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DOI: 10.1055/s-0030-1252044
© Georg Thieme Verlag KG Stuttgart · New York
Tissue Engineering von Haut – von der Spalthaut zum gezüchteten Hauttransplantat?
Skin Tissue Engineering – from Split Skin to Engineered Skin Grafts?Publikationsverlauf
eingereicht 30.11.2009
akzeptiert 15.3.2010
Publikationsdatum:
17. Mai 2010 (online)
Zusammenfassung
Heutzutage sind Spalt- oder Vollhauttransplantate der Goldstandard in der Behandlung von Substanzdefekten der Haut, deren Erfolge in der Therapie von zum Beispiel Schwerstverbrannten erkennbar sind. Allerdings haben Schwerstverbrannte mit mehr als 50% verbrannter Körperoberfläche nur begrenzte Spenderareale. Des Weiteren haben Hauttransplantate auf chronischen Wunden schlechtere Einheilungsraten als bei Verbrennungspatienten, was z. B. durch Begleiterkrankungen oder vermehrte lokale Infektionen bedingt sein kann. Aufgrund oben genannter Limitationen ist der Bedarf an kostendeckenden, benutzerfreundlichen synthetischen oder gezüchteten Hautersatzmaterialien, die sowohl für akute und chronische Wunden geeignet sind, als auch bei Problempatienten mit Begleiterkrankungen zur Anwendung kommen können, vorhanden. In den letzten 30 Jahren sind eine Vielzahl an unterschiedlichen biologischen und synthetischen Hautersatzmatrizes sowie Produkte mit humanen patienteneigenen Zellen auf den Markt gekommen, an deren Weiterentwicklung ständig gearbeitet wird. Eine Möglichkeit ist die Züchtung eines Hautersatzes in vitro, der sich nach Transplantation in das Wundbett integrieren soll. Eine andere Alternative stellt die Herstellung einer biokompatiblen und bioresorbierbaren Matrix dar, die die ortständigen Zellen rekrutieren kann und zur narbenlosen Heilung anregt. Allerdings können die heute verfügbaren Hautersatzprodukte die Spalt- oder Vollhauttransplantation noch nicht vollständig ersetzen, da noch immer Einschränkungen wie unzureichende Einheilung und/oder mechanische Stabilität des Hautersatzes oder ein Fehlen von differenzierten Strukturen auftreten. An dem Ziel einen Hautersatz herzustellen, der alle funktionellen und strukturellen Fähigkeiten der gesunden menschlichen Haut mit sich bringt und diese vollständig ersetzen kann, wird weiter gearbeitet. Dieser Artikel gibt einen Überblick über die heute verfügbaren Lösungsansätze und Produkte im Feld des Tissue Engineerings von Haut.
Abstract
Today split or full skin grafts are still the gold standard in the treatment of substance defects of the skin. Such results can be seen, for example, in the therapy for burn patients. However, in patients with more than 50% burned skin area, donor sites are limited. Likewise in chronic wound patients inferior take rates of skin grafts as compared to burn wounds are observed. This may be attributed, for example, to accompanying or underlying chronic diseases or a higher rate of local infections. These phenomena also lead to a lack of availability of transplantable skin grafts. Hence the need for cost effective and user friendly synthetic or engineered skin grafts, which can serve for acute and chronic wounds and which can be also used in critically ill patients, is at hand. During the last 30 years a huge number of biological and synthetic skin graft materials and products based on the patient's own cells were launched on the market. Researchers and clinicians are constantly working on further improvements. One possibility is the engineering of skin grafts in vitro, which have to be integrated into the wound bed after transplantation. Another approach is the fabrication of biocompatible and bioresorbable matrices, which can attract host cells and stimulate a wound-healing process without scars. However, the skin graft materials available today cannot yet replace split or full skin grafts completely because of their inherent limitations such as insufficient take rates and/or the lack of mechanical stability and differentiated structures of the grafted artificial skin. Thus researchers in the field of skin tissue engineering are still working on the final goal of developing a skin graft which has all the features of healthy human skin and is capable of replacing human skin completely. This article gives on overview of the currently available solutions and products in the field of skin tissue engineering.
Schlüsselwörter
Haut Tissue Engineering - Hautersatz - Keratinozyten - kultivierte autologe Epidermis
Key words
skin tissue engineering - skin replacement - keratinocytes - cultured epidermal autografts
Literatur
- 1
Gallico Gr, O’Connor N, Compton C. et al .
Permanent coverage of large burn wounds with autologous cultured human epithelium.
N Engl J Med.
1984;
311
448-451
Reference Ris Wihthout Link
- 2
Bleiziffer O, Horch RE, Hammon M. et al .
T17b murine embryonal endothelial progenitor cells can be induced towards both proliferation
and differentiation in a fibrin matrix.
J Cell Mol Med.
2009;
13
926-935
Reference Ris Wihthout Link
- 3
Nguyen VA, Furhapter C, Obexer P. et al .
Endothelial cells from cord blood CD133+CD34+ progenitors share phenotypic, functional
and gene expression profile similarities with lymphatics.
J Cell Mol Med.
2009;
13
522-534
Reference Ris Wihthout Link
- 4
Popescu LM, Gherghiceanu M, Manole CG. et al .
Cardiac renewing: interstitial Cajal-like cells nurse cardiomyocyte progenitors in
epicardial stem cell niches.
J Cell Mol Med.
2009;
13
866-886
Reference Ris Wihthout Link
- 5
Sabatier F, Camoin-Jau L, Anfosso F. et al .
Circulating endothelial cells, microparticles and progenitors: key players towards
the definition of vascular competence.
J Cell Mol Med.
2009;
13
454-471
Reference Ris Wihthout Link
- 6
Timmermans F, Plum J, Yoder MC. et al .
Endothelial progenitor cells: identity defined?.
J Cell Mol Med.
2009;
13
87-102
Reference Ris Wihthout Link
- 7
van Osch GJ, Brittberg M, Dennis JE. et al .
Cartilage repair: past and future – lessons for regenerative medicine.
J Cell Mol Med.
2009;
13
792-810
Reference Ris Wihthout Link
- 8
Ballyns JJ, Bonassar LJ.
Image-guided tissue engineering.
J Cell Mol Med.
2009;
13
1428-1436
Reference Ris Wihthout Link
- 9
Hutmacher DW, Horch RE, Loessner D. et al .
Translating tissue engineering technology platforms into cancer research.
J Cell Mol Med.
2009;
13
1417-1427
Reference Ris Wihthout Link
- 10
Spadaccio C, Chello M, Trombetta M. et al .
Drug releasing systems in cardiovascular tissue engineering.
J Cell Mol Med.
2009;
13
422-439
Reference Ris Wihthout Link
- 11
Giunta RE, Machens HG.
[Science and research in academic plastic surgery in Germany].
Handchir Mikrochir Plast Chir.
2009;
41
359-363
Reference Ris Wihthout Link
- 12
Langer R, Vacanti JP.
Tissue engineering.
Science.
1993;
260
920-926
Reference Ris Wihthout Link
- 13
Rab M, Koller R, Ruzicka M. et al .
Should dermal scald burns in children be covered with autologous skin grafts or with
allogeneic cultivated keratinocytes?.
“The Viennese concept”. Burns.
2005;
31
578-586
Reference Ris Wihthout Link
- 14
Kamolz L, Lumenta D, Kitzinger H. et al .
Tissue engineering for cutaneous wounds: An overview of current standards and possibilities.
Eur Surg.
2008;
40
19-26
Reference Ris Wihthout Link
- 15
Beele H.
Artificial skin: past, present and future.
Int J Artif Organs.
2002;
25
163-173
Reference Ris Wihthout Link
- 16
Horch RE, Kopp J, Kneser U. et al .
Tissue engineering of cultured skin substitutes.
J Cell Mol Med.
2005;
9
592-608
Reference Ris Wihthout Link
- 17
Boyce ST.
Design principles for composition and performance of cultured skin substitutes.
Burns.
2001;
27
523-533
Reference Ris Wihthout Link
- 18
Aubock J.
[Skin replacement with cultured keratinocytes].
Z Hautkr.
1988;
63
565-567
Reference Ris Wihthout Link
- 19
Billingham RE, Medawar PB.
A note on the specificity of the corneal epithelium.
J Anat.
1950;
84
50-56
Reference Ris Wihthout Link
- 20
Medawar PB.
The cultivation of adult mammalian skin epithelium in vitro.
Q J Microsc Sci.
1948;
89
187-196
Reference Ris Wihthout Link
- 21
Karasek MA.
Growth and differentiation of transplanted epithelial cell cultures.
J Invest Dermatol.
1968;
51
247-252
Reference Ris Wihthout Link
- 22
Karasek MA.
Culture of human keratinocytes in liquid medium.
J Invest Dermatol.
1983;
81
24s-28s
Reference Ris Wihthout Link
- 23
Rheinwald JG, Green H.
Epidermal growth factor and the multiplication of cultured human epidermal keratinocytes.
Nature.
1977;
265
421-424
Reference Ris Wihthout Link
- 24
Rennekampff HO, Hansbrough JF, Woods Jr V. et al .
Integrin and matrix molecule expression in cultured skin replacements.
J Burn Care Rehabil.
1996;
17
213-221
Reference Ris Wihthout Link
- 25
Barrandon Y, Green H.
Three clonal types of keratinocyte with different capacities for multiplication.
Proc Natl Acad Sci U S A.
1987;
84
2302-2306
Reference Ris Wihthout Link
- 26
Falanga V, Isaacs C, Paquette D. et al .
Wounding of bioengineered skin: cellular and molecular aspects after injury.
J Invest Dermatol.
2002;
119
653-660
Reference Ris Wihthout Link
- 27
Munster AM.
Cultured skin for massive burns A prospective, controlled trial.
Ann Surg.
1996;
224
372-375
; discussion 375–377
Reference Ris Wihthout Link
- 28
Horch R, Stark G.
Economy of skin grafting in burns.
Hospital – J Eur Assoc Hosp Man.
2001;
3
6-9
Reference Ris Wihthout Link
- 29
Meana A, Iglesias J, Del Rio M. et al .
Large surface of cultured human epithelium obtained on a dermal matrix based on live
fibroblast-containing fibrin gels.
Burns.
1998;
24
621-630
Reference Ris Wihthout Link
- 30
Kamolz L, Andel H, Eisenbock B. et al .
The Use of Allogeneic Cultivated Keratinocytes for the Early Coverage of Burns – The
Viennese Concept.
Osteosynthesis and Trauma Care.
2007;
15
48-51
Reference Ris Wihthout Link
- 31
Boyce ST, Supp AP, Wickett RR. et al .
Assessment with the dermal torque meter of skin pliability after treatment of burns
with cultured skin substitutes.
J Burn Care Rehabil.
2000;
21
55-63
Reference Ris Wihthout Link
- 32
Koller R, Bierochs B, Meissl G. et al .
The use of allogeneic cultivated keratinocytes for the early coverage of deep dermal
burns – indications, results and problems.
Cell Tissue Bank.
2002;
3
11-14
Reference Ris Wihthout Link
- 33
Koller R, Bierochs B, Meissl G. et al .
The use of stored skin grafts for keratinocyte cultures.
Br J Plast Surg.
2001;
54
87
Reference Ris Wihthout Link
- 34
Sasaki M, Abe R, Fujita Y. et al .
Mesenchymal stem cells are recruited into wounded skin and contribute to wound repair
by transdifferentiation into multiple skin cell type.
J Immunol.
2008;
180
2581-2587
Reference Ris Wihthout Link
- 35
Wu Y, Chen L, Scott PG. et al .
Mesenchymal stem cells enhance wound healing through differentiation and angiogenesis.
Stem Cells.
2007;
25
2648-2659
Reference Ris Wihthout Link
- 36
Li H, Fu X, Ouyang Y. et al .
Adult bone-marrow-derived mesenchymal stem cells contribute to wound healing of skin
appendages.
Cell Tissue Res.
2006;
326
725-736
Reference Ris Wihthout Link
- 37
Takahashi K, Tanabe K, Ohnuki M. et al .
Induction of pluripotent stem cells from adult human fibroblasts by defined factors.
Cell.
2007;
131
861-872
Reference Ris Wihthout Link
- 38
Mansbridge JN.
Tissue-engineered skin substitutes in regenerative medicine.
Curr Opin Biotechnol.
2009;
20
563-567
Reference Ris Wihthout Link
- 39
Page RL, Ambady S, Holmes WF. et al .
Induction of stem cell gene expression in adult human fibroblasts without transgenes.
Cloning Stem Cells.
2009;
11
417-426
Reference Ris Wihthout Link
- 40
Kamolz LP, Kolbus A, Wick N. et al .
Cultured human epithelium: human umbilical cord blood stem cells differentiate into
keratinocytes under in vitro conditions.
Burns.
2006;
32
16-19
Reference Ris Wihthout Link
- 41
Mangoldt F.
Die Epithelsaat zum Verschluss einer großen Wundfläche.
Med Wochenschr.
1895;
21
798-803
Reference Ris Wihthout Link
- 42
Kamolz LP, Luegmair M, Wick N. et al .
The Viennese culture method: cultured human epithelium obtained on a dermal matrix
based on fibroblast containing fibrin glue gels.
Burns.
2005;
31
25-29
Reference Ris Wihthout Link
- 43
Johnsen S, Ermuth T, Tanczos E. et al .
Treatment of therapy-refractive ulcera cruris of various origins with autologous keratinocytes
in fibrin sealant.
Vasa.
2005;
34
25-29
Reference Ris Wihthout Link
- 44
Bannasch H, Unterberg T, Fohn M. et al .
Cultured keratinocytes in fibrin with decellularised dermis close porcine full-thickness
wounds in a single step.
Burns.
2008;
34
1015-1021
Reference Ris Wihthout Link
- 45
Larochelle F, Ross G, Rouabhia M.
Permanent skin replacement using engineered epidermis containing fewer than 5% syngeneic
keratinocytes.
Lab Invest.
1998;
78
1089-1099
Reference Ris Wihthout Link
- 46
Rouabhia M.
Burns and skin transplantation.
Transplant Proc.
1999;
31
889
Reference Ris Wihthout Link
- 47
Burke JF, Yannas IV, Quinby Jr WC. et al .
Successful use of a physiologically acceptable artificial skin in the treatment of
extensive burn injury.
Ann Surg.
1981;
194
413-428
Reference Ris Wihthout Link
- 48
Lal S, Barrow RE, Wolf SE. et al .
Biobrane improves wound healing in burned children without increased risk of infection.
Shock.
2000;
14
314-318
; discussion 318–319
Reference Ris Wihthout Link
- 49
Branski LK, Herndon DN, Pereira C. et al .
Longitudinal assessment of Integra in primary burn management: a randomized pediatric
clinical trial.
Crit Care Med.
2007;
35
2615-2623
Reference Ris Wihthout Link
- 50
Kopp J, Jeschke MG, Bach AD. et al .
Applied tissue engineering in the closure of severe burns and chronic wounds using
cultured human autologous keratinocytes in a natural fibrin matrix.
Cell Tissue Bank.
2004;
5
89-96
Reference Ris Wihthout Link
- 51
Ryssel H, Gazyakan E, Germann G. et al .
The use of MatriDerm in early excision and simultaneous autologous skin grafting in
burns – a pilot study.
Burns.
2008;
34
93-97
Reference Ris Wihthout Link
- 52
Golinski PA, Zoller N, Kippenberger S. et al .
Development of an Engraftable Skin Equivalent based on Matriderm(R) with Human Keratinocytes
and Fibroblasts.
Handchir Mikrochir Plast Chir.
2009;
Reference Ris Wihthout Link
- 53
Keck M, Haluza D, Burjak S. et al .
Cultivation of keratinocytes and preadipocytes on a collagen-elastin scaffold (Matriderm®): First results of an in vitro study.
Eur Surg.
2009;
41
189-193
Reference Ris Wihthout Link
- 54
Voigt M, Schauer M, Schaefer DJ. et al .
Cultured epidermal keratinocytes on a microspherical transport system are feasible
to reconstitute the epidermis in full-thickness wounds.
Tissue Eng.
1999;
5
563-572
Reference Ris Wihthout Link
- 55
Reimers K, Radtke C, Choi CY. et al .
Expression of TNF-related apoptosis-inducing ligand (TRAIL) in keratinocytes mediates
apoptotic cell death in allogenic T cells.
Ann Surg Innov Res.
2009;
3
13
Reference Ris Wihthout Link
- 56
Macri L, Silverstein D, Clark RA.
Growth factor binding to the pericellular matrix and its importance in tissue engineering.
Adv Drug Deliv Rev.
2007;
59
1366-1381
Reference Ris Wihthout Link
- 57
Macri L, Clark RA.
Tissue engineering for cutaneous wounds: selecting the proper time and space for growth
factors, cells and the extracellular matrix.
Skin Pharmacol Physiol.
2009;
22
83-93
Reference Ris Wihthout Link
- 58
Horch RE, Bannasch H, Stark GB.
Transplantation of cultured autologous keratinocytes in fibrin sealant biomatrix to
resurface chronic wounds.
Transplant Proc.
2001;
33
642-644
Reference Ris Wihthout Link
Korrespondenzadresse
Prof. R. E. Horch
Universitätsklinikum Erlangen
Plastisch- und Handchirurgische
Klinik
Krankenhausstraße 12
91054 Erlangen
eMail: raymund.horch@uk-erlangen.de