 5801177 0.973547 97.35 98.12

QCH2 5934047 5812229 0.979471 97.95

QCH3 5915547 5860225 0.990648 99.06

99

Table 30: Long Term Stability Data of Internal Standard in Stock/Working

Solution

QC Low (2 µg/ml)+ QC High (12.8 µg/ml)

Sample

ID.

IS area at 0

hours

IS area after

30 days

Area

time 30/

area

time 0

Stability% Stability

average %

QCL1 4783334 4599833 0.961637 96.16 97.32

QCL2 4779222 4701122 0.983658 98.36

QCL3 4765110 4643301 0.974437 97.44

QCH1 4775990 4599981 0.963147 96.31 97.65

QCH2 4783112 4689297 0.980386 98.03

QCH3 4756633 4690218 0.986037 98.60

3.2 Sucralose –Pioglitazone HCl Combination Effect on Pioglitazone HCl Serum

Levels

Rats serum levels of pioglitazone HCl were calculated through serum samples

analysis that obtained from rats groups per day of trials.

On each day of trials: serum samples of overall samples pooling time intervals

were prepared, then analyzed with combined calibration curve simultaneously.

A calibration was run for each samples group of analysis for samples

concentration calculations.

First day trial samples were analyzed and calculations were obtained using its

combined calibration, as shown in figures 10 and 11, tables 31 and 32.

100

Figure 10: First Day Trials Calibration Curve

Table 31: First Day Trials Calibration Curve Data

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1 69194 211054 888665 1282666 2147128 4650648

IS area 2 3434439 3501072 3357176 3018770 3450005 3267527

Area ratio 0.020147 0.060283 0.2647061 0.424897 0.622355 1.423293

RF

0.1051

0.1042

0.1230

0.0993

0.1331

0.0992

Back calculated conc.

(µg/ml) 0.25 0.70 2.99 4.79 6.99 15.98

± 15% of St true

value

0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4

y =0.089190 x- 0.001972 R²=0.997962

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

0 2 4 6 8 10 12 14 16 18

Tria 1 Calibration

Are

a R

atio

Conc.(µg/ml)

101

Table 32: First Day Trial Serum Data

*NA: Not Available

Figure 11: First Day Trial Serum – Time Profile Curve

Second and third day of trials samples were analyzed at the third day of trials

using the same calibration of day 30 long term stability test, as shown in figures 9,12

and 13, table 27, 33 and 34.

0.000

2.000

4.000

6.000

8.000

10.000

12.000

14.000

16.000

0.00 2.00 4.00 6.00 8.00 Co

nce

ntr

atio

n (

µg

/ml)

Time (hr)

Day -1- trials

PG alone

PG+Sucralose

Day-1- trials

PG alone, N=1

PG+Sucralose, N=1

Serum concentration(µg/ml)

Group no. 30 min 1 hr 2 hr 3 hr 4 hr 6 hr 8 hr 24 hr

Group 1

(PG alone)

5.536

10.192 13.013 15.139 10.359 8.541 *NA *NA

Group 2

(PG+Sucralose)

5.726 10.316 11.987 12.982 12.931 9.054 *NA *NA

102

Data was obtained, and then a statistical analysis was carried out to evaluate it in

order to determine acceptance or rejection of intended proposal, as shown in table 35.

Figure 9: Second and Third Day Trials Calibration Curve (Long Term Stability

at Day 30)

Table 27: Second and Third Day Trials Calibration Curve Data(Long Term

Stability at day 30)

Sample ID St1 St2 St3 St4 St5 St6

Concentration(µg/ml) 0.25 0.75 3 5 7 16

Pioglitazone area 1 112973 341691 1608632 2330399 3317295 7594075

IS area 2 4756542 4688983 4718793 4735351 4793017 4817622

Area ratio 0.023751 0.072871 0.340899 0.492128 0.69211 1.576312

RF 0.1021

0.0942

0.1035

0.1083

0.1221

0.0990

Back calculated conc.

(µg/ml) 0.249 0.745 3.453 4.980 7.000 15.931

± 15% of St true

value

0.0375

0.1125

0.45

0.75

1.05

2.4

-15%

+15%

0.2125

0.2875

0.6375

0.8625

2.55

3.45

4.25

5.75

5.95

8.05

13.6

18.4 y= 0.099000x-0.000900000 R²=0.998330

0

0.2

0.4

0.6

0.8

1

1.2

1.4

1.6

1.8

0 2 4 6 8 10 12 14 16 18

Trials 2+3 Calibration

Conc.(µg/ml)

Are

a R

atio

103

Table 33: Second Day Trial Serum Data

Figure 12: Second Day Trial Serum –Time Profile Curve

Table 34: Third Day Trial Serum Data

0.000

5.000

10.000

15.000

20.000

0.00 5.00 10.00 15.00 20.00 25.00 30.00

Co

nce

ntr

atio

n a

vera

ge

(µg/

ml)

Time ( hr)

Day -2- trials

PG alone

PG+ Sucralose

Day-2- trials

PG alone, N=2

PG+Sucralose, N=3

Serum concentration(µg/ml)

Group no. 30 min 1 hr 2 hr 3 hr 4 hr 6 hr 8 hr 24 hr

Group 1

(PG alone)

5.591

10.294

13.143

15.290

13.493

8.626

5.858

0.556

Group 2

(PG alone)

5.656

10.605

13.484

15.352

13.585

8.989

6.070

0.596

Group 3

(PG+Sucralose)

5.736

10.666

12.241

13.130

12.928

8.434

5.045

0.303

Group 4

(PG+Sucralose)

5.783

10.419

12.107

13.112

12.050

8.282

4.949

0.242

104

Day-3- trials

PG alone, N=1

PG+Sucralose, N=3

Serum concentration(µg/ml)

Group no. 30 min 1 hr 2 hr 3 hr 4 hr 6 hr 8 hr 24 hr

Group 1

(PG alone)

5.681

10.671

13.256

15.281

14.095

8.807

5.689

*NA

Group 2

(PG+Sucralose)

5.882

10.544

12.325

12.923

11.713

8.707

5.010

*NA

Group 3

(PG+Sucralose)

5.690

10.581

12.144

13.026

12.826

8.367

5.005

*NA

Group 4

(PG+ Sucralose)

5.737

10.337

12.011

13.008

12.957

8.216

4.910

*NA

Figure 13: Third Day Trial Serum – Time Profile Curve

0.000

5.000

10.000

15.000

20.000

0.00 2.00 4.00 6.00 8.00 10.00

Co

nce

ntr

atio

n (

µg

/ml)

Time ( hr)

Day-3- trials

PG alone

PG+Sucralose

105

Table 35: Serum Data Statistical Analysis Results

[ Serum Concentrations Statistical Results for all Samples (Without Sucralose)](µg/ml)

Time 30 min 1 hr 2 hr 3 hr 4 hr 6 hr 8 hr 24 hr

N 4 4 4 4 4 4 3 2

Range (5.54-

5.60)

(10.19-

10.67)

(13.01-

13.48)

(15.14-

15.35)

(10.36-

14.10)

(8.54-

8.99)

(5.69-

6.07)

(0.56-

0.60)

Mean 5.62 10.44 13.22 15.27 12.88 8.74 5.87 0.58

Std. Error 0.03 0.12 0.10 0.05 0.85 0.10 0.11 0.02

Std.

Deviation 0.066 0.23 0.20 0.09 1.70 0.2 0.19 0.03

[ Serum Concentrations Statistical Results for all Samples (With Sucralose)](µg/ml)

Time 30 min 1 hr 2 hr 3 hr 4 hr 6 hr 8 hr 24 hr

N 6 6 6 6 6 6 5 2

Range (5.69-

5.88)

(10.32-

10.67)

(11.99-

12.33)

(12.92-

13.13)

(11.71-

12.96)

(8.22-

9.05)

(4.91-

5.05)

(0.24-

0.30)

Mean 5.76 10.48 12.14 13.03 12.57 8.51 4.98 0.27

Std. Error 0.03 0.06 0.05 0.03 0.22 0.13 0.02 0.03

Std.

Deviation 0.07 0.14 0.13 0.08 0.54 0.32 0.05 0.04

Concentrations Comparison [ Without Sucralose vs. With Sucralose ] (µg/ml)

P-value

(t-Test)

0.024 E-4 5.48 E-4 0.67 E-4 0.01 E-4 4.86 E-4 1.01 E-4 3.83 E-4

*NA

Means

Difference

-0.14 -0.04 1.09 2.24 0.32 0.23 0.89 0.30

Effect Size

[Cohen’s

d] -2.16 -0.19 6.45 26.43 0.25 0.87 6.34 8.32

percentage

change

between

means % -0.026 -0.004 0.08 0.15 0.024 0.03 0.15 0.53

* NA: Not Available

106

After statistical analysis, data was analyzed and assessed as follow: serum data

after 30 minutes of administration showed a strong significant result as P value was

less than 0.05, while a very small Cohen’s d value was gotten which indicated small

effect size of combination of sucralose on pioglitazone HCl in serum with reduction

percentage of mean concentrations between pioglitazone HCl alone and combined

with sucralose groups equals -2.5%, results represented a medium worthy

combination effect, as shown in figure 14 and table 35.

Figure 14: Dot diagram with error bars for mean comparison of pioglitazone

HCl serum concentration (µg/ml) within 95% of confidence interval between PG

(Pioglitazone HCl alone) and PG plus (Pioglitazone HCl combined with

Sucralose) after 30 minutes of of drug administration.

107

Serum data at 1 hour showed a strong significant result as P value was less than

0.05 with a small Cohen’s d value which indicated small combination effect size of

sucralose on pioglitazone HCl in serum with reduction percentage of mean

concentrations between pioglitazone HCl alone and combined with sucralose groups

equals -0.35%, results showed the absence of any worthy combination effect.

See figure 15 and table 35.

Figure 15: Dot diagram with error bars for mean comparison of pioglitazone

HCl serum concentration (µg/ml) within 95% of confidence interval between PG

(Pioglitazone HCl alone) and PG plus (Pioglitazone HCl combined with

Sucralose) after 1 hour of of drug administration.

108

Serum data at 2 hours showed also a very strong significant result as P value was

less than 0.05 while Cohen’s d value indicated large effect size of combination of

sucralose on pioglitazone HCl in serum, large effect size of Cohen’s d value indicates

the necessity of larger samples size to get more rational P value correlated with

founded large size effect. Reduction percentage of mean concentrations between

pioglitazone HCl alone and combined with sucralose groups equals 8.2%. Results

evaluation represented strong mentionable combination effect, as shown in figure 16

and table 35.

Figure 16: Dot diagram with error bars for mean comparison of pioglitazone

HCl serum concentration (µg/ml) within 95% of confidence interval between PG

(Pioglitazone HCl alone) and PG plus (Pioglitazone HCl combined with

Sucralose) after 2 hours of of drug administration.

109

Serum data at 3 hours showed a significant result as P value was P < 0.05, Cohen’s

d value indicated large effect size of combination of sucralose on pioglitazone HCl in

serum, with a reduction percentage of mean concentrations between pioglitazone HCl

alone and combined with sucralose groups equals 14.64 % which indicated strong

effect of sucralose combination on pioglitazone serum levels, the greatest effect of

combination was obtained at 3 hours, as shown in figure 17 and table 35.

Figure 17: Dot diagram with error bars for mean comparison of pioglitazone

HCl serum concentration (µg/ml) within 95% of confidence interval between PG

(Pioglitazone HCl alone) and PG plus (Pioglitazone HCl combined with

Sucralose) after 3 hours of of drug administration

110

Serum data at 4 hours showed a significant result as P value was less than 0.05

with a Cohen’s d value indication of moderate to small effect size of combination,

with a reduction percentage of mean concentrations between equals 2.44 %, P value

and Cohen’s d values correlation indicates the need of larger samples size to

rationalize between obtained values, as shown in figure 18 and table 35.

Figure 18: Dot diagram with error bars for mean comparison of pioglitazone

HCl serum concentration (µg/ml) within 95% of confidence interval between PG

(Pioglitazone HCl alone) and PG plus (Pioglitazone HCl combined with

Sucralose) after 4 hours of of drug administration.

111

Serum data at 6 hours showed a significant result as P value was less than 0.05

with a Cohen’s d value indication of large to moderate effect size of combination in

serum, which emphasizes the need of larger samples size for obtaining more rational

P value. Reduction percentage of mean concentrations between solitary use of

pioglitazone and combination equals 2.63%, result represented combination effect to

be taken in consideration, as shown in figure 19 and table 35.

Figure 19: Dot diagram with error bars for mean comparison of pioglitazone

HCl serum concentration (µg/ml) within 95% of confidence interval between PG

(Pioglitazone HCl alone) and PG plus (Pioglitazone HCl combined with

Sucralose) after 6 hours of of drug administration.

112

Serum data at 8 hours showed a significant result as P value was ˂ 0.05 with

Cohen’s d value of large effect size (larger sample size is needed).Reduction

percentage of mean concentrations between solitary and combined use equals 15.13%.

Data analysis indicated strong effect of combination, as shown in figure 20 and table

35.

Figure 20: Dot diagram with error bars for mean comparison of pioglitazone

HCl serum concentration (µg/ml) within 95% of confidence interval between PG

(Pioglitazone HCl alone) and PG plus (Pioglitazone HCl combined with

Sucralose) after 8 hours of of drug administration.

113

Serum data at 24 hours showed a Cohen’s d value of large effect size of

combination, with percentage reduction of mean concentrations equals 52.69 %.

Cohen’s d value represented strong combination effect while P value was not

calculated as number of samples was too small, as shown in figure 21 and table 35.

Figure 21: Dot diagram with error bars for mean comparison of pioglitazone

HCl serum concentration (µg/ml) within 95% of confidence interval between PG

(Pioglitazone HCl alone) and PG plus (Pioglitazone HCl combined with

Sucralose) after 24 hours of of drug administration.

114

Cmax showed a significant serum level reduction with P-value = 0.008 E-4 which

indicates statistically significant decrease in pioglitazone Cmax serum concentration.

Cmax showed a value of 15.27 µg/ml with pioglitazone alone administration while it

was reduced to be 13.03 µg/ml when it is combined with sucralose. Effect size of

serum concentration differences was considered as strong due to large Cohen’s d

value, as shown in figure 22 and table 36.

Figure 22: Serum Concentration – Time Profile Graph (0-24) hours of Oral

Administration of Drug,(PG = Pioglitazone HCl alone, PG Plus = Pioglitazone

HCl with Sucralose).

0.000

2.000

4.000

6.000

8.000

10.000

12.000

14.000

16.000

18.000

20.000

0 5 10 15 20 25 30

Ser

um

con

cen

tra

tio

n (

µg

/ml

time (hr)

PG

PG Plus

115

AUC of pioglitazone in serum showed a strong significant P –value equals 0.001,

while difference between AUCs in presence and absence of sucralose was with

reduction of (12.07), as shown in table 36.

Table 36: Serum Concentration – Time Profile Kinetic Parameters

Statistical analysis results showed a statistically significant combination interaction

between pioglitazone and sucralose when both compounds are given concurrently, as

P values represented a strong combination effect, this combination interaction could

be justified according to sucralose induction effect on CYP 450 enzymes, specifically

3A4 subtype by which pioglitazone is extensively metabolized.

Pioglitazone is basically absorbed in stomach where CYP3A4 isoenzymes are

located profusely in parietal cells endoplasmic reticulum, this enzyme will exert its

metabolic biotransformational effect over pioglitazone once absorbed.

On the other hand and after pioglitazone absorption, drug will be metabolized via

another pathway as it will be extensively bounded to plasma proteins then distributed

through the circulatory system to reach the liver where most of metabolic reactions

occur.

Drug C max (µg/ml)

T max (hr)

T ½ (hr)

AUC (µg/ml*hr)

PG 15.27 ±0.03 3 3.6 130.59 ±2.10

PG Plus Sucralose 13.03 ± 0.1 3 3.6 118.52 ±2.90

P value 0.008 P values ˂ 0.05 0.001

116

Induction effect of sucralose over the CYP3A4 metabolic enzyme will also

activate the metabolism of pioglitazone in liver too, which results in pioglitazone

plasma/serum levels reduction and over production of pioglitazone active and inactive

metabolites.

As mentioned before that the active metabolites of pioglitazone have stronger

pharmacological effect than pioglitazone in most cases, thus precise detection and

quantification of pioglitazone active metabolites should be performed to investigate

the further clinical complications that could occur due to high levels of pioglitazone

active metabolites production.

In rats, CYP3A1, 3A2, 3A9, 3A18, 3A23 and 3A62 have been reported as CYP3A

forms. CYP3A23 was classified as identical to CYP3A1 by the analysis of its gene.

CYP3A62 form has been identified as a new rat CYP3A isoenzyme with

expression profile similar to human CYP3A4 and rat CYP3A9. CYP3A62 is a

predominant form in the intestinal tract, where CYP3A1 and -3A2 were found only in

liver (Matsubara et al., 2004).

As recent studies illustrated a distinctive binding affinity variance of pioglitazone

to reactive sites of CYP3A enzymes during metabolic reaction and which justifies its

variable bioavailability between humans and rats, this variance impresses a possible

perceptible clinical differences in pioglitazone human plasma levels when combined

with sucralose, which strongly recommends further clinical research in humans.

117

CHAPTER FOUR

CONCLUSION

118

4. Conclusion

A successful HPLC method was validated and developed to quantify pioglitazone

HCl in rats serum, the method was precise and accurate with rational linearity

performance and reasonable sensitivity and selectivity.

Concerning stability and recovery tests, all obtained results were reasonable and

accepted according to EMEA guidelines.

Combination effect of pioglitazone with sucralose over all time intervals of

pioglitazone serum profile was demonstrated as strong statistical effect according to

Cohen’s d and significant P values too.

Cmax showed a significant change between presence and absence of sucralose

while Tmax didn’t show any change, which suggests the possibility of interaction

between pioglitazone HCl and sucralose during combination.

Advanced clinical research on human volunteers to make more precise results

concerning pioglitazone HCl – sucralose combination interaction is suggested

through the detection and quantification of pioglitazone HCl and its active metabolites

as these metabolites are also pharmacologically active in human body of diabetic

patient ( Tanis et al., 1996 ; Scheen, 2007).

119

5. Appendix: Chromatograms

Figure 23: Serum Blank Chromatogram with IS

120

Figure 24: Serum Blank Chromatogram 1

121

Figure 25: Serum Blank Chromatogram 2

122

Figure 26: Serum Blank Chromatogram 3

123

Figure 27: Serum Blank Chromatogram 4

124

Figure 28: Serum Blank Chromatogram 5

125

Figure 29: Serum Blank Chromatogram 6

126

Figure 30: Piolitazone LLOQ Chromatogram (Peak 1 for Pioglitazone HCl, Peak

2 for IS)

127

Figure 31: Pioglitazone HCl QCL Chromatogram (Peak 1: Pioglitazone HCl,

Peak 2: IS)

128

Figure 32: Pioglitazone HCl QCM Chromatogram (Peak 1: Pioglitazone HCl,

Peak 2: IS)

129

Figure 33: Pioglitazone HCl QCH Chromatogram (Peak 1: Pioglitazone HCl,

Peak 2: IS)

130

Figure 34: Pioglitazone HCl Zero Concentration with IS Chromatogram (IS:

Peak 2)

131

Figure 35: Pioglitazone HCl Unknown Concentration Chromatogram after 30

minutes Oral Administration (Pioglitazone HCl: Peak 1, IS: Peak 2)

132

Figure 36: Pioglitazone HCl Unknown Concentration Chromatogram after 3

hours of Oral Administration (Peak 1: Pioglitazone HCl, Peak 2: IS)

133

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الملخص

‏و‏التي‏سبق‏اعطاؤها‏‏الفئران‏بيوغليتازون‏هيدروكلورايد‏في‏مصلدراسة‏تحليلية‏ذات‏مصداقية‏لمعايرة‏ال

باستخدام‏جهاز‏الاستشراب‏المائي‏عالي‏الاداء‏والطيف‏للضوئي‏للاشعة‏فوق‏البنفسجية‏السكرالوز

اعداد

لينة‏ناصر‏عبد‏الخالق‏التميمي

المشرف‏المشارك‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏المشرف

الدكتور‏وائل‏ابودية‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏‏الاستاذ‏الدكتور‏توفيق‏عرفات

باستخدام‏جهاز‏‏وزلسة‏لتحديد‏البيوغليتازون‏بوجود‏السكرااقد‏تم‏ذلك‏باستخدام‏طريقة‏بسيطة‏وسريعة‏وحس

من‏%‏5..5ناتيرايل‏و‏اسيتو%‏5..5)تم‏استخدام‏خليط‏من‏‏.ي‏الاداء‏والطيف‏الكتليلالاستشراب‏المائي‏عا

مايكروميتر‏ومعدل‏‏5بقطر‏حوالي‏‏.‏العمود‏الفاصل‏نوع‏كربون‏,(تاتيمحلول‏امونيوم‏اسمليمولار‏‏0.0.5

.‏مايكروليتر‏وتم‏استخدام‏السيلدينافيل‏كمعيار‏داخلي‏00وحجم‏الحقن‏للعينات‏كان‏‏(دقيقةل‏مل‏لك.)‏تدفق

‏1..5.يعادل‏‏كيز‏للبيوغليتازون‏وحده‏في‏المصلفقد‏كان‏اعلى‏تر,‏اعتمادا‏على‏النتيجة‏التي‏تم‏الحصول‏عليها

على‏ع‏البيوغليتازون‏ليصبح‏اهذا‏المستوى‏عند‏اقتران‏وجود‏السكرالوز‏م‏بينما‏انخفض,‏ميكروغرام‏لكل‏مل

".ملحوظ‏احصائيا‏ميكروغرام‏لكل‏مل‏وقد‏اعتبر‏هذا‏التاثير‏1.01.يساوي‏‏تركيز‏للبيوغليتازون‏في‏المصل

لمستويات‏البيوغليتازون‏في‏‏ودقة‏قياسات‏التحاليل%(‏5.معدل‏معامل‏التباين‏اقل‏من‏)كانت‏دقة‏القياسات‏عالية‏

تي‏تكفل‏صحة‏طريقة‏التحليل‏استنادا‏الى‏المعايير‏الاوروبية‏المعتمدة‏لقبول‏ضمن‏المعايير‏المقبولة‏ال‏المصل

ازون‏فقد‏كانت‏مطابقة‏للشروط‏كونها‏المنحنيات‏القياسية‏للبيوغليت‏أما‏,طرق‏التحليل‏البيولوجية‏للمحليل‏الحيوية

‏.‏‏.0.0‏تزيد‏عن

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