Zusammenfassung
Die Haut ist nicht nur das größte Organ des menschlichen Körpers, sondern auch die primäre Immunbarriere. Daher stellt der großflächige Verlust der Haut durch thermische Traumata nicht nur eine lebensbedrohliche Situation für die Betroffenen, sondern durch die Notwendigkeit des Hautersatzes noch immer eine ernsthafte Herausforderung in der Plastischen und Verbrennungschirurgie dar. Die Entwicklung und ständige Verbesserung innovativer Methoden der Hautexpansion sowie des Tissue Engineering lassen heute Verbrannte mit mehr als 80% verbrannter Körperoberfläche überleben. Zwar hat sich die Applikation gezüchteter Epidermis und zusammengesetzter kultivierter Hautkonstrukte als lebensrettende Maßnahme etabliert — jedoch ist die Indikationsstellung, ab welcher diese Technologie zum Einsatz kommt, immer enger geworden.
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Literatur
Bünger C (1823) Gelungener Versuch einer Nasenbildung aus einem völlig getrennten Hautstück aus dem Beine. J Chir Augenheilkd 4: 569–573
Reverdin JL (1969) Greffe epidermique. Bulletin de la Societe Imperiale de Chirurgie de Paris 10: 511–514.
Braun W (1920) Zur Technik der Hautpfropfung. Zentralbl Chir 47: 1355–1361
Ollier L (1872) Sur le greffes cutanees ou autoplatiques. Bull Acad Med 1: 243–256
Thiersch C (1874) Ueber die feineren anatomischen Veränderungen bei Aufheilung von Haut auf Granulationen. Langenbecks Arch Klin Chir 17: 318–324
Mangoldt F (1895) Die Epithelsaat zum Verschluß einer großen Wundfläche. Med. Wochenschr 21: 798–803
Mir Y, Mir L (1950) The gauze technique in skin grafting; a quick method in applying dermatome grafts. Plast Reconstr Surg 5: 91–96
Janzekovic Z (1970) A new concept in the early excision and immediate grafting of burns. J Trauma 10: 1103–1108
Fisher JC (1984) Skin — the ultimate solution for the burn wound. N Engl J Med 311: 466–467
Alexander JW, MacMillan BG, Law E, Kittur DS (1981) Treatment of severe burns with widely meshed skin autograft and meshed skin allograft overlay. J Trauma. 21: 433–438
Pallua N, Machens HG, Becker M, Berger A (1996) [Surgical prevention of post-traumatic infection by immediate necrectomy of burn wounds]. Langenbecks Arch Chir Suppl Kongressbd 113: 1144–1148
Gabarro P (1943) A new method of grafting. BMJ 1: 723
MacMillan B, Altemeier W (1962) Massive excision of the extensive burn. Research in burns. Am Inst Biol Siences 9: 331
Tanner JC, Jr., Vandeput J, Olley JF (1964) The mesh skin graft. Plast Reconstr Surg 34: 287–292
Tanner JC, Jr., Shea PC, Jr., Bradley WH, Vandeput JJ (1969) Large-mesh skin grafts. Plast Reconstr Surg 44: 504–506
Burleson R, Eiseman B (1972) Nature of the bond between partial-thickness skin and wound granulations. Surgery 72: 315–322
Adams DC Ramsey ML (2005) Grafts in dermatologic surgery: review and update on full-and split-thickness skin grafts, free cartilage grafts, and composite grafts. Dermatol Surg 318 (Pt 2): 1055–1067
Brou J, Vu T, McCauley RL, Herndon DN, Desai MH, Rutan RL, et al (1990) The scalp as a donor site: revisited. J Trauma 30: 579–581
Corps BV (1969) The effect of graft thickness, donor site and graft bed on graft shrinkage in the hooded rat. Br J Plast Surg 22: 125–133
Smahel J, Ganzoni N (1972) The take of mesh graft in experiment. Acta Chir Plast 14: 90–100
Meek CP (1958) Successful microdermagrafting using the Meek-Wall microdermatome. Am J Surg 96: 557–558
Kreis RW, Mackie DP, Vloemans AW, Hermans RP Hoekstra MJ (1993) Widely expanded postage stamp skin grafts using a modified Meek, technique in combination with an allograft overlay. Burns 19: 142–145
Vandeput J, Tanner JC, Jr., Carlisle JD (1966) The ultra postage stamp skin graft. Plast Reconstr Surg 38: 252–254
Chang LY, Yang JY (1998) Clinical experience of postage stamp autograft with procine skin onlay dressing in extensive burns. Burns 24: 264–269
Bondoc CC, Burke JF (1971) Clinical experience with viable frozen human skin and a frozen skin bank. Ann Surg 174: 371–382
Kreis RW, Hoekstra MJ, Mackie DP, Vloemans AF, Hermans RP (1992) Historical appraisal of the use of skin allografts in the treatment of extensive full skin thickness burns at the Red Cross Hospital Burns Centre, Beverwijk, The Netherlands. Burns 18[Suppl 2]: S19–S22
Abbott WM, Hembree JS (1970) Absence of antigenicity in freeze-dried skin allografts. Cryobiology 6: 416–418
Hermans RP (1983) The use of human allografts in the treatment of scalds in children. Panminerva Med, 25: 155–156
Kreis RW, Vloemans AF, Hoekstra MJ, Mackie DP, Hermans RP (1989) The use of non-viable glycerol-preserved cadaver skin combined with widely expanded autografts in the treatment of extensive third-degree burns. J Trauma 29: 51–54
Achauer BM, Hewitt CW, Black KS, Martinez SE, Waxman KS, Ott RA, et al. (1986) Long-term skin allograft survival after short-term cyclosporin treatment in a patient with massive burns. Lancet 1(8471): 14–15
Takiuchi I, Higuchi D, Sei Y, Nakajima T (1982) Histological identification of prolonged survival of a skin allograft on an extensively burned patient. Burns Incl Therm Inj 8: 164–167
Hafemann B, Frese C, Kistler D, Hettich R (1989) Intermingled skin grafts with in vitro cultured keratinocytes — experiments with rats. Burns 15: 233–238
Phillips A, Clarke J (1991) The use of intermingled autograft and parental allograft skin in the treatment of major burns in children. Br J Plast Surg 44: 608
Alsbjörn B, Sýrensen B (1985) Grafting with epidermal Langerhans cell depressed cadaver split skin. Burns 11: 259
Burke JF, May JW, Jr., Albright N, Quinby WC, Russell PS (1974) Temporary skin transplantation and immunosuppression for extensive burns. N Engl J Med 290: 269–271
Burke JF, Quinby WC, Bondoc CC, Cosimi AB, Russell PS Szyfelbein SK (1975) Immunosuppression and temporary skin transplantation in the treatment of massive third degree burns. Ann Surg 182: 183–197
Hewitt CW, Black KS, Stenger JA, Go C, Achauer BM, Martin DC (1988) Comparison of kidney, composite tissue, and skin allograft survival in rats prolonged by donor blood and concomitant limited cyclosporine Transplant Proc 20[Suppl 3]: 1110–1113
Hewitt CW, Black KS, Harman JC, Beko KR, 2nd, Lee HS, Patel AP, et al (1990) Partial tolerance in rat renal allograft recipients following multiple blood transfusions and concomitant cyclosporine. Transplantation 49: 194–198
Frame JD, Sanders R, Goodacre TE, Morgan BD (1989) The fate of meshed allograft skin in burned patients using cyclosporin immunosuppression Br J Plast Surg 42: 27–34
Kanitakis J, Ramirez-Bosca A, Haftek M, Thivolet J (1990) Histological and ultrastructural effects of cyclosporin A on normal human skin xenografted on to nude mice. Virchows Arch A Pathol Anat Histopathol 416: 505–511
Bromberg BE, Song IC, Mohn MP (195) The use of pig skin as a temporary biological dressing. Plast Reconstr Surg 36: 80–90
Ding YL, Pu SS, Wu DZ, Ma C, Pan ZL, Lu X, et al (1983) Clinical and histological observations on the application of intermingled auto — and porcine-skin heterografts in third degree burns. Burns Incl Therm Inj 9: 381–386
Min J, Yang GF (1981) [Clinical and histological observations on intermingled pig skin and auto-skin transplantation in burns (authors’ transl)]. Zhonghua Wai Ke Za Zhi 19: 43–45
Yang ZJ (1981) Treatment of extensive third degree burns. A Chinese concept. Rev Med Chir Soc Med Nat Iasi 85: 69–74
Baumer F, Henrich HA, Bonfig R, Kossen DJ, Romen W (1986) [Surgical treatment of 3d degree burns with mixed homologous/autologous and heterologous/autologous fullthickness skin grafts. Comparison of results with native and frozen homologous and heterologous tissues in animal experiments]. Zentralbl Chir 111: 426–430
Jackson D (1954) A clinical study of the use of skin homografts for burns. Br J Plast Surg 7: 26–43
Converse JM, Rapaport FT (1956) The vascularization of skin autografts and homografts; an experimental study in man. Ann Surg 143: 306–315
Toranto IR, Sayler KE, Myers MB (1974) Vascularization of porcine skin heterografts. Plast Reconstr Surg 54: 195–200
Herndon DN, Rutan RL (1992) Comparison of cultured epidermal autograft and massive excision with serial autografting plus homograft overlay. J Burn Care Rehabil 13: 154–157
Horch R, Stark GB, Kopp J, Spilker G (1994) Cologne Burn Centre experiences with glycerol-preserved allogeneic skin: Part I: Clinical experiences and histological findings (overgraft and sandwich technique). Burns 20 [Suppl 1]: S23–S26
Sawada Y (1985) Survival of an extensively burned child following use of fragments of autograft skin overlain with meshed allograft skin. Burns Incl Therm Inj 11: 429–433
Sawada Y (1989) Buried chip skin grafting for treatment of perianal burns. Burns Incl Therm Inj 15: 36–38
Ming-Liang Z, Chang-Yeh W, Zhi-De C (1986) Microskin grafting II. Clinical report. Burns 12: 544
Zhang ML, Chang ZD, Han X, Zhu M (1986) Microskin grafting. I. Animal experiments. Burns Incl Therm Inj 12: 540–543
Zhang ML, Wang CY, Chang ZD, Cao DX, Han X (1986) Microskin grafting. II. Clinical report. Burns Incl Therm Inj 12: 544–548
Lin SD, Lai CS, Chou CK, Tsai CW (1992) Microskin grafting of rabbit skin wounds with Biobrane overlay. Burns 18: 390–434
Lin SD, Lai CS, Chou CK, Tsai CW, Wu KF, Chang CW (1992) Microskin autograft with pigskin xenograft overlay: a preliminary report of studies on patients. Burns 18: 321–325
O’Conner N, Mulliken J, Banks-Schlegel S, Kehinde O, Green H (1981) Grafting of burns with cultured epithelium prepared from autologous epidermal cells. Lancet 1: 75–78
Hefton JM, Madden MR, Finkelstein JL, Shires GT (1983) Grafting of burn patients with allografts of cultured epidermal cells. Lancet 2(8347): 428–430
Gallico GG, 3rd, O’Connor NE, Compton CC, Kehinde O, Green H (1984) Permanent coverage of large burn wounds with autologous cultured human epithelium. N Engl J Med 311: 448–451
Madden MR, Finkelstein JL, Staiano-Coico L, Goodwin CW, Shires GT, Nolan EE, et al (1986) Grafting of cultured allogeneic epidermis on second-and third-degree burn wounds on 26 patients. J Trauma 26: 955–962
Eldad A, Burt A, Clarke JA, Gusterson B (1987) Cultured epithelium as a skin substitute. Burns Incl Therm Inj 13: 173–180
Teepe RG, Kreis RW, Hoekstra MJ, Ponec M (1987) [Permanent wound cover using cultured autologous epidermis transplants: a new treatment method for patients with severe burns]. Ned Tijdschr Geneeskd 131: 946–951
Aubock J (1988) [Skin replacement with cultured keratinocytes]. Z Hautkr 63: 565–567
Aubock J, Irschick E, Romani N, Kompatscher P, Hopfl R, Herold M, et al (1988) Rejection, after a slightly prolonged survival time, of Langerhans cell-free allogeneic cultured epidermis used for wound coverage in humans. Transplantation 45: 730–737
Ljunggren C (1898) Von der Fähigkeit des Hautepithels ausserhalb des Organismus sein Leben zu behalten, mit Berücksichtigung der Transplantation. Dtsch Z Chir 47: 608–615
Carrel A, Burrows M (1919) Cultivation of adult tissues and organs outside of the body. JAMA 55: 1379–1381
Hadda S (1912) Aus der chirurg. Abteilung des israelitischen Krankenhauses zu Breslau: Die Kultur lebender Körperzellen. Berl Klin Wschr 49: 11
Kreibich K (1914) Aus der deutschen dermatologischen Klinik in Prag: Kultur erwachsener Haut auf festem Nährboden. Arch Dermatol Syph 120: 168–176
Waymouth C (1965) Construction and use of synthetic media. In: Willmer E (ed) Cells and tissues in culture. London, Academic, p 99
Börnstein K (1930) Über Gewebezüchtung menschlicher Haut. Klin Wschr 9: 1119
Pinkus H (1932) Über Gewebekulturen menschlicher Epidermis. Arch Dermatol Syph 165: 53–85
Medawar P (1948) The cultivation of adult mammalian skin epithelium in vitro. QJ Microsc Sci 89: 187
Parshley MS, Simms HS (1950) Cultivation of adult skin epithelial cells (chicken and human) in vitro. Am J Anat 86: 163–189
Lewis s, Pomerat C, Ezell D (1949) Human epidermal cell observed in tissue culture phase-contrast microscope. Anat Rec 104: 487
Flaxman B, Harper R (1975) Primary cell culture for biochemical studies of human keratinocytes. Br J Dermatol 92: 305
Flaxman BA, Harper RA (1975) Primary cell culture for biochemical studies of human keratinocytes. A method for production of very large numbers of cells without the necessity of subculturing techniques. Br J Dermatol 92: 305–309
Blocker TG, Jr., Pomerat CM, Lewis SR (1950) Research opportunities with the use of cultures of living skin. Plast Reconstr Surg 5: 283–288
Bassett CA, Evans VJ, Earle WR (1956) Characteristics and potentials of long term cultures of human skin. Plast Reconstr Surg 17: 421–429
Medawar P (1948) Tests by tissue culture methods on the nature and immunity to transplanted skin. Q J Microsc Sci 89: 239
Moscona A (1961) Rotation-mediated histogenetic aggregation of dissociated cells. A quantifiable approach to cell interactions in vitro. Exp Cell Res 22: 455–475
Karasek MA (1968) Growth and differentiation of transplanted epithelial cell cultures. J Invest Dermatol 51: 247–252
Igel HJ, Freeman AE, Boeckman CR, Kleinfeld KL (1974) A new method for covering large surface area wounds with autografts. II. Surgical application of tissue culture expanded rabbit-skin autografts. Arch Surg 108: 724–729
Freeman AE, Igel HJ, Herrman BJ, Kleinfeld KL (1976) Growth and characterization of human skin epithelial cell cultures. In Vitro 12: 352–362
Rheinwald JG, Green H (1975) Serial cultivation of strains of human epidermal keratinocytes: the formation of keratinizing colonies from single cells. Cell 6: 331–343
Rheinwald JG, Green H (1975) Formation of a keratinizing epithelium in culture by a cloned cell line derived from a teratoma. Cell 6: 317–330
Medawar P (1941) Sheets of pure epidermal epithelium from human skin. Nature 148: 783
Billingham RE, Reynolds J (1952) Transplantation studies on sheets of pure epidermal epithelium and on epidermal cell suspensions. Br J Plast Surg 5: 25–36
Perry VP, Evans VJ, Earle WR, Hyatt GW, Bedell WC (1956) Long-term tissue culture of human skin. Am J Hyg 63: 52–58
Wheeler CE, Canby CM, Cawley EP (1957) Long-term tissue culture of epithelial-like cells from human skin. J Invest Dermatol 29: 383–391; discussion 91–92
Cruickshank CN, Cooper JR, Hooper C (1960) The cultivation of cells from adult epidermis. J Invest Dermatol 34: 339–342
Prunieras M, Mathivon MF, Leung TK, Gazzolo L (1965) [Euploid Culture of Adult Epidermal Cells in Monocellular Layers]. Ann Inst Pasteur (Paris). 108: 149–165
Constable H, Cooper JR, Cruickshank CN, Mann PR (1974) Keratinization in dispersed cell cultures of adult guinea-pig ear skin. Br J Dermatol 91: 39–48
Karasek MA, Charlton ME (1971) Growth of postembryonic skin epithelial cells on collagen gels. J Invest Dermatol 56: 205–210
Cohen S (1962) Isolation of a mouse submaxillary gland protein accelerating incisor eruption and eyelid opening in the new-born animal. J Biol Chem 237: 1555–1562
Cohen S (1965) The stimulation of epidermal proliferation by a specific protein (EGF). Dev Biol 12: 394–407
Green H, Kehinde O, Thomas J (1979) Growth of cultured human epidermal cells into multiple epithelia suitable for grafting. Proc Natl Acad Sci USA 76: 5665–5668
Cuono C, Langdon R, McGuire J (1986) Use of cultured epidermal autografts and dermal allografts as skin replacement after burn injury Lancet 1(8490): 1123–1124
Hennings H, Michael D, Cheng C, Steinert P Holbrook K, Yuspa SH (1980) Calcium regulation of growth and differentiation of mouse epidermal cells in culture. Cell 19: 245–254
Yuspa SH Koehler B, Kulesz-Martin M, Hennings H (1981) Clonal growth of mouse epidermal cells in medium with reduced calcium concentration. J Invest Dermatol 76: 144–146
Barnes D, Sato G (1980) Methods for growth of cultured cells in serum-free medium. Anal Biochem 102: 255–270
Shipley GD, Ham RG (1981) Improved medium and culture conditions for clonal growth with minimal serum protein and for enhanced serum-free survival of Swiss 3T3 cells. In Vitro 17: 656–670
Tsao MC, Walthall BJ, Ham RG (1982) Clonal growth of normal human epidermal keratinocytes in a defined medium. J Cell Physiol 110: 219–229
Wille JJ, Jr., Pittelkow MR, Shipley GD, Scott RE (1984) Integrated control of growth and differentiation of normal human prokeratinocytes cultured in serum-free medium: clonal analyses, growth kinetics, and cell cycle studies. J Cell Physiol 121: 31–44
Kopp J, Jeschke MG, Bach AD, Kneser U, Horch RE (2004) 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 5: 89–96
Yasushi F, Koichi U Yuka O, Kentaro K, Hiromichi M, Yoshimitsu K (2004) Treatment with autologous cultured dermal substitutes (CDS) for burn scar contracture in children. Wound Repair Regen 12: A11
Freising C, Horch R (2001) Clinical results of cultivated keratinocyzes to treat burn injuries — a metaanalysis. In: Achauer B (ed) Cultured human keratinocytes and tissue engineered skin substitutes. Thieme, Stuttgart, pp. 220–226
Woodley DT, Peterson HD, Herzog SR, Stricklin GP, Burgeson RE, Briggaman RA, et al (1988) Burn wounds resurfaced by cultured epidermal autografts show abnormal reconstitution of anchoring fibrils. Jama 259: 2566–2571
Horch RE, Stark G, Spilker G (1994) Treatment of perianal burns with submerged skin particles. Zentralbl Chir 119: 722–725
Horch RE, Corbei O, Formanek-Corbei B, Brand-Saberi B, Vanscheidt W, Stark G (1998) Reconstitution of basement membrane after “sandwich-technique” skin grafting for severe burns demonstrated by immunohistochemistry. J Burn Care Rehabil 19: 189–202
Horch RE, Jeschke MG, Spilker G, Herndon DN, Kopp J (2005) Treatment of second degree facial burns with allo-grafts — preliminary results. Burns 31: 597–602
Munster AM, Smith-Meek M, Shalom A (2001) Acellular allograft dermal matrix: immediate or delayed epidermal coverage? Burns 27: 150–153
Ronfard V, Rives JM, Neveux Y, Carsin H, Barrandon Y (2000) Long-term regeneration of human epidermis on third degree burns transplanted with autologous cultured epithelium grown on a fibrin matrix. Transplantation 70: 1588–1598
Hunyadi J, Farkas B, Bertenyi C, Olah J, Dobozy A (1987) Keratinocyte grafting: covering of skin defects by separated autologous keratinocytes in a fibrin net. J Invest Dermatol 89: 119–120
Altmeppen J, Hansen E, Bonnlander GL, Horch RE, Jeschke MG (2004) Composition and characteristics of an autologous thrombocyte gel. J Surg Res 117: 202–207
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Horch, R.E., Kopp, J. (2009). Haut und Hautersatz, Tissue Engineering. In: Kamolz, LP., Herndon, D.N., Jeschke, M.G. (eds) Verbrennungen. Springer, Vienna. https://doi.org/10.1007/978-3-211-79896-6_12
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