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Comprehensive Summaries of Uppsala Dissertationsfrom the Faculty of Medicine 1094
_____________________________ _____________________________
A Laparoscopic Approachin Gastro-Oesophageal Surgery
Experimental and Epidemiological Studies
BY
RUNE SANDBU
ACTA UNIVERSITATIS UPSALIENSISUPPSALA 2001
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Dissertation for the Degree of Doctor of Philosophy (Faculty of Medicine) in Surgerypresented at Uppsala University in 2001
ABSTRACTSandbu, R. 2001. A Laparoscopic Approach to Gastro-Oesophageal Surgery: Experimentaland Epidemiological Studies. Acta Universitatis Upsaliensis - Comprehensive Summariesof Uppsala Dissertations from the Faculty of Medicine 1094. 87 pp. ISBN 91-554-5155-1.
The extension of laparoscopic procedures into the chest may induce specificpathophysiologic effects. In pigs, we have demonstrated how devastating a combined thoraco-laparoscopicapproach can be for gas exchange. Furthermore, the transmission of elevated pressureintra-cranially is a potential danger. The application of positive end-expiratory pressure(PEEP) was found to improve gas exchange and, more importantly, hypoxemia could beavoided. The application of PEEP did not increase intra-cranial pressure further; nor did itadversely affect cerebral circulation. Even before the introduction of the laparoscopic technique, there was a substantialincrease in the annual number of antireflux procedures. Therefore, the threefold increase ofthe incidence of antireflux surgery recorded during the past decade cannot solely beexplained by the introduction of minimal access surgery. However, a clear shift in thepreferred methodology took place. This change was not scientifically supported at the timeof the transition and, surprisingly, it is still not supported today. In comparison with opensurgery, patients do not seem to derive significant long-term benefits from having theantireflux procedure done laparoscopically. As was demonstrated, laparoscopy might evenbe an inferior approach in some patients. Nevertheless, it is reasonable to assume thatlaparoscopy can yield equally good results as open surgery despite our failure to confirmthat in our studies. Determination of the effectiveness of minimal access surgery in thetreatment of GORD is critical, before minimal access techniques become the standard forantireflux surgery in the community.
Key words: Gastro-oesophageal surgery, fundoplication, laparoscopy, long-term results,pneumothorax, intra-cranial pressure, positive end-expiratory pressure.
Rune Sandbu, Department of Surgical Sciences, Uppsala University Hospital,SE-751-85, Uppsala, Sweden
Rune Sandbu 2001 ISSN 0282-7476 ISBN 91-554-5155-1 Printed in Sweden by Uppsala University, Tryck & Medier, Uppsala, 2001
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The thesis is based on the following papers, which will be referred to in thetext by their Roman numerals (I-V)
I. Rune Sandbu, Birgitta Birgisdottir, Dag Arvidsson, Ulf Sjöstrand, StenRubertsson. Optimal Positive end-expiratory Pressure (PEEP) settingsin differential lung ventilation during simultaneous unilateralpneumothorax and laparoscopy. An experimental study in pigs.Surg Endosc Published on line 7th September 2001.
II. Rune Sandbu, Ulf Haglund, Harry J. Khamis, Sten Rubertsson. Noadverse effects of PEEP on intracranial pressure or cerebral circulationduring laparoscopy and simultaneous pneumothorax in pigs. Submitted.
III. Rune Sandbu, Ulf Haglund, Dag Arvidsson, Thomas Hallgren.Antireflux Surgery in Sweden, 1987-1997: A Decade of Change.Scand J Gastroenterol 2000; 35: 345-8.
IV. R Sandbu, H Khamis, S Gustavsson, U Haglund. Long-term results ofantireflux surgery: The benefits of the laparoscopic technique underquestion. Accepted for publication, Br J Surg.
V. R Sandbu, H Khamis, S Gustavsson, U Haglund. Laparoscopicantireflux surgery in routine hospital care. Accepted for publication,Scand J Gastroenterol.
Reprints have been made with the permission of the publishers
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Table of contents
Abbreviations ----------------------------------------------------------------------------------- 5Introduction
Historical background ------------------------------------------------------------------------- 7 Technical principles of minimal access surgery-------------------------------------------- 8 Potential benefits of minimal access surgery ----------------------------------------------- 10 Anatomical considerations -------------------------------------------------------------------- 11 Pathophysiology
Pneumothorax and positive end-expiratory pressure (PEEP)----------------- 12Insufflation pressure and intracranial pressure (ICP):Pneumothorax and PEEP ---------------------------------------------------------- 13
Gastro-oesophageal surgery and minimal access approach: An overview-------------- 14Aims of the thesis ------------------------------------------------------------------------------ 20Material and Methods
A. Experimental studies (Studies I and II) Ethical considerations and animals ---------------------------------------------- 21 Method of anaesthesia ------------------------------------------------------------ 21 Technique for separate lung intubation and differential lung ventilation --- 22
Model for combined positive pressure pneumoperitoneumand unilateral pneumothorax------------------------------------------------------ 23
Experimental design -------------------------------------------------------------- 24Monitoring -------------------------------------------------------------------------- 26
B. Epidemiological studies and survey of long-term results on antireflux surgery (Studies III-V)
Methods of survey------------------------------------------------------------------ 29Study design ------------------------------------------------------------------------ 30Patients and ethical considerations (Studies IV and V) ----------------------- 32
Statistical methods --------------------------------------------------------------------------- 33Results and discussion
Study I ------------------------------------------------------------------------------------------ 35 Study II ----------------------------------------------------------------------------------------- 39 Study III ---------------------------------------------------------------------------------------- 42 Study IV ---------------------------------------------------------------------------------------- 47 Study V ----------------------------------------------------------------------------------------- 51
General discussion ---------------------------------------------------------------------------- 58Conclusions -------------------------------------------------------------------------------------- 66Acknowledgements---------------------------------------------------------------------------- 67References ---------------------------------------------------------------------------------------- 68
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Abbreviations
BMI body mass indexCNS central nervous systemCO2 carbon dioxideCO cardiac outputc-pH pH in cerebral cortical tissueCPP cerebral perfusion pressureC stat static lung complianceEpC Centre for EpidemiologyETCO2 end-tidal partial pressure of carbon dioxideGORD gastro-oesophageal-reflux-diseaseICP intracranial pressureLDF Laser-Doppler flow signalMAP mean arterial pressurePCWP pulmonary capillary wedge pressurePEEP positive end-expiratory pressurePaCO2 partial pressure of carbon dioxide in arterial bloodPcCO2 partial pressure of carbon dioxide in cerebral cortical tissuePcO2 partial pressure of oxygen in cerebral cortical tissuePjvO2 partial pressure of oxygen in venous blood from the brainPPI proton-pump inhibitorsSaO2 oxygen saturation in arterial bloodSjvO2 oxygen saturation in venous blood from the brainVCO2 CO2 elimination
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Introduction
Historical background
In 1901, Georg Kelling, a surgeon from Dresden, demonstrated a method he
called “koelioscopie.” The surgeon punctured the peritoneal cavity with a
needle and expanded it with filtered air. He then inserted a trocar into the
abdominal wall and used the trocar to introduce a cystoscope (laparoscope).
This procedure was performed on a live canine during the 73rd Congress of
German Naturalists and Physicians. It was the beginning of the field of
laparoscopy (1-3).
The first major clinical contribution is attributed to the Swedish physician,
Hans Christian Jacobaeus (1910) (4). His initial experience with the
technique was restricted to patients with ascites. He was able to diagnose
syphilis, tuberculosis, cirrhosis and malignancies. Later, Jacobaeus expanded
the limits to include the thoracic cavity (thoracoscopy) (5).
For more than half a century, however, laparoscopy had limited use in clinical
practice. It was chiefly applied in gynaecology as a diagnostic tool and for
tubal ligation. A major problem at that time concerned optics and light
transmission. It was not just a coincidence that the development of general
laparoscopic surgery occurred shortly after the introduction of the computer
chip TV camera. The first reports of successful laparoscopic cholecystectomy
emanated from France in 1987 (6,7).
After 1987, everything happened with incredible speed and a veritable
explosion of laparoscopy into general surgical practice followed. Within a
few years, there was hardly any open intra-abdominal procedure that had not
been attempted laparoscopically (3,8). Enthusiasts predicted by the turn of the
20th century that the majority of general surgery would be performed using
this new approach (9,10). Certainly, for procedures such as cholecystectomy
and Nissen fundoplication, laparoscopy has become the “gold standard”
8
(8,11,12). The matter of securing adequate training and credentialing of
laparoscopic surgeons has become widely debated (13). By contrast, the
question of evaluation of outcomes was virtually bypassed for all procedures
(9,10,14).
When laparoscopy is adopted in the upper abdomen, in particular when the
dissection is extended to the mediastinum, there is substantial risk of
pneumothorax (15-17). The positive insufflation pressure applied in the
abdomen may then be transmitted to the intra-thoracic structures and
fundamentally change the patophysiologic conditions.
This thesis is an attempt to address some of those issues that arise when
laparoscopy is applied in gastro-oesophageal surgery.
Technical principles of minimal access surgery
The denotation “minimal access surgery” refers to all surgical procedures that
apply visualisation through video-endoscopy and limited access, often
through trocars, to perform all or part of the intended procedure.
In this thesis, I will focus on laparoscopy as it is performed at the gastro-
oesophageal junction.
Basic laparoscopic principles and equipment are outlined below:
The main prerequisite for abdominal exposure is establishment of
pneumoperitoneum. Different techniques can be used to gain prime
entrance to the peritoneal cavity: Verres needle, Hasson trocar or
minilaparotomy.
9
Insufflation of carbon dioxide (CO2) is utilised to maintain
pneumoperitoneum. CO2 is a common product of metabolism and its
major advantage is the rapid dissolution in the event of venous gas
embolus. It is also low in cost and highly inflammable. Other gases have
been evaluated (air, O2, He and N2O), but for different reasons they are
less suited for laparoscopy (18-20).
Optimal exposure of the operative field depends on the insufflation
pressure; “the higher pressure, the better view.” However, increased intra-
abdominal pressure is of potential danger to the patient’s safety.
Undesired, but unavoidable side effects, are reduction of the respiratory
minute volume and compression of the vena cava with obstruction of
venous blood return to the heart. Therefore, it is not advisable to apply
pressure higher than 12-15 mm Hg (20-22).
One or several trocars are used to make easy access for the endoscope
and surgical instruments.
Light is transmitted from the light source to the endoscope through light
cables.
Video imaging equipment allows all members of the surgical team to
view the operative field simultaneously.
Most standard abdominal procedures have been translated into equivalent
laparoscopic procedures. Ideally, the difference should be the abdominal
access not the surgical principles.
10
Potential benefits of minimal access surgery
Minimal access surgery offers possibilities to reduce tissue damage because
of the operation. The reduction of surgical stress has been demonstrated in a
decreased inflammatory cytokine response in the early post-operative course
(23-26). The development of post-operative infectious complications (i.e.
wound infections) may be attenuated (27-29).
Patients often experience less pain after laparoscopic procedures and a quick
mobilisation allows for shorter hospital stay. Earlier return to normal
activities and thereby a shorter period of sick leave has repeatedly been
reported for different laparoscopic procedures, i.e. cholecystectomy
(12,30,31), appendectomy (27-29,32,33) and inguinal hernia repair (34-37).
However, when prospective, randomised single-blind comparisons of
laparoscopic versus small-incision cholecystectomy or of laparoscopic versus
open fundoplication have been undertaken, no significant advantages were
found in terms of post-operative recovery (38,39).
A reduced risk of incisional hernia (40,41) and a more acceptable, cosmetic
result may be further arguments in favour of the laparoscopic approach. In
patients in whom one has had the opportunity to inspect intra-peritoneal a
second time, sparse general adhesions have been observed; however, the local
adhesions have often been dense (42,43). It is not known whether the
laparoscopic approach will reduce the risk of post-operative ileus and make
subsequent laparotomy easier. Scientific support for these arguments is
inconclusive.
Economic considerations regarding laparoscopic techniques are not included
in the present thesis.
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Anatomical considerations
The diaphragm constitutes the boundary between thoracic and abdominal
cavities. On the thoracic side, the diaphragm is lined by the pleura and on
abdominal side by the peritoneum. Although these membranes are extremely
delicate, they define the different anatomic compartments. Several important
organs pass between the thorax and abdomen, i.e. the aorta, the caval vein and
the oesophagus. The opening in the diaphragm where the oesophagus passes
into the abdomen is called the hiatus and the slings of diaphragm muscle,
which curves around the oesophagus from right and left to support the hiatus,
is called the right and left crus. With age, the hiatus often becomes wider and
the gastro-oesophageal junction looses its anchoring in the crura. The
proximal part of the stomach may slide up into the mediastinum, with a hiatal
hernia being the result (Figure 1).
Figure 1: Schematic illustration of the gastro-oesophageal junction and hiatal hernia.
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During gastro-oesophageal operations, the surgeon regularly opens the
peritoneum in the hiatal region in order to extend the dissection into the
mediastinum. The proximity of surgical manipulations to cardiac and
pulmonary structures is challenging cardiopulmonary functions and the risk of
peri-operative complications increases. In particular, the mediastinal pleura
might be ruptured during dissection (16,44-47).
Pathophysiology
Pneumothorax and positive end-expiratory pressure (PEEP)
If the pleura is opened and communication to the peritoneal cavity
established, inadvertently or as part of the procedure, a pneumothorax will
result and the negative intra-pleural pressure found during normal inspiration
cannot be maintained.
In open surgery this does not normally constitute a problem because the intra-
pleural pressure will be equal to the pressure in the operating room
(atmospheric or zero pressure) and application of a minimal PEEP will force
the lungs to inflate fully. By contrast, the intra-pleural pressure of a
pneumothorax (or, to be precise, a capnothorax) created during laparoscopy
may equalise the positive intra-peritoneal insufflation pressure and thereby
prevent full inflation of the lung during inspiration. Such an event may harm
the gas exchange.
The application of PEEP has been suggested to counterbalance the
insufflation pressure (16,48). Theoretically, PEEP can improve the ventilation
of collapsed and poorly ventilated alveoli, decrease intra-pulmonary shunt
volumes and, finally, increase systemic oxygen saturation (49). On the other
hand, compliance can be reduced during PEEP because of over-distension of
alveoli, alveolar rupture and surfactant inactivation (49). PEEP induced
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increase in lung volume may cause compression of the small intra-alveolar
vessels, thereby increasing pulmonary resistance (50,51) and decreasing
cardiac output (CO).
It has not been established which combination of insufflation pressure and
PEEP is least harmful for the circulation and gas exchange.
Insufflation pressure and intracranial pressure (ICP):
pneumothorax and PEEP
During laparoscopy, positive-pressure gas insufflation is applied to establish
abdominal distension. This application also induces a significant increase in
intracranial pressure (ICP), a phenomenon which has not been widely
recognised (52-54).
ICP is normally held within narrow limits. The four intracranial
compartments (cerebrospinal fluid, blood, parenchyma, and bone) respond to
changes in one or more of the compartments with reciprocal changes in the
non-osseous compartments to maintain a stable ICP (Monro-Kellie doctrine)
(55). Nevertheless, during rapid increase in one or more compartments,
compensation by the remaining compartments is usually inadequate and ICP
rises. Furthermore, the cranial cavity is not isolated from changes in pressure
of other compartments. Blood and cerebrospinal fluid movements will
transmit changes in intra-abdominal and intra-thoracic pressure intra-
cranially. Elevated intra-abdominal pressure will compress lumbar and
abdominal veins, as well as impair venous return. Central venous pressure
will rise and hence impede venous drainage from the central nervous system
(CNS) with a resulting increase in ICP (53,54,56).
As described in the previous section, application of PEEP is recommended to
correct the negative effects of pneumothorax, if encountered during
laparoscopy. However, potential deleterious effects on the CNS because of
PEEP have been described, though the results from different studies were
14
inconsistent (57-61). In head-injured patients, PEEP resulted in reduction of
mean arterial pressure (MAP) and elevation of ICP, and consequently reduced
cerebral perfusion pressure (CPP) (58). PEEP is thought to increase intra-
thoracic pressure and thereby impair venous return and cardiac filling, which
can lead to reduction of CO and MAP (58-60). These observations were made
in patients or animals with cerebral lesions, where the brain’s ability to
withstand pressure elevations was already challenged.
However, if a communicating pneumothorax is faced during a laparoscopic
procedure in a healthy subject, with reduction of lung compliance and oxygen
saturation, it is not known whether application of PEEP to promote
pulmonary gas exchange would lead to a further increase in ICP and thereby
impairment of cerebral blood flow.
Gastro-oesophageal surgery and minimal access approach:
An overview
Antireflux surgery
Of all gastro-oesophageal surgical procedures, antireflux surgery is at present
the most commonly performed. For this reason, antireflux surgery is best
suited to study how the new technique was implemented in routine hospital
care. The surgical treatment of hiatal hernia is, in principal, the same as for
severe gastro-oesophageal-reflux-disease (GORD). Thus, many of the
following paragraphs can also include the treatment of hiatal hernia.
Two major changes in the management of severe GORD have occurred
during the past decade. For many years, surgical therapy was regarded as
superior (62,63), but with the introduction of proton-pump inhibitors (PPI) in
1989, an alternative and often equally effective medical treatment became
15
available (64-66). The introduction of the laparoscopic technique for
antireflux surgery provided an alternative option. The laparoscopic Nissen
fundoplication was first described in 1991 by both Dallemagne (67) and
Geagea (68). In Sweden, antireflux procedures employing minimal access
surgery were first employed in 1992.
The principles of fundoplication operations include mobilising the lower
oesophagus and to wrapping the fundus of the stomach either partially or
totally around the oesophagus. When the oesophageal hiatus is enlarged, it is
narrowed by sutures in order to preclude the possibility for para-oesophageal
herniation and to prevent the wrap from being pulled up into the chest
(Figures 2A and 2B). The specific techniques for different kinds of
fundoplication and crural closure used in open surgery, i.e. partial anterior
(Watson) or posterior (Toupet) and total fundoplication (Nissen, Nissen-
Rosetti) have been translated into equivalent laparoscopic techniques.
Figure 2: 360 0 (total) Nissen fundoplication with crural closure (A), and
180 0 (partial, posterior) Toupet fundoplication (B).
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Heading (69) estimated a fundoplication rate (number of antireflux operations
per 100,000 inhabitants) of 10 for Scotland for the 5-year period between
1982 and 1986. The remarkable increase in antireflux surgery in recent years,
noted in several European countries, is often attributed to the change in
surgical modality (70). In contradiction, it is generally held that the
indications for surgery remain unchanged, regardless of the surgical technique
(71). Nevertheless, current trends indicate that laparoscopic fundoplication is
being used increasingly as an alternative to maintenance therapy with proton
PPI (11).
Numerous studies have concluded that the short-term outcome after
laparoscopic antireflux procedures is at least as good as for open procedures.
Accelerated painless recovery is achieved without compromising the efficacy
and clinical outcome of the procedure (11). However, published reports are
almost exclusively from specialised centres (72-79), making it difficult to
draw any firm conclusions from these data and applying them to routine
hospital care. The widespread adoption of laparoscopic antireflux surgery by
generalists without special interests in reflux disease can possibly have a
negative impact on the outcome. It has been repeatedly demonstrated that
laparoscopic antireflux surgery has a long learning curve (80-84). Therefore,
it may be hard to achieve the necessary experience and surgical training in
low-volume hospitals.
To our knowledge, there have only been published results from six controlled
randomised trials comparing the outcome after the two techniques. The Dutch
multicentre study was discontinued because of a high incidence of early
dysphagia in the laparoscopic group (85). In a Swedish study with blind
evaluation of the recovery and discharge periods, patients in both groups
stayed a median of three days post-operatively at hospital and no significant
differences were found in the duration of sick leave (39). Good short-term
results after both laparoscopic and open procedures have been reported from
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different Finnish groups in three prospective, randomised studies. They
compared complications, outcome, quality of life and patient satisfaction. In
one study, the patients (n=42) were followed for 2 years; the other reports
were based on a 12-month follow-up (86-88). The different procedures seem
to be equally effective, but the number of patients in each study is too small to
allow any firm conclusions. Both Heikkinen and Loustarinen report that new
on-set dysphagia tended to be more frequent among patients who had had the
antireflux procedure made laparoscopically. A similar finding was reported in
a randomised Swedish study (89).
To our knowledge, long-term follow-up studies have not been done.
Surgeons, as well as patients, seem to prefer the laparoscopic technique and
take it for granted that the effectiveness of laparoscopic and conventional
open approach is comparable (43,90,91).
The goal of antireflux surgery is resolution of all symptoms of gastro-
oesophageal reflux with negligible side effects and no further need for
medical therapy (92,93). To evaluate outcome of antireflux surgery it is
therefore paramount to ask the patients whether they are symptom-free and
satisfied with the results. Exclusion of heartburn, which is the cardinal
symptom of GORD, correlates well with post-operative normalisation of 24-
hour pH monitoring (94). Many patients, however, refuse to participate in
post-operative 24-hour pH monitoring. Moreover, this test is both elaborate
and expensive. The absence of heartburn is fairly reliable in predicting normal
acid exposure on pH testing (94). Several investigators have proposed
disease-specific questionnaires as a tool for follow-up surveys after antireflux
surgery (93-95).
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Cardiomyotomy
The minimal access technique has replaced open surgery in the treatment of
oesophageal achalasia. Laparoscopic Heller myotomy and partial
fundoplication have emerged as the procedure of choice (96,97). From
specialised centres, excellent results have been reported (96,98,99). However,
the disease is seldom occurring and few, if any, units in Sweden will have
enough patients to perform this procedure routinely.
Oesophagectomy
Different techniques for endoscopic oesophagectomy have been employed.
The mediasinoscopic approach to the oesophageus was developed by Buess
and colleagues (100), but its diffusion has remained limited. Several
investigators have reported their experience of oesophagectomy with
thoracoscopy-assisted techniques combined with laparotomy for gastric
mobilisation (101-103). This technique was also adopted at our clinic, but for
the same reasons as reported by others, we abandoned it after a few years
because no reduction in morbidity or mortality could be demonstrated (104-
107). Refinements in technical equipment, i.e. the introduction of a hand-port
system, have made dissection and gastric mobilisation easier to perform
laparoscopically (108). A combined thoracoscopic and laparoscopic technique
was therefore a logical development (109,110). However, contrary to other
advanced surgical endoscopic procedures, endoscopic oesophagectomy has
not yet been convincing and few clinics have included the technique in their
standard repertoire (111).
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Concerning the oncological issue, we now know that performing a radical
lymphadnectomy by the minimal access technique takes longer operating time
and may increase morbidity (111,112).
Gastric resections
Laparoscopic partial gastrectomy for benign diseases and for palliation has
been accepted as an effective surgical option (113). Laparoscopically assisted
resections for malignancies, however, deserve a word of caution. The CO2
insufflation may stimulate tumour proliferation and the risk for port site
metastases has been addressed in several reports (19,114,115). Further
standardisation is needed as well as the definition of correct indications based
on long-term results. In Sweden, the laparoscopic approach is seldom used for
gastric resections (for benign as well for malign disease).
Bariatric methods
Laparoscopic methods for gastric banding and Roux-en-Y gastric bypass are
widely adopted and the new technique has generated further refinements in
the surgical treatment of obesity.
Prospective, randomised studies comparing equivalent open and laparoscopic
methods are few and the little results available are inconclusive (116,117). In
obese patients morbidity, caused by parietal trauma after laparotomy, occurs
in up to 30% (infections and incisional hernias) of the patients (41). These
complications have been encountered only infrequently when applying
minimal access techniques.
In Sweden, obesity surgery is mostly performed at specialised clinics; all of
these clinics have extensive experience in employing the laparoscopic
approach.
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Aims of the thesis
This thesis deals with two principally disparate issues.
First, in part one of the thesis pathophysiology specific for the application of
laparoscopic techniques in gastro-oesophageal surgery is investigated. We
evaluated two possible therapeutic actions (differential lung ventilation and
PEEP) to correct for potential harmful effects (Studies I and II). Second, in
part two the widely applied laparoscopic approach for antireflux surgery is
surveyed as regards implementation and outcome (Studies III-V).
The specific aims of part 1 were to study the following issues during
combined pneumoperitoneum and unilateral pneumothorax in anaesthetised
pigs:
- investigate the effects on cardiopulmonary function (Study I)
- determine whether differential ventilation with varying PEEP on each lung
was beneficial (Study I)
- to evaluate the effects of PEEP on ICP and cerebral blood flow (Study II)
The specific aims of part 2 were as follows:
- analyse whether the new therapeutic options (i.e. the introduction of
proton pump inhibitors (PPI) in 1989 and the laparoscopic technique in
1992) altered the surgical treatment of GORD. Specifically, we sought to
study the change in the frequency of antireflux procedures (Study III)
- to compare the long-term results after conventional open and laparoscopic
procedures (Study IV)
- to compare the long-term results after laparoscopic antireflux procedures
at low- and high-volume hospitals (Study V)
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Material and Methods
A. Experimental studies (Studies I and II)
Ethical considerations and animals
The experimental protocols were reviewed and approved by the Institutional
Review Board of Uppsala University. The animals were treated in conformity
with the Helsinki convention for the use and care of animals (“Principles of
Laboratory Animal Care” and “Guide for the Care and Use of Laboratory
Animals,” National Institute of Health Publication No. 80-23, revised 1985).
Thirty male and female Swedish Landrace piglets 11-14 weeks of age, with a
mean weight of 24 2 kg (range 21-30 kg), were studied. The animals were
fasted overnight with free access to water and delivered by the same supplier
directly to the laboratory on the morning of the experiment. After the
completion of the experiment, when the animals still were anaesthetised,
cardiac arrest was induced with intravenous injection of potassium chloride.
Method of anaesthesia
Anaesthesia was accomplished with an intramuscular injection of 3mg/kg
tiletamine + 3mg/kg zolazepam (6 mg/kg Zoletil®, Virback Lab., France),
2mg/kg xylazine (Rompun®, Bayer, Germany) and atropine 0.04mg/kg
combined with an intravenous bolus injection of 1 mg/kg morphine.
Anaesthesia was maintained with a continuous infusion of 20 mg/kg/h
22
ketamine and 0.48 mg/kg/ h morphine (118). Muscular blockade was
maintained by continuous intravenous infusion of pancuronium bromide, 0.24
mg/kg/h. Tracheotomy was performed and mechanical ventilation initiated
with an I:E ratio of 1:1, FiO2 of 0.4, respiratory rate 25 per minute and PEEP
5 cm H2O (Servo ventilator 900C, Siemens-Elema, Sweden). Minute
ventilation was adjusted to maintain PaCO2 between 5.0 and 5.5 k Pa.
To compensate for fluid losses throughout the study, an intravenous bolus of
50-200 ml dextran 70 (Macrodex ® 6%, Fresenius Kabi AB, Sweden) was
administered before commencement of the interventions, aiming at a
pulmonary capillary wedge pressure (PCWP) of 8-10 mm Hg. This was
followed by a continuous intravenous infusion of a balanced crystalloid
solution with 2.5% glucose, 10 ml/ kg/h.
Technique for separate lung intubation and differential lung ventilation
(Study I)
Each lung was intubated separately. In the pig, the bronchial tree differs from
human anatomy (119). Pigs have a separate bronchial branch to the right
upper lobe, and this branch goes directly from the trachea, proximal to the
carina.
First, the larger 8 mm endotracheal tube was positioned with its tip
immediately above the bronchial branch to the right upper lobe. To achieve
separate intubation and differential ventilation, the left bronchus was
intubated through the wide bore tube with a 5 mm outer diameter
endotracheal tube. This tube was advanced over a 3.5 mm bronchoscope to
ensure optimal placement (Figure 3). After the cuffs were inflated, both tubes
were connected to separate ventilators.
23
Figure 3: Schematic illustration of separate lung intubation in pigs.
Model for combined positive pressure pneumoperitoneum and unilateralpneumothorax (Studies I and II)Two trocars (5 mm) were introduced: one intraperitoneally and the other into
the right pleural space to accommodate gas insufflation. The trocars were
connected to a common gas insufflator (Pelvi-Pneu CO2, WISAP, Germany)
and the pressure was monitored with an aneroid manometer. During the
experimental intervals, CO2 was insufflated with a common pressure applied
to both trocars in the abdomen and in the right haemithorax, and thereby
pneumoperitoneum and unilateral pneumothorax under equal positive
pressure were achieved (Figure 4).
24
Experimental design
Study I
The model for combined positive pressure pneumoperitoneum, unilateral
pneumothorax and differential lung ventilation was used. Different
combinations of PEEP on right and left lung were evaluated. The rationale for
the application of PEEP was to decrease the pressure gradient between the
peritoneal and pleural cavities during inspiration and expiration so that the
lungs inflate completely. We hypothesised that the optimal respiratory
technique would be differential lung ventilation. We assumed that PEEP
applied in the lung with pneumothorax had to be equal to or exceed the CO2
insufflation pressure. To avoid harmful effects that might be related to
prolonged and elevated PEEP, we decreased PEEP on the lung without
pneumothorax.
An experimental cycle was initiated by insufflating CO2 with a pressure of 10
mm Hg applied to both trocars. During this period, right and left PEEP
settings of 10(right)/5(left), 10/10, 15/5, 15/10 cm H2O were used by random
assignment. The same PEEP setting was applied for the next 20 minutes with
no adjustments of the ventilators. Measurements were recorded at the end of
each interval. The gas insufflation was then turned off. The pneumothorax
and the pneumoperitoneum were evacuated and a period of haemodynamic
and respiratory stabilisation was allowed. Thereafter, a new experimental
cycle was started with another combination of PEEP.
In a pilot study, with a PEEP setting of 5/5 cm H2O, extremely high airway
pressures, exceeding 90 cm H2O, were recorded. This resulted in severe
deterioration of blood gases, which was hard to overcome despite long
recovery periods. Therefore, the PEEP combination of 5/5 was always applied
at the end of the experiment. During the study, it became clear that a higher
PEEP on both lungs was favourable, and for the last four animals, an
additional cycle with a PEEP setting of 15/15 was inserted before 5/5.
25
Figure 4: Experimental set-up in Study I (combined right pneumothorax andpneumoperitoneum with differential lung ventilation).
Study II
In this study we examined the changes in ICP and cerebral circulation in a
similar model as described above but without differential lung ventilation. We
hypothesised that application of PEEP to counterbalance the insufflation
pressure would be beneficial for pulmonary gas exchange, but increase ICP
and consequently impair cerebral blood flow.
In the control group (n=11) we analysed changes in ICP, cerebral circulation
and blood gases. Carbon dioxide insufflation pressures of 5, 10, 15 or 20 mm
Hg were randomly assigned and applied for 20 minutes during the
intervention period. PEEP was kept at 5 cm H2O.
In another eight piglets the experiment was similar, except PEEP was adjusted
to a value equal to the insufflation pressure of CO2 during the intervention
periods (PEEP group, n=8).
26
In all animals the experiment consisted of four test intervals with intermediate
recovery periods.
Monitoring
Haemodynamic monitoring (Studies I and II)
Intra-vascular catheters were placed surgically. A catheter (16 G) was inserted
via a branch of the right external carotid artery into the aortic arch for
recording of MAP and sampling for arterial blood gas analysis. A pulmonary
artery catheter (7 Fr) was introduced via the right external jugular vein into
the pulmonary artery for measurements of CO and PCWP. Intra-vascular
pressures and ECG were monitored continuously (Solar 8000, Marqutte
Hellige, USA). Blood samples were analysed in a blood gas analyser (ABL5,
Radiometer, Denmark) and in a Haemoxymeter (OSM3, Radiometer,
Denmark). In Study II a catheter (20 G) was also inserted into the left internal
jugular vein and passed retrogradely into the jugular bulb for blood sampling,
for measurements of oxygen saturation and for partial pressure (SjvO2 and
PjvO2).
Respiratory monitoring (Studies I and II)
A respiratory profile monitor (CO2SMO+, Novametrix Medical Systems, Inc.,
Wallingford, Connecticut, USA) was connected to the ventilator for
monitoring of end-tidal carbon dioxide levels (ETCO2), CO2 elimination
(VCO2) and static compliance (C stat).
In Study I two ventilators with two separate respiratory profile monitors were
used.
Intracranial monitoring (Study II)
Paratrend® catheter: The probe incorporates optical fibres for the
measurements of PCO2 and pH, an electrochemical sensor for PO2, and a
27
thermocouple for measurements of temperature (Paratend-7®, Biomedical
Sensors LTD, High Wycombe, England). The cylindrical construction of the
sensor allows measurements over the entire surface of the probe, the diameter
of which is 0.5 mm. The four sensor components are located at intervals along
the distal 4 cm of the polyethylene probe, which is permeable to O2 and CO2.
The outer surface of the probe is coated with covalently bonded heparin to
prevent deposition of fibrin. The monitor continuously displays pH, PCO2,
PO2 and temperature. Although originally designed for measurement of
arterial blood gases, Paratrend-7® has also been validated for measurements in
cerebral tissue (120-122).
The Paratrend® catheter was inserted through a Camino® bolt (Camino
laboratories, San Diego, USA) fitted into a right parietal burr hole and
positioned 4 cm into the brain for measurement of cerebral cortical tissue
PO2, PCO2, and pH (PcO2, PcCO2 and c-pH) (Figure 5).
Camino® pressure transducer: ICP was measured by a Camino® pressure
transducer inserted through a 2-mm burr hole approximately 1 cm anterior to
the Paratrend® probe (Figure 5).
Periflux® laser-Doppler flowmetre: For continuous measurement of cerebral
cortical blood flow, a Laser-Doppler flow probe (Flexible Straight Probe 320,
Periflux® laser-Doppler flowmetre PF 2B, Perimed, Stockholm, Sweden) was
introduced through a 2-mm burr hole 1 cm anterior to the coronal suture. The
probe was placed on the surface of the brain cortex (Figure 5).
The flow estimate with this technique is based on the Doppler effect induced
by moving erythrocytes to low-power laser light. Light (with a wavelength of
632.8 nm) from a 2-mV helium neon laser is guided to the tissue by a light
conductor, which also serves to transmit the back-scattered light to the
photodetector system. There is a frequency shift when the laser light has
interacted with moving tissue elements. The bandwidth of the Doppler-shifted
28
frequencies increases proportionally to the velocity of erythrocytes. The
signal amplitude reflects the microcirculation.
The Laser-Doppler probe has been validated for flow measurements in the
CNS; good correlation was reported with flow changes detected by the
microsphere technique (123,124). Its accuracy in monitoring changes in
cerebral cortical blood flow has also been validated during the low flow state
after induction of cerebral ischaemia (125).
The Laser-Doppler flow signal (LDF) was registered as online printout. The
measurements of each animal were recorded as a fraction of the steady state
baseline level, which was designated as 1.0.
Cerebral perfusion pressure (CPP) was calculated as the difference between
MAP and ICP (MAP-ICP = CPP).
Figure 5: Schematic illustration of the placement of the Paratrend® catheter (A), Camino®
pressure transducer (B) and Periflux® laser-Doppler flowmetre (C).
29
B. Epidemiological studies and survey of the long-term results
of antireflux surgery
Methods of survey
EpC (Studies III-V)
The Centre for Epidemiology (EpC) at the Swedish National Board of Health
and Welfare administers a register of all in-patient public hospital care in
Sweden (126). This register, which is updated each year, became fully
comprehensive in 1987. Data of all surgical procedures are publicly available
while patient identification numbers are protected. The ICD-9 (WHO)
classification of diagnoses is applied and operations are coded according to
the Swedish Classification of Surgical Procedures.
Questionnaire to the heads of all surgical departments (Study III)
To validate the information obtained from EpC we mailed a questionnaire on
antireflux surgery to the heads of all surgical departments in Sweden. The
question was whether the department performed any antireflux surgery, and,
if so, the number of open and laparoscopic procedures for 1995 and 1996.
Pre-operative evaluation and indications for surgery were not addressed in
this study.
Questionnaire to patients (Studies IV and V)
A questionnaire devised to identify typical symptoms of GORD and post-
operative side effects of antireflux surgery was mailed to all patients included
in the studies.
The questionnaire included items on heartburn, acid regurgitation, medical
treatment, dysphagia, gas bloat, ability to belch and vomit, as well as an
30
overall estimate of satisfaction. We specifically asked about revision surgery
and complaints that could be related to the scars. The usefulness of the
questionnaire was validated on 136 patients before the study was undertaken
(127).
Study design
Study III
Age, gender, county of residence for each patient, information regarding the
numbers and the kind of antireflux procedures, the duration of hospital stay
and the post-operative mortality rate were analysed for the period from 1987
to 1997 using data obtained by the EpC. We have compared the surgical
activity in different health service regions (counties) and among different
hospitals over the years. Fundoplication rates for each county are calculated
and adjustments are made for variations in the population.
Information from the questionnaire that was sent to heads of all surgical
departments was compared with data obtained from EpC in order to validate
the latter.
Study IV
Long-term outcome after laparoscopic and conventional open antireflux
procedures were compared by administering a questionnaire to the patients 4
years after surgery. We hypothesised that the open and the laparoscopic
techniques were equally effective in controlling symptoms and providing
patient satisfaction. The success rate was estimated to be 85-95% (77).
Sample sizes of approximately 180 patients were necessary to detect a
difference of 10% in failure rate in a two-tailed test with a significance level
of 5% and statistical power of 85%. The response rate was estimated to be
between 80 and 90%.
31
The study period took place between 1995 and 1996. In an effort to have
uniform study groups we selected those hospitals where more than 50 patients
had been operated on by one of the techniques. Two random samples of
approximately 230 patients in each group were thus identified for study
purposes.
Study V
Long-term results after laparoscopic antireflux procedures performed at low-
and high-volume hospitals were compared using a questionnaire 4 years after
surgery. The study period was the same as in the previous study, i.e. 1995 and
1996.
We hypothesised that the long-term results were equally good for patients
operated on at low- and high-volume hospitals. Calculation of sample size
was similar to study IV. All 220 patients operated on at low-volume hospitals
and a computerised random sampling of 225 patients operated on at high-
volume hospitals was identified for study purposes.
Definition of treatment failure (Studies IV and V)
The main endpoints in Studies IV and V were treatment failure and patient
satisfaction. Treatment failure was defined by the presence of one or more of
three criteria:
a new antireflux procedure had been required to control symptoms or to
relieve side effects
medication was taken at least once a week specifically to relieve heartburn
or acid regurgitation
patient dissatisfaction with the result of surgery
32
Patients and ethical considerations (Studies IV and V)
The study protocol was approved by the local ethics committee in science at
Uppsala University. Permission to obtain the identification numbers and
addresses was provided by the Centre for Epidemiology (EpC). None of the
patients included in Studies IV and V were treated at the authors’ department.
The questionnaires were treated anonymously and confidentially. The patients
were also informed of their freedom to choose to participate in the study and
that no financial compensation would be given. Non-responders received a
second survey. Heads of those surgical departments that took part were
informed about and approved of the study.
33
Statistical methods
Study I
A Two-way, Randomised Block design was performed for each outcome
variable to determine if the mean outcomes of the four randomised treatments
differed significantly from one another.
In addition, comparisons were made between the mean outcome averaged
over the four randomised procedures, the mean outcome at baseline and the
mean outcome for procedure “5/5.”
For treatment “15/15,” which was applied only for the four last animals, a
purely descriptive comparison of the average outcomes was employed.
Study II
A multivariate repeated measures analysis of variance (MANOVA) was used,
with the different settings of insufflation pressure serving as a within factor
and PEEP serving as a between factor. For SaO2, the standard analysis was
inappropriate because of severe skewness of the data. Therefore, a repeated
measures analysis of variance was performed on the ranks of the SaO2 values,
and the Wilcoxon rank sum test for two independent samples was
subsequently used to compare the median SaO2 values between the two
groups.
Studies I and II: A residual analysis was performed to confirm that the
underlying model assumptions were met by the data. P values of less than 0.05
were defined as significant. The Bonferroni correction was used to ensure that
the overall Type 1 error rate did not exceed 0.05.
34
Study III
In Study III, simple descriptive methods were used, i.e. number, percent,
proportion and median.
Studies IV and V
Comparison of questionnaire items between the groups was conducted using a
logistic regression with sex, age, and body mass index (BMI) serving as the
covariates. The Bonferroni correction was used to control the overall Type 1
error rate at 0.05. Comparisons of age, sex and BMI between the groups were
conducted using t tests and the chi-squared test.
35
Results and discussion
Study I
Results
When a communicating pneumo-pleuro-peritoneum was established with CO2
insufflation pressure of 10 mm Hg in anaesthetised pigs, the following major
observations were noted:
increased PCWP
hypercarbia, respiratory acidosis and increased CO2 elimination
hypoxemia
The hypoxemia could be corrected and the acidosis considerably reduced if
adequate PEEP was applied on both lungs (Figures 6 and 7). The blood gases
were close to normal when PEEP in both lungs exceeded the CO2 insufflation
pressure. If there was a difference in PEEP between the lungs, there was a
tendency to simultaneous decrease in C stat, ETCO2 and VCO2 in the lung
with the lower PEEP, even in the presence of hypercarbia as measured by
blood gas analysis. Haemodynamic outcomes were relatively stable.
36
PEEP settings
Figure 6: Arterial oxygen saturation (SaO2) at baseline and at different
combinations of PEEP in right and left lung (dx/sin).
PEEP settings
Figure 7: pH at baseline and at different combinations of PEEP in right and
left lung (dx/sin).
60
65
70
75
80
85
90
95
100
105
SaO
2 %
Baseline 10\5 10\10 15\5 15\10 15\15 5\5
7,2
7,25
7,3
7,35
7,4
7,45
7,5
7,55
pH
Baseline 10\5 10\10 15\5 15\10 15\15 5\5
37
Discussion
It is well known that CO2 is absorbed transperitoneally during laparoscopy
(128,129). The degree of hypercarbia and acidemia that is induced depends on
CO2 insufflation pressure, peritoneal area available for gas exchange and
respiratory compensation (49). At an insufflation pressure of 10 mm Hg, the
changes are usually moderate and are clinically well tolerated both in humans
(49) and in pigs (130). With a communicating pneumo-pleuro-peritoneum, a
larger surface area will be exposed. More CO2 may be absorbed with a
concomitant increase in hypercarbia and acidosis. With positive pressure in the
pleural cavity, as in our model, a pneumothorax may further aggravate the
condition because of collapse of lung parenchyma and impaired gas exchange.
Shunting of blood in the collapsed lung parenchyma may result in hypoxemia
and CO2 retention (130,132). CO2 is more soluble and crosses from the blood
into the alveoli 25 times faster than oxygen (49). Impaired gas exchange is
therefore first noted in reduced oxygenation rather than increasing hypercarbia,
even in the presence of an abnormal amount of systemically dissolved CO2.
We observed a significant difference in PaO2 between the four randomised
treatments, but not in PaCO2.
Tension pneumothorax refers to a pneumothorax characterised by an increased
intra-pleural pressure that is caused by an opening through the pleura allowing
air to pass in but not out. An increasing intra-thoracic extra-pulmonary
pressure can cause the lung to collapse and even push the structures in
mediastinum to the other side (mediastinal shift). In a strict sense the
pneumothorax of our model is not a tension pneumothorax, but it has a positive
intra-thoracic pressure and thus a tension-like pathophysiology may result.
It is unclear whether cardiovascular collapse observed during tension
pneumothorax is secondary to a direct compressive effect on central venous
structures with reduced preload to the heart, or secondary to grave hypoxemia
38
that is caused by lung parenchymal collapse with shunting of desaturated
blood, or a combination (49,131). In our study severe hypoxemia, hypercarbia
and respiratory acidosis developed without significant changes in HR and
MAP. This finding led us to conclude that hypoxemia is an early sign of
impaired gas exchange in ventilated pigs with pneumothorax. This position is
in accordance with the findings of Barton and colleagues in an experiment with
progressive pneumothorax, where SaO2 decreased immediately and continued
to decline to levels below 50% before cardiovascular collapse (131).
We initially hypothesised that the optimal respiratory technique during
laparoscopy with communicating unilateral pneumothorax would be
differential lung ventilation with different PEEP on left and right lungs. On the
side of the pneumothorax, we thought that PEEP had to equal or exceed the
CO2 insufflation pressure to avoid lung parenchymal collapse and poor
oxygenation. To minimise harmful side effects we tried to keep a lower PEEP
on the contra-lateral lung.
Our hypothesis, however, was not completely supported. To counterbalance
the positive insufflation pressure it seemed correct to apply an equal or larger
PEEP. However, this PEEP had to be applied to both lungs to avoid
deterioration of gas exchange. No beneficial effects of differential application
of PEEP were documented.
39
Study II
Results
This study demonstrated that the establishment of positive pressure
pneumo-pleuro-peritoneum resulted in immediate elevation of ICP. The
magnitude of the increase in ICP was proportional to the increase in
insufflation pressure (Figure 8).
CPP decreased, but LDF remained unchanged (Figures 8 and 9). There
were no obvious metabolic signs of cerebral ischaemia. However, arterial
and venous jugular bulb desaturation developed unless PEEP was matched
to counterbalance the insufflation pressure (Figure 10).
Application of PEEP prevented arterial hypoxemia and hypercapnia;
moreover, a less pronounced decrease in pH was observed (Figures 10 and
11).
Changes in ICP, CPP, and cerebral oxygen extraction ratio did not differ
significantly between the study groups. Hence, PEEP did not adversely
affect ICP or cerebral circulation (Figure 8).
We did not succeed in obtaining reliable and reproducible measurements of
PcO2. The variation between initial baseline values in different animals and
between baseline measurements at different times during the same experiment
was pronounced and unsystematic, often yielding no measurement at all. The
problem with the oxygen sensor of the Paratrend® probe has also been
experienced in similar experiments in our laboratory (133). Nevertheless,
because of regular blood sampling from the left jugular bulb catheter, we
obtained measurements of saturation and partial pressure of oxygen in venous
blood from the brain (SjvO2 and PjvO2). We could then calculate the cerebral
40
oxygen extraction ratio as the ratio of the arterial jugular bulb oxygen content
difference to the arterial oxygen content [(CaO2 – CjvO2)/CaO2].
The Laser-Doppler probe was found sensitive to adjustments in location. In
five animals measurements of cortical blood flow were inaccessible because
we were unable to establish stable baseline values.
41
Figure 8
Figure 9
ICP and CPP in control (-) and PEEP group (+)
0102030405060708090
100
0 5 10 15 20Insufflation pressure (mm Hg)
ICP
and
CPP
(mm
Hg)
ICP -ICP +CPP -CPP +
Laser-Doppler flow (LDF) in control (-) and PEEP group (+)
0
0,5
1
1,5
2
0 5 10 15 20Insufflation pressure (mm Hg)
LDF
(frac
tion
of th
e ba
selin
e)
LDF(-)LDF(+)
42
Figure 10
Figure 11
SaO2 and SjO2 control (-) and PEEP group (+)
0
20
40
60
80
100
0 5 10 15 20Insufflation pressure (mm Hg)
SaO
2 an
d Sj
O2
% SaO2-SaO2+SjO2+SjO2-
a-pH and c-pH in control (-) and PEEP group (+)
6,8
6,9
7
7,1
7,2
7,3
7,4
7,5
0 5 10 15 20Insuff lation pressure (mm Hg)
a-pH
and
c-p
H a-pH-
a-pH+
c-pH-
c-pH+
43
Discussion
In our study the increase of ICP was immediate and proportional to the
increase in insufflation pressure. The difference in PaCO2 between the control
and the PEEP group was significant, but LDF remained at the same level and
the elevation in ICP did not differ between the groups. These results verify the
observations of Halvorsen and co-workers. In their study baseline ICP was 14
(±2) and increased to 30 (±5) mm Hg at 15 mm Hg pneumo-peritoneum. This
increase was independent of changes in PaCO2 and pH (54). It is also in
accordance with the data from Schöb and his colleagues who tested different
insufflation gases in pigs (134). The increase in ICP with increasing
insufflation pressure has been described during laparoscopy in humans
(135,136).
Although the increased ICP constitutes a sign of warning, in clinical practice
the most important factor is whether the cerebral circulation is compromised.
Specifically, brain tissue oxygenation must be ensured. Even a brief period of
inadequate perfusion of brain tissue leads to intense production of lactic acid
(metabolic acidosis) (137). In an experimental study of cardiopulmonary
resuscitation five minutes of cardiac arrest resulted in c-pH of 6.3-6.6 though
a-pH was not below 7.4 (133). In our study the acid-base buffering capacity
of the brain was not exhausted. No cortical metabolic acidosis was detected
because cortical oxygenation was probably sufficient to meet local demands.
Autoregulation of cerebrovascular resistance to blood flow can prevent large
fluctuations in cerebral circulation despite large variations in systemic blood
pressure (137). In the normal cerebrovascular bed cerebral blood flow can be
maintained in the face of rising ICP until the difference between MAP and ICP
falls to about 40 mm Hg (137-139). Moreover, because oxygen supply is
usually superfluous and the cerebral extraction ratio is low, the brain can,
during periods of compromised circulation, increase the oxygen extraction
44
ratio (133,137). Recent studies suggest that SjvO2 correlates better with
cerebral oxygenation than CPP (140-143). Our study verified that cortical
cerebral blood flow could be maintained despite a reduction in CPP.
Nevertheless, in the control group (pneumo-pleuro-peritoneum without
compensatory PEEP), SjvO2 was extremely low and the oxygen extraction
ratio was close to its upper limit when insufflation pressures of 15 and 20 mm
Hg were applied. Jugular venous oxygen saturation below 50% can be
interpreted as a sign of global brain hypoxia (144), indicating that the
compensatory mechanisms were nearly exhausted. PEEP enhanced arterial
oxygenation and thereby could augment the oxygen supply to the brain.
This study was conducted on young and healthy pigs. However, one should be
careful in interpreting the results and then applying them in clinical situations.
Our patients are often elderly with cardiopulmonary impairment, a condition
that renders them far more sensitive to an insult such as combined pneumo-
pleuro-peritoneum. The study verifies that the acute problem of pneumothorax
during ongoing laparoscopic surgery (i.e. fundoplication, cardiomyotomy,
oesophageal resection and bariatric procedures) may be corrected by
application of PEEP. PEEP may help to ensure good oxygenation, CO2
elimination and avoidance of cerebral hypoxemia.
Study III
Results
A good correlation was found between data obtained from EpC and the
answers to the questionnaire from the heads of the surgical departments that
participated in the study. We concluded that the data in EpC were reliable.
Therefore, data collected exclusively from EpC are used in the following
analysis.
45
The increase in the annual number of antireflux procedures was almost
threefold during the study period (Figure 12). In 1987, 456 antireflux
procedures were performed. Ten years later, this figure had risen to 1,303. The
fundoplication rate rose from an average of 5.5 to 12.3/100,000 inhabitants
during a 10-year period.
The variation in operative volume among hospitals was also pronounced; we
found that most hospitals operated on fewer than 15 patients during the study
period.
The length of hospital stay has decreased for both open and laparoscopic
procedures. Mean hospital stay was 12.2 days in 1987, whereas in 1997 it was
3.0 days for laparoscopic and 7.9 days for open surgery. Furthermore, we
observed a large variation among hospitals regarding the length of hospital
stay.
GORD was registered as the diagnosis in 270 procedures (43.9%) among
those patients who had an antireflux procedure or a hiatal hernia repair carried
out in 1987; 406 procedures (66.0%) were diagnosed as hiatal hernia. Thus,
the diagnosis of hiatal hernia was more frequently adopted than GORD. Ten
years later, 1,143 patients (84.4%) were given a diagnosis of reflux and 242
(17.8% were classified as hiatal hernia. Only one (0.03%) laparoscopic
antireflux procedure has been associated with a fatal outcome since its
introduction in 1992.
46
Figure 12: Annual numbers of antrireflux procedures in Sweden, 1987-1997.
Discussion
The annual numbers of surgical procedures performed to correct GORD and
hiatus hernia have changed dramatically and inversely during the study period.
The explanation is more likely a shift in nomenclature than an actual change in
the frequencies of the different diseases.
The increase in the fundoplication rate started before the introduction of
proton-pump inhibitors and continued even more pronounced during the
following few years. The development of laparoscopic antireflux surgery did
not alter the course of this increase. The present study shows that soon after its
introduction the laparoscopic technique replaced the open procedure as the
0200400600800
100012001400
87 88 89 90 91 92 93 94 95 96 97
LaparoscopicOpen
47
preferred method. This change occurred before the proposed benefits of
laparoscopy were clearly documented.
The length of hospital stay has also been considerably reduced during the study
period for open surgery, from 12.2 to 7.9 days, on average, illustrating the
problem with historical controls.
The fundoplication rates varied greatly among health service regions.
However, there is no reason to believe that the prevalence of GORD is
different (145). On the other hand, no one can define the most optimal or even
a reasonable fundoplication rate. It might be that the often quoted annual
number of 10 antireflux operations/100,000 (69) is far too low.
Study IV
Results
Failure and dissatisfaction were significantly more common in the laparoscopy
group than in the laparotomy group. Treatment failure rates were 29.0% in the
laparoscopy group and 14.6% in the laparotomy group (p<0.004). The
dissatisfaction rates were 15.0 and 7.0% in the laparoscopy and laparotomy
group, respectively (p<0.005). We could not recognise any item in which the
patients receiving the open technique had an overall significantly worse
outcome.
An estimated 19.5% of the patients in the laparoscopy group and 8.6% in the
open group reported that they used medication at least once a week specifically
to relieve heartburn or acid regurgitation (p<0.02). Most of them used
medication every day, and in case of medication, 75% used PPI.
Gas bloat or flatulence was reported as the most bothersome abdominal
complaint by 39.7% of all the patients. Only 2.1% (8 patients) considered
48
dysphagia as their most bothersome symptom, although 9.0% (33 patients)
reported daily episodes of difficulties in swallowing food.
Discussion
In this study the high overall failure rate is primarily a result of the high
proportion of patients who continue to use medication to relieve heartburn or
who are dissatisfied. It is obvious that the definition of treatment failure has
influenced the reported results. This is discussed in more detail in a later
section (General Discussion). A more restrictive definition of failure will
reduce the number of procedures that are classified as failures; however, there
will still be a marked difference between the results after laparoscopic and
open procedures.
The results in the laparoscopic group are worse than most of the literature
suggests (72-74,78,79,146), but they are not extreme (43,147-149). It should
also be noted that the results obtained from population-based studies, as ours,
are often inferior to what is reported from selected specialised centres.
At a 2-year follow-up after laparoscopic fundoplication, Soper reported that
26% of the patients had symptoms suggestive of persisting gastro-oesophageal
reflux (43). Anatomic failure of the procedure was documented in 7% and in
2.8% surgical revision was required. The incidence of redo after a primary
laparoscopic approach is usually about 2-6% at short-term follow-up (11).
Most remarkably, the group at Adelaide University noted 12.7% repeat
operations in their 5-year follow-up of 178 consecutive laparoscopically
operated patients (148). More than half of the surgical failures were due to
intra-thoracal herniation. This complication is seldom reported after open
surgery, but is frequently encountered after laparoscopic procedures (42,150).
The design of the present study does not allow us to explore the findings at
49
redo procedures and thus we cannot determine whether intra-thoracal
herniation is a usual cause for surgical failure in Sweden. There are no data
available in the literature to suggest that the surgical failure rate is higher after
laparoscopic fundoplication than after the open approach. In the present study
revision surgery was reported in 5-6% in both groups.
The long learning curve of laparoscopic antireflux surgery may be a
confounding factor (80-83). However, laparoscopic antireflux surgery had
been performed for more than 3 years in Sweden and 950 procedures were
accomplished before the study period (Study III). In addition, the patients were
selected only from those hospitals with high activity in laparoscopic antireflux
surgery. Even though this was an inclusion criteria of the study, it may also be
a bias. An increasing incidence of antireflux surgery may tend to lower the
threshold for accepting patients for surgery (78,90,151). In their enthusiasm
over the new approach, surgeons undertaking laparoscopic procedures may
have operated on patients with less convincing symptoms of GORD. In the
1990s, it was a trend to focus more on technical skills in laparoscopic
handicraft than on the experience of antireflux surgery. Thus, laparoscopic
surgeons at many hospitals took over antireflux surgery from specialised
thoracic and oesophageal surgeons (91). In the beginning, surgeons may have
found it difficult to accomplish an equivalent antireflux procedure by
laparoscopy as in open surgery (152). “Minor” adjustments of the antireflux
procedure could have been made, i.e. omission of hiatal repair and insufficient
mobilisation of the gastric fundus. If so, this may also have had an impact on
outcome after laparoscopic antireflux surgery.
Dysphagia is one of the most troublesome complications of antireflux
surgery. However, there is no standardised and uniformly applied scoring
system and the incidence of persisting dysphagia, as recorded in the literature,
is extremely variable. In several reports laparoscopic fundoplication has been
associated with obstructive complaints such as dysphagia and bloating
50
(85,88). These consequences are believed to be associated with the lack of
tactile feedback and other factors inherent in the laparoscopic technique
(77,153). In a prospective, randomised multicentre trial from the Netherlands
(85), 7 out of 57 patients had persistent dysphagia at a 3-month follow-up
after laparoscopic fundoplication. The dysphagia was severe enough to
require intervention. By comparison, none of the 46 patients having open
surgery experienced dysphagia of this severity. This substantial difference led
to discontinuation of the trial on ethical grounds. Others have not reported
such frequent and severe dysphagia after undergoing laparoscopic surgery.
This observation may be an indication of the impact the individual surgeons
have on the occurrence of dysphagia rather than the specific technique used.
In the present study there was no significant difference in the incidence of
dysphagia or gas bloat among the study groups. Furthermore, severe
dysphagia was seldom encountered. An incidence of approximately 2% of
this problem is exactly the same as Bessell reported in a study on 846
consecutively laparoscopically operated patients (154). In fact, occurrence of
dysphagia among the patients who responded to the questionnaire was
comparable to that found in a normal population (145) and much less
common than that found among patients with GORD (155,156).
Our study does not support the presumption that laparoscopic antireflux
surgery is to be preferred to open procedure. It does suggest, however, that
patients do not derive significant benefit from having the antireflux procedure
made laparoscopically.
51
Study V
Results
Treatment failures were more common among patients operated on at high-
volume hospitals than those operated on at low-volume hospitals. Estimated
treatment failure rates after adjusting for age, sex and BMI were 29.0 and
19.7% at high- and low-volume hospitals, respectively (p<0.0314). However,
because of the number of items that was tested, the p value for the difference in
treatment failure rates was not statistically significant at an overall 0.05 level
(Bonferroni correction).
Nevertheless, with each question regarding the effectiveness of the procedure
to suppress reflux, the patients operated on at low-volume hospitals tended to
have a more favourable outcome. They experienced heartburn and acid
regurgitation less often, needed less medication to relieve such complaints and
revision surgery was undertaken less frequently among these patients.
Gas bloat and flatulence were considered as the most bothersome abdominal
complaints by 46.8% of all patients. Although 7.8% (32 of 408 patients)
reported daily episodes of difficulties in swallowing, only 2.7% (eleven
patients) identified dysphagia as their most troublesome post-operative
symptom. Further, among patients who reported daily episodes of difficulty in
swallowing, gas bloat and flatulence were more often considered as their worst
symptom.
We could adjust for three confounding factors: age, gender and BMI; however,
the difference between the groups was not significant for any of these
variables. Neither age nor gender had a significant influence on outcomes of
the different items. Yet, BMI seemed to have an impact on outcome. As BMI
increased, the more satisfied was the patient with his or her experience after
52
the operation. The correlation was statistically significant (p<0.0006), but the
magnitude of the correlation was small, with a Spearman correlation
coefficient of –0.14. In addition, BMI was almost identical in the high- and
low-volume groups.
The results of Studies IV and V are summarised in Tables 1 and 2.
53
Table 1: The study groups and reasons for exclusion. * The high-volume laparoscopicgroup is compared with the open procedure group.
Laparoscopic procedureOpen procedure
Low-volume High-volume
P value*
Patients identified in
EpC235 220 225
Died 2 1 1
Moved, could not be
traced3 0 5
Excluded
other major procedures
previous surgery
10
16
4
0
1
0
not able to answer
(age, cerebral disease)1 1 1
Final sample size 203 214 217
Response rate 91 % 97 % 92 %
Women 47 % 38 % 40 % 0.135*
Mean age 57.8 51.5 53.5 0.0001*
Mean BMI 26.3 26.4 26.3 0.95*
Median follow-up 4 years 4 years 4 yearsRange
3.4-5.5
54
Table 2: Results of the patient questionnaire. For details, refer to manuscripts IV and V.* The high-volume laparoscopic group is compared with the open procedure group.
Laparoscopic procedureOpen procedure
(n = 185) % Low-volume
(n = 208) %
High-volume
(n = 200) % P value*
A. Effectiveness of the
antireflux procedure
No improvement 2.0 5.3 6.0
Revision surgery 5.4 2.9 6.0
Acid regurgitation 3.7 5.3 8.6
Heartburn 6.0 6.8 11.0
Medication 8.7 11.1 19.5* < 0.02*
Failure 14.6 19.7 29.0* < 0.004*
Dissatisfied 7.0 13.9 15.0* < 0.005*
B: Procedure related
side effects
Difficulties inswallowing food>once a day
(>5 times a day)
9.8 (1.6) 7.7 (1.4) 8.0 ( 2.0)
Difficult or unable to
belch33.1 46.0 29.0
Gas bloat, flatulence
(daily complaints)27.7 39.1 31.8
Suspicion of incisional
hernia4.0 2.4 2.0
Would recommend the
operation92 90 92
55
Discussion:
Because of the great variation in operating volume of laparoscopic antireflux
surgery among hospitals (Study III), we considered Sweden well suited for
studying the impact of operative volume on outcome. To our surprise, the
results suggest that procedures performed at high-volume hospitals were less
successful than procedures done at low-volume hospitals. Different
explanations could help to account for these results. For instance, an
increasing incidence of antireflux surgery may tend to lower the threshold for
accepting patients for surgery, as also was discussed in the previous section.
Furthermore, whereas university and large, county hospitals are educational
institutions with a high number of surgical trainees, the staff at the smaller,
regional hospitals doing fewer procedures may be more experienced. In a
recent report from the USA (VA National Surgical Quality Improvement
Program) it was concluded after assessing the outcomes of eight commonly
performed operations that volume of surgery cannot be used as an alternative
measure of quality in surgical care (157). Moreover, outstanding results can
also be obtained by regional hospitals, despite a low-volume of patients (158).
Nevertheless, a larger hospital volume can provide excellent facilities for
specialisation and refinements in every particular step of treatment and patient
care (79,159). It should be a challenge for units with an interest in
laparoscopic antireflux surgery to demonstrate that the potential advantage of
high-volume is also reflected in better outcome.
When considering the results of the present study, it should be kept in mind
that there are some methodological weaknesses. For instance, this study was
not randomised. However, it is unlikely that patients would submit
themselves to randomisation between high- and low-volume hospitals. It may
even be argued that, despite the relatively large difference between the
median volumes of the hospital groups, neither of the study groups were
frankly high-volume hospital groups in an international context. Other factors
56
may influence the long-term results: in particular, the indication for surgery,
the selection of different techniques, differences in hospital routines and the
experience of the surgeon. These circumstances could not be adjusted for by
other means than a large sample size. Furthermore, the result of a
questionnaire may be different from that obtained by clinical examination on
the same issue. It is then difficult to predict which one is more accurate.
Moreover, because the questionnaires in the present study were handled
anonymously and confidentially and did not involve any of the authors’
patients, there is no danger of the kind of bias that can result when researchers
query their own patients.
Inability to belch or vomit, gas bloat and increased flatulence are often
perceived as surgical side effects but are difficult to evaluate (93), especially
when a pre-operative comparison is lacking as in our study. Interestingly,
47% of the patients regarded gas bloat or increased flatulence as their most
bothersome post-operative symptom. Among the dissatisfied patients 29%
complained above all of gas bloat and increased flatulence. Surgical side
effects are therefore not to be underestimated when indications for surgery
and different therapeutic options are considered.
We have tried to assess the effectiveness of laparoscopic antireflux surgery. If
our results mirror the reality of the situation, laparoscopic antireflux surgery is
questionable as the method of choice for treatment of serious GORD. The
substantial increase in the incidence of antireflux surgery seen in Sweden
during the past few years may not have optimised the treatment of GORD
patients. Medical maintenance therapy with PPI could perhaps be the better
option for some patients and open surgery may have been better than
laparoscopic for others. Results of laparoscopy may also improve if the
indications for antireflux surgery are restricted. A prospective, randomised
57
study to identify different sub-groups of patients who are more likely to
benefit from laparoscopic surgery than PPI is recommended.
General discussion
The uncritical acceptance of laparoscopic technique among patients and
surgeons, enthusiastically supported in mass media, made possible a
revolution in surgical practice within less than a decade. The quick and wide
acceptance occurred despite the fact that it was weakly supported by solid
data (10). The technical equipment of this approach may be ultra-modern, but
the way it was implemented violated traditional scientific principles. At the
time when this approach already was regarded as the method of choice,
minimal access surgery was not modern medicine in the meaning that it was
not evidence-based (160).
Laparoscopy had been applied in gynaecology for decades. Moreover,
substantial knowledge had been collected from experimental and clinical
studies regarding the effect of positive pressure pneumoperitoneum. However,
communicating pneumo-pleuro-peritoneum represents a more complicated
and challenging condition. The experimental work of this thesis was an
attempt to explore that specific pathophysiologic condition in light of the new
surgical approach applied during dissection in the diaphragmatic hiatus.
In pigs we have demonstrated how devastating a combined thoraco-
laparoscopic approach can be for gas exchange. PEEP may then help to
optimise respiratory function. The application of PEEP was found to improve
gas exchange and, more importantly, hypoxemia could be avoided. Yet, no
beneficial effects of differential lung application of PEEP were documented.
To achieve optimal ventilation application of PEEP to both lungs had to
counterbalance the insufflation pressure.
The transmission of elevated pressure intra-cranially during positive pressure
pneumo-pleuro-peritoneum is a potential danger. However, application of
59
PEEP does not seem to increase ICP further; nor does it seem to adversely
affect cerebral circulation. Because PEEP can help to ensure good systemic
oxygenation and CO2 elimination, it may also help to avoid cerebral
hypoxemia.
Pneumothorax, which is a potential complication to laparoscopic surgery in
the upper abdomen (i.e. antireflux procedures, operations for large hiatal
hernia and cardiomyotomies) may be much more frequent than realised
(16,45,161). Many instances of pneumothorax are subclinical (16). Despite
an endoscopical and radiological verified pneumothorax, the clinical
symptoms are often moderate with an increase in airway pressure and ETCO2,
as well as reduced lung compliance. If more pronounced symptoms develop,
hypoxemia will also be present (16,44,47,132). Joris et al. have demonstrated
the therapeutic value of the application of PEEP in patients with
pneumoperitoneum and communicating pneumothorax. What this implies is
that the operative procedure can often be continued without performing tube
thoracostomy or conversion to open surgery (16).
Before applying PEEP, it is necessary to assess the nature of the
pneumothorax and consider differential diagnosis, i.e. endobronchial
intubation, obstruction of the tracheal tube or a bronchus and bronchospasm.
Fiberoptic bronchoscopy and x-ray of the chest can be helpful but such
examinations are often not readily available. Auscultation can reveal
unilateral decreased breath sounds, and combined with increased airway
resistance, elevated ETCO2 and an abrupt decrease in compliance, the
diagnose is fairly reliable. Moreover, the surgical procedure itself can give an
indication of the reason of acute respiratory insufficiency. One should also
keep in mind that the lesion of pleura can operate as a “check-valve,”
whereby tension pneumothorax can develop (162,163). This is a potentially
life-threatening complication and if impairment of cardiopulmonary functions
is encountered, the pneumothorax should immediately be evacuated. Simple
60
desufflation of the abdomen cannot be relied upon in tension pneumothorax;
instead, managing the patient with a chest drain is indicated.
If pneumothorax is encountered during such standard laparoscopic procedures
as fundoplication and hypoxia develops, the first step recommended is an
increase of oxygen concentration in inspired air, followed by increased
ventilation and application of PEEP. The results from Study I indicate that
optimal PEEP is equal to or higher than the abdominal insufflation pressure.
The insufflation pressure should be kept as low as possible because the
negative effects on respiratory function tend to worsen with increasing
pressure (162,164). A tube thoracostomy during the operation may interfere
with maintenance of pneumoperitoneum and hence make it difficult to expose
the surgical field. However, it is paramount that if there are signs of
cardiopulmonary compromise, laparoscopy should be discontinued.
After the operation, when the abdomen has been desufflated, any residual gas
will be quickly absorbed and the pneumothorax will disappear. Therefore,
chest drain is seldom indicated. In any event, a chest X-ray should be
routinely performed post-operatively to rule out any suspicion of tension
pneumothorax.
Diagnostic laparoscopy in trauma patients has proven successful in detection
of occult diaphragmatic lacerations, particular in patients with lower chest
stab wounds (165,166). Such injuries are notoriously difficult to detect by
chest roentenography, computed tomography or diagnostic lavage. Wiedeman
et al. have demonstrated that tension pneumothorax may develop when
pneumoperitoneum is created in the face of a diaphragmatic injury and that
the risk of its development increases with increasing insufflation pressure
(162). Hypoxemia provided an early clue of the pneumothorax, even when
chest X-ray was still normal. The lines of action given above can be applied
during short diagnostic procedures, but if a diaphragmatic lesion were
61
diagnosed, we would not recommend the repair to be done laparoscopically
because of the substantial risk of tension pneumothorax. Further, the lesion is
seldom encountered and a conventional method is to be preferred.
In major oesophageal surgery, i.e. oesophageal resection, one is confronted
with longer operating times and more extended dissection in the mediastinum.
Harmful effects of excessive PEEP applied for too many hours may
predispose for overdistention of lung parenchyma with post-operative
inflammatory reaction and atelectases as a result. Moreover, the patients are
often elderly with cardiopulmonary impairment, rendering them far more
sensitive to an insult such as a combined pneumo-pleuro-peritoneum. At
present, we do not think that a thoraco-laparoscopic approach is to be
recommended for oesophageal resection.
This thesis has demonstrated that the advent of the laparoscopic technique had
a profound impact on the practice of antireflux surgery. However, there was a
substantial increase in the annual number of antireflux procedures even before
the introduction of the laparoscopic technique. The threefold increase of the
incidence of antireflux surgery recorded during the past decade therefore
cannot solely be explained by the advent of the minimal access technique.
Nevertheless, a clear shift in the preferred methodology took place. This
change was not scientifically supported at the time of the transition and,
surprisingly, it is still not supported today. As was demonstrated, laparoscopy
might even be an inferior approach in some patients. However, it is
reasonable to assume that laparoscopic technique can yield equally good
results as open surgery despite our failure to confirm that in this series of
studies. Controlled prospective, randomised studies with adequate patient
enrolment to secure statistical power are needed to settle this issue
conclusively.
62
The development of the minimal access technique has stimulated numerous
innovations of new surgical instruments that can also be utilised in open
surgery, i.e. the Harmonic scalpel technology. In combination with
advancements in the treatment of post-operative pain, this development has
even changed the practice of conventional open surgery. However, before
new trials are undertaken, it is important that properly defined measures to
evaluate short- and long-term outcome are agreed upon.
For instance, one problem is that the criteria to evaluate success or failure are
not well defined (90,93). To equalise reflux control with success rate can give
a false impression (91,92). In a number of reports it is not stated how many
patients are still on antireflux medication (43,72-74,78,95) but if reported,
continuous medical therapy in about 6-8% is usual (77,91,167). There is no
agreement today whether continued use of medication is a sign of failure, as
in this thesis (Studies IV and V), or not. Even patients with objectively
demonstrated anatomical failure of the fundic wrap often do well on PPI (43).
The definition of failure in the present studies was rather demanding, but was
defined in order to achieve the goals of antireflux surgery. For a disease in
which an alternative and often similarly effective medical therapy exists
(168), one has to aim at optimal surgical results and patient satisfaction is
therefore crucial. After all, most patients who submit themselves to surgery
do it because of exacerbating symptoms and not because of objective signs,
i.e. endoscopic findings or results from 24-hour pH monitoring. The Genval
panel of experts accepted the statement, “reflux disease is likely present when
heartburn occurs on two or more days a week on the basis of the negative
impact of this symptom frequency on the health related well being (quality of
life)” (169). It is therefore logical that reasonable symptom control without
the need of frequent medication should be an indicator for surgical success or
failure. Although we are aware that indiscriminate use of acid suppression
therapy does not necessarily represent a technically failed antireflux
63
procedure, we still regard it as a treatment failure because cessation of
medication to suppress the symptoms of GORD is an important aim of
surgery. The questionnaire applied in Studies IV and V was also designed to
detect medication used specifically to suppress reflux symptoms.
Moreover, because the questionnaires were handled anonymously and
confidentially and did not involve any of the authors’ patients, there was no
danger for the kind of bias that can result when researchers query their own
patients.
This thesis did not study the indications for antireflux surgery. The treatment
of severe GORD is unique because medical maintenance therapy with PPI
and antireflux surgery are similarly effective options for most patients.
Surgical indications that were sound before the advent of PPI do not
necessarily stand for trial today. Likewise, the apparently attractiveness of the
laparoscopic approach may influence the patients and doctors’ choice of
treatment. In this respect, we had better have solid knowledge for our
recommendations, rather than merely relying on presumptions. Therefore, a
large prospective, randomised study on the optimal treatment of severe
GORD should ideally compare maintenance therapy with PPI in adequate
doses to surgical treatment with open or laparoscopic procedure. Such a study
should be of national interests; the pharmaceutical industry or medical
suppliers should not fund such a study because the treatment of GORD has
strong implications for the national health economy. Except for the rarely
occurring syndrome of Zollinger-Ellison, GORD is the only commonly
accepted indication for maintenance PPI therapy (FASS). Every year the
Swedish people buy PPI for approximately one hundred million dollars (170).
At the same time, approximately 1,300 patients will be operated on at a cost
of 4,000-7,000 dollars per patient, including sick leave (171).
64
The argument in favour of surgery has been that it offers a definitive
treatment. However, as this thesis has proven, this is a presupposition that has
not been verified. Many patients continue to use antisecretory medication
regularly despite surgery. Furthermore, patients often complain of what they
believe to be side effects of the surgical treatment. In contrast, patients who
never have had the opportunity to discuss different treatment options and
chosen to continue with maintenance therapy may regret they never have been
offered surgery.
A study that compares outcome of medical and surgical treatments will of
course demand close collaboration between surgeons and internists. That may
be as challenging as the problem of funding. The patients will benefit in the
long term when both surgeons and internists can agree upon the treatment.
Depending on what speciality the patients’ doctor happens to promote, the
indications for different therapeutic options should not differ that greatly
(9,11,90,172).
Generally, the laparoscopic approach is also appealing because it offers a
completely new “costume” to old surgical solutions. In particular, younger
surgeons may feel attracted by new technology because it is easy for them to
adopt and in a single, giant leap they may suddenly surpass their “master.”
The ”master,” on the other hand, may feel a regained youthful vigour when he
or she is still able to cope with the new trend. Yes, the fairy tale of HC
Andersen, “The Emperors new cloths” is worth remembering. Why is it that
new surgical techniques can move from “innovations” to widespread use on
the basis of little more than intuition (10,14,173)?
The laparoscopic approach is a major complement of the surgical technique.
There is no reason to deny that fact, but in terms of patient outcome and
overall management of abdominal disease, it has been a small advance
relative to the huge financial investments (10). We need to determine when it
should be used and for whom it would benefit most.
65
When confronted in the future with new therapeutic options, medical
societies, community health care systems and legal authorities should make a
common effort to guarantee that the evaluation and introduction take place
with maintained quality control. Before a new drug is accepted for legal
prescription, it is scrutinised through long and cumbersome experimental and
clinical evaluation. Similarly, there should be a more demanding attitude
toward general implementation of new surgical methods in routine hospital
care. The instrument manufacturers should not be allowed to have any
consequential influence on that process. At an early stage, new techniques
have to undergo clinical testing, and a long time is often needed for follow-up
before a complete picture of risks, side effects and outcomes are known. It
should not be acceptable to let the individual surgeon determine the utility of
new surgical techniques. It is more effective and honest if data on the
usefulness of the techniques were collected systematically and collectively. A
national consulting board for research and supervision of the implementation
of new surgical methods would be welcomed.
66
Conclusions
During laparoscopy, pneumothorax may induce deleterious effects on the
respiratory function.
Application of PEEP may help to ensure good oxygenation and CO2
elimination when accidental pneumothorax is encountered during
laparoscopy (pneumoperitoneum). PEEP did not adversely affect ICP or
cerebral circulation.
To achieve optimal ventilation the PEEP applied to both lungs has to
counterbalance the insufflation pressure. No benefit of differential lung
ventilation was encountered.
Surgical treatment for GORD has increased threefold in 1997 as compared
with 1987.
The laparoscopic approach has replaced the open technique as the method
of choice in antireflux surgery.
In comparison with open surgery, patients do not seem to derive
significant long-term benefits from having the antireflux procedure done
laparoscopically.
Better results after laparoscopic surgery, particularly at hospitals with
larger operating volumes, have to be demonstrated before the method can
be recommended as routine treatment for severe GORD.
We strongly recommend carrying out a randomised controlled trial
between maintenance treatment with adequate doses of PPI and
conventional open or laparoscopic techniques.
67
Acknowledgements
I would like to express my sincere gratitude to all those who have helped mein these studies and especially to:
Ulf Haglund for your consistent support and guidance in scientific andclinical work. You were tolerant and loyal when it was most needed.
Elisabeth Bergquist for your enthusiastic participation in the practicalcompletion of this thesis. It is a pleasure to work with you.
Harry Kahmis for invaluable help with the statistical aspects of my work. Youhave always responded expeditious, even after returning to your position inDayton. Your friendly attitude and educational skills made the statisticalproblems comprehensible.
Sten Rubertsson who has been my human link in the task of comprehendingall of the challenging anaesthesiological issues.
My co-authors, Sven Gustavsson, Dag Arvidsson, Thomas Hallgren, and UlfSjöstrand for providing strong support and inspiring ideas.
Birgitta Birgisdottir and Anders Nordgren who ensured the technical qualityof the laboratory research. You made the work run smoothly and without anyencumbrances. Arne Linder kindly performed the differential bronchialintubation.
Mohana Thiruchelvam for skilful linguistic revision of several of themanuscripts, and Åsa Isacson for highly dependable secretarial assistance.
Gustav Liedberg for brilliant teaching regarding surgical handicraft.
Gudrun, my dear sister, a special thanks to you for always caring for yourfamily, me included.
68
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