Bone Tissue Engineering by Bioreactor

Department of Mechanical Engineering, Department of Bioengineering

School of Engineering University of tokyo

http://www.furukawa.t.u-tokyo.ac.jp/

furukawa@mech.t.u-tokyo.ac.jp

Cadaver

Other species

Golden Standard

Substitutes

Tissue engineering bone

Grafts for bone defect Q： clinical relevant? Bone regeneration in

vitro

Bone cells

Matrix

Growth factors

A V

Bone

Porous scaffold

Stem cells

Pharmaceutic

Nutrient＋O2

Shear

Bioreactor

Waste

Tissue engineering bone

Q： clinical relevant?

Intracellular calcium release↑ IP3 ↑, cAMP↑

COX-2↑,, Erk-1/2 ↑

G proteins↑

PGE2 ↑, PGI2↑, NO↑

Fluid forces > Mechanical strain

ALP activity↑ osteocalcin↑

Osteopontin↑(2 dyn/cm2)

Mineralized matrix deposition↑

Q h wal

l

2D study by flow chamber Oscillatory flow

by mechanical loading

Bone Mass↑

Hydrodynamic Bioreactor

Nutrient

＋O2

Waste Shear

Cells

Pharmaceutic

Gene, growth

factors, etc

Scaffold

Seeding, viability, function

Adaptation

Efficiency, cost

Bioreactor

Clinical Application

Safety, cost, convenient,

evaluation prior transplantation

Co

nven

tio

na

l

Perf

usio

n S

ys.

Ro

tati

on

Wall V

essel

Sti

rrin

g

Fla

sk

Sta

tic

Seeding

Uniformity Proliferation

Uniformity Culture

Volume Safety

☓

☓

☓

○

Flexible

>50ml

$$$

>20ml

>50ml

$$$

◎

◯

△

×

３D culture sys.

Q： what new?

☓

☓

☓

○

Purpose

Oscillatory flow

Loading induced flow profile in vivo

Develop a hydrodynamic bioreactor :

Compact

Safe

Easy operation

In-line seeding with high efficiency

Small culture volume large culture volume

Oscillatory Perfusion

System

In clean bench In incubator

Seeding ring

Methods of Seeding and Culture

MC 3T3-E1

Osteoblast-like cells

1.5×106 / 100μl Oscillatory

Mixing

Top Dropping

After 2 hrs

+1600 μl Media

Flow rate

0.5ml / min

Static

DNA Content

MTT Staining

DNA Content

ALP Activity

MTT Staining

Hoechst/ PI

Staining

24 hrs 5 days

β-TCP Scaffold

(10mm×h8mm)

Spacial Distribution of Cell

Viability

— Calcein-AM/PI Staining Top Upper Middle Lower Bottom

Perf

usio

n (0

.5m

l/m

in)

Sta

tic C

ulture

Top

Uppe

r

Middl

e

Lowe

r

Bottom

Living cells

Dead cells

ALP Staining Static Culture Perfusion Culture (0.5ml/min)

B

ott

om

L

ow

er

M

iddle

Upper

T

op

ALP PI ALP PI

Top

Upper

Middle

Lower Bottom

Evaluation of Flow Rate

Waveform

Probe

＋silicon

tube

The difference in

flow rate among the

6 wells:5.81%±0.6

(n=3)

Flo

w r

ate

(m

l/m

in)

-2.5

-2.0

-1.5

-1.0

-0.5

0.0

0.5

1.0

1.5

2.0

2.5

3.0

1.92 ≈2.0 1/2 0.4 24.00

0.96 ≈1.0 1/2 0.2 12.00

0.08 1/120 1.0 1.00

0.04 1/120 0.5 0.50

0.004 1/1200 0.5 0.05

0 0 0 0.00

(dyn/cm2) ƒ

(Hz)

Volume (ml/well)

RATE (ml/min/well)

Spacial Distribution of Cell

Viability

— Calcein-AM/PI Staining

Static Perfusion Perfusion Perfusion

0.05ml/min 0.5ml/min 1.0ml/min

Dex (

+)

D

ex (

-)

ALP Activity

— Early Osteogenic Marker

﹡

0.00

0.02

0.04

0.06

0.08

0.10

0.12

0.14

Static Perfusion

ALP

Activity/s

caffold

(m

M/h

r)

0.00

0.02

0.04

0.06

0.08

0.10

0.12

Static Perfusion

ALP

Activity/d

sD

NA

(m

M/h

r/ug)

Static Perfusion

Static Perfusion

Total differentiation per scaffold: Average differentiation per cell:

Perfusion > Static (p<0.05) Perfusion > Static (p<0.1)

Seeding

Uniformity

Proliferation

Uniformity Culture

Volume Safety

☓

☓

☓

△

Flexible

>50ml

$$$

>20ml

>50ml

$$$

◎

◯

△

×

Comparison

Q： what new?

◎ 1.5ml ◎

☓

☓

☓

△

◎

Conclusion

Tissue engineering bone with clinical relevant size could be cultured uniformly in only 1.5ml

media by the oscillatory perfusion system.

Oscillatory perfusion system: Compact, efficient seeding & culture, safe, etc.

The only bioreactor uniform 3D culture

0.5ml/min optimized

Cassette design internal flow+ external flow

Strategy of 3D culture of customized tissue engineering bone was established - first study

Katsuko S Fruukawa，Takashi Ushida，Du Dajiang