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NTIS 바로가기한국생물공학회지 = Korean journal of biotechnology and bioengineering, v.23 no.1, 2008년, pp.8 - 17
서영권 (동국대학교 생명과학연구원) , 송계용 (중앙대학교 의과대학 병리학교실) , 박정극 (동국대학교 생명화학공학과)
There are many different approaches to healing of acute and chronic ulcer and large skin defect, such as burn. Currently available wound covers fall into two categories. Permanent covering, such as autografts, and temporary ones, such as allograft including de-epidermized cadaver skin, bioartificial...
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Hansbrough, J. F., and E. S. Franco (1998), Skin replacements, Clin. Plast. Surg. 25, 407-423
Ruszczak, Z., and R. A. Schwartz (2000) , Modem aspects of wound healing, Dermatol. Surg. 26, 219-229
Horch, R. E., J. Kopp, J. Beier, and A. D. Bach (2005), Tissue engineering of cultured skin substitutes, J. Cell. Mol. 9, 592-608
Cuono, C., R. Langdon, and J. McGuire (1986), Use of cultured epidermal autografts and dermal allografts as skin replacement after burn injury, Lancet 17,1123-1124
Abbott, W. M., and J. S. Hembree (1970), Absence of antigenicity in freeze-dried skin allografts, Cryobiology 6, 416-418
Hussmann, J., R. C. Russell, J. O. Kucan, D. Hebebrand, T. Bradley, and H. U. Steinau (1994), Use of glycerolized human allog rafts as temporary and permanent cover in adult s and children, Burns 20, S61-65
Kuroyanagi, Y. N., Yamada, R. Yamashita, and E. Uchinurna (2001),Tissue-engineered product: allogenic cultured dermal substitute composed of spongy collagen with fibroblast. Artif. Organs 25, 180-186
Wainwright, D. J. (1995), Use of acellular allograft dermal matrix (AlIoDarm) in the management of full-thickness burns, Burns 21, 243-248
Callcut, R. A., M. J. Schurr, M. Sloan, and L. D. Faucher (2006), Clinical experience with Alloderm : a one -staged composite dermal/epidermal replacement utilizing processed cadaver dermis and thin autografts, Burns 32, 583-588
Rennekampff, H. O ., V. Kiessig, S. Griffey, G. Greenleaf, and J. F. Hansbrough (1997), Acellular human dermis promotes cultured keratinocyte engraftment, J. Burn Care Rehabil. 18, 535-544
Jasinkowski , N. L., and J. L. Cullum (1984), Human amniotic membrane as a wound dressing, AORN J. 39, 894-895
Tyszkiewicz, J. T., I. A. Uhrynowska-Tyszkiewicz, A. Kaminski and A. Dziedzic-Goclawska (1999), Amnion allografts prepared in the central tissue bank in warsaw, Ann. Transplant. 4, 85-90
Quinby W. C., H. C. Hoover, M. Scheflan, P. T. Walters, S. A. Slavin, and C. C. Bondoc (1982), Clinical trials of amniotic membranes in burn wound care, Plast. Reconstr. Surg. 70, 711-717
Subrahmanyam , M. (1995), Amniotic membrane as a cover for microskin grafts, Br. J. Plast. Surg. 48, 477-478
Honavar, S. G., S. K. Bansal, V. S. Sangwan, and G. N. Rao (2000), Amniotic membrane transplantation for ocular surface reconstruction in Stevens-Johnson Syndrome, Ophthalmology 107, 975-979
Kim, J. S., J. C. Kim, B. K. Na, J. M. Jeong, and C. Y. Song (2000), Amniot ic membrane patching promotes healing and inhibits proteinase activity on wound healing following acute corneal alkari burn, Exp. Eye Res. 70, 329-337
Ward, D. J., J. P. Bennett, H. Burgos, and J. Fabre (1989), The heal ing of chronic venous leg ulcers with prepared human amnion, Br. J. Plast. Surg. 42, 463-467
Ahn, J. I., I. K. Jang, D. H. Lee, Y. K. Seo, H. H. Yoon, Y. H. Shin, C. H. Kim, K. Y. Song, H. G. Lee, E. K. Yang, K. H. Kim, and J. K. Park (2005), A comparison of lyophilized amniotic membrane with cryopreserved amniotic membrane for the reconstruction of rabbit corneal epithelium. Biotech and Biopro. Eng. 10, 262-269
Badylak, S. F. (2007), The extracelular matrix as a biologic scaffold material, Biomaterials 28, 3587-3593
Hodde, J. (2002), Natually occurring scaffolds for soft tissue repair and regeneration. Tissue Eng. 8, 295-308
Kawai, K, S. Suzuki, Y. Tabata, Y. Ikada, and Y. Nishimura (2000), Accelerated tissue regeneration through incorporation of basic fibroblast growth factor -impregnated gelatin microspheres into artificial dermis. Biomaterials 21, 489-499
Lin, S. D., C. S. Lai, C. K. Chou, C. W. Tsai, K. F. Wu, and C. W. Chang (1992), Microskin autograft with pigskin xenograft overlay; a preliminary report of studies on patien ts, Burn 18, 321-325
Basile, A. R. (1982), A comparative study of glycerinized and lyophilized porcine skin in dressings for third-degree burns, Plast. Reconstruct Surg. 69, 969-974
Madden, M. R., J. L. Finkelstein, L. Staiano-Coico, C. W. Goodwin, G. T. Shires, E. E. Nolan, and J. M. Hefton (1986), Grafting of cultured allogeneic epidermis on second- and third- degree burn wounds on 26 patients, J. Trauma. 26, 955-962
Phillips, T. J., J. Bhawon, I. M. Leigh, H. J. Baum, and B. A. Gilchrest (1990), Cultured epidermal autografts and allografts: a study of diffe rentiation and allograft survival, J. AM. Acad. Dermatol. 23, 189-198
Burt, A. M., C. D. Pallett, J. P. Sloane, M. J. O' Hare, K. F. Schafler, P. Yardeni, A. Eldad, J. A. Clarke, and B. A. gusterson (1989), Survival of cultured allografts in patients with bums assessed with probe specific for Y chromosome, BMJ. 298, 915-917
Aubock, J., E. Irschick E, N. Romani, P. Kompatscher, R. Hopfl, M. Herold, G. Schuler, M. Bauer, C. Huber, and P. Fritsch (1988), Transplantation 45, 730-737
Horch, R. E., M. Debus, G. Wagner, and G. B. Stark (2006), Cultured human keratinocytes on type I collagen membranes to reconstitute the epidermis, Tissue Eng. 6, 53-67
Seo, Y. K., J. I. Ahn, D. H. Lee, S. Y. Kwon, D. H. Jung, Y. S. Park, K. Y. Song, E. K. Yang, Y. J. Kim, and J. K. Park (2004), The wound healing effects of human deepithelialized amniotic membrane with skin keratinocyte. Tissue Eng. Regen: Med 1, 178-183
Kearney, J. N. (2001), Clinical evaluation of skin substitutes, Burns 27, 545-551
Burke, J. F., I. V. Yannas, W. C. Quinby, C. C. Bondoc, and W. K. Jung (1981), Successful use of a physiologically acceptable artifical skin in the treatment of extensive burn injury, Ann. Surg. 194, 413-428
Matsui, R., N. Okura, K. Osaki, J. Konishi, K. Ikegami, and M. Koide (1996), Histological evaluation of skin reconstruction using artificial dermis, Biomaterials 17, 995-1000
Kremer, M., E. Lang , and A. C. Berger (2000 ), Evaluation of dermal-epidermal skin equivalents ('composite-skin') of huma n keratinocytes in a collagen-glycosaminoglycan matrix ( $Integra^{TM}$ Artificial Skin), Br. J. Plast. Surg. 53, 459-465
Matsui, R., K. Osaki, J. Konishi, K. Ikegami, and M. Koide (1996), Evaluation of an artificial dermis full -thickness skin defect model in the rat, Biomaterials 17, 989-994
Suzuki , S., K. Kawai, F. Ashoori , N. Morimoto, Y. Nishimura, and Y. Ikada (2000), Long-term follow-up study of artificial dermis composed of outer silicone layer and inner collagen sponge, Br. J. Plast. Surg. 53, 659-666
Guerret, S., E. Govignon, D. J. Hartmann, and V. Ronfard (2003) Long-term remodeling of a bilayered living human skin equivalent(Apligra $circledR$ ) grafted onto the nude mice : immunolocalization of human cells and characterization of extracellular matrix, Wound Rep. Reg. 11, 35-45
Naughton, G., J Mansbridge, and G. Gentzkow (1997), A metabolically active human dermal replacement for the treatment of diabetic foot ulcers, Artif. Organs 21, 1203-1210
Hanbrough, J. F., D. W. Mozingo, P. Kealey, M. Davis, A. Gidner, and G. D. Gentzkow (1997), Clinical trials of a biosynthetic temporary skin replacement, Dennagraft-transitional covering, compared with cryopreserved human cadaver skin for temporarycoverage of excised bum wounds, J. Burn Care Rehabil. 18, 43-51
Hanbrough, J. F., M. L. Cooper, R. Cohen, R. Spielvogel, G. Greenleaf, R. L. Bartel, and G. Naughton (1992), Evaluation of a biodegradable matrix containing cultured human fibroblasts as a dermal replacement beneath meshed skin grafts on athymic mice. Surgery 111, 438-446
Sabolinski M. L., O. Alvarez , M. Auletta, G. Mulder , and N. L. Parenteau (1996), Cultured skin as a smart material for healing wounds.experience in venous ulcers, Biomaterials 17, 311-320
Cooper, M. L., and J. F. Hansbrough (1991), Use of a composite skin graft composed of cultured human keratinocytes and fibroblasts and a collagen-GAG matrix to cover full-thickness wounds on athymic mice, Surgery 109, 198-207
Yannas, I. V., and J. F. Burke (1980), Design of an artificial skin I . Basic design principles, J. Biomed. Mater. Res. 14, 65-81
Dagalakis, N., J. Flink, P. Stas ikelis, J. F. Burke, and I. V. Yannas (1980), Design of an artificial skin III . Control of pore structure , J. Biomed. Mater. Res. 14, 511-528
Yannas, I. V., J. F. Burke, P. L. Gordon , C. Huang, and R. H. Rubenstein (1980), Design of an artificial skin III . Control of chemical composition, J. Biomed. Mater. Res. 14, 107-132
Nehrer, S., H. A. Breinan, A. Ramappa, G. Young, S. Shortkroff, L. K. Louse, C. B. Sledge, I. V. Ya nnas, and M. Spector (1997), Matrix collagen type and pore size influence behaviour of seeded canine chondrocytes, Biomaterials 18, 769-776
Orgill, D. P., and I. V. Yannas (1998), Design of an artificial skin N. Ues of island graft to isolate organ regeneration from scar synthesis and other processes leading to skin wound closure , J. Biomed. Mater. Res. 39, 531-535
Doillon, C. J., C. F. Whyne, S. Brandwein, and F. H. Silver (1986), Collagen-based wound dressing : Control of the pore structure and morphology . J. Biomed. Mater. Res. 20, 1219-1228
Boyce, S. T , D. J. Christianson, and J. F. Hansbro ugh (1988), Structure of a collagen-GAG dermal skin substitute optimized for cultured human epidermal kerationcytes, J. Biomed. Mater. Res. 22, 939-957
Pieper, J. S., A. Oosterhof, P. J. Dijkstra, J. H. Veerkamp, and T. H. Van Kuppevelt (1996), Preparation and characterization of porous crosslinked collagenous matrices containing bioavailable chondroitin sulphate , Biomaterials 20, 847-858
Berthod, F., F. Sahuc, D. Hayek, O. Damour, and C. Collombel (1996), Deposition of collagen fibriles bundles by long -term culture of fibroblast in a collagen sponge, J. Biomed. Mater. Res. 32, 87-93
Lamme E. N., R. T. van Leeuwen, J. R. Mekker, E. Middelkoop (2002), Allogeneic fibroblasts in dermal substitutes induce inflammation and scar formaion, Wound Repair Regen . 10, 152-160
Morimoto, N., Y. Saso, K. Tomihata, T Taira, Y. Takahashi, M. Ohta, and S. Suzuki (2005), Viability and function of autologous and allogeneic fibroblasts seeded in dermal substitutes after implantation, J. Surg. Res. 125, 56-67
Seo Y. K., K. Y. Song, Y. J. Kim, and J. K. Park (2007), Wound healing effect of acellular artificial dermis containing extracellular matrix secreted by human skin fibroblast , Artif Organs 31, 509-520
Alexander, S. A., and R. B. Donoff (1980), The glycosaminoglycans of open wound, J. Surg. Res. 29, 422-429
Hu, M., E. E. Sabelman, Y. Gao, J. Chang , and V. R. Hentz (2003), Three-dimensional hyaluronic acid grafts promote healing and reduce scar formation in skin incision wounds, J. Biomed. Mater. Res. B Appl. Biomater. 67, 586-592
Murashita , T., Y. Nakayama , T. Hirano , and S. Ohashi (1997), Acceleration of granulation tissue ingrowth by hyaluronic acid in artificial skin, Br. J. Plast. Surg. 49, 58-63
Greco, R. M., J. A. Iocono, and H. P. Ehrich (1998), Hyaluronic acid stimulates human fibroblast proliferation within a collagen matrix , J. Cell. Physiol. 177, 465-473
Boralidi, F., M. A. Croce, D. Quaglino, R. Sammarco, E. Camevali, R. Tiozzo, and I. Pasquali-Ronchetti (2003), Cell-matrix interactions of in vitro human skin fibroblasts upon addition of hyaluronan , Tissue Cell 35, 37-45
Caplan, A. I. (2000), Tissue engineering designs for the future: New logics, old molecules , Tissue Eng. 6, 1-8
Galassi, G., P. Brun, G. Abatangelo, M. Radice, R. Cortivo, G. F. Zanon, P. Genovese , and G. Abatangelo (2000), In vitro reconstructed dermis implanted in human Wounds: degradation studies of the HA-based Supporting scaffold , Biomaterials 21, 2183-2191
Doillon , C. J., F. H. Silver, and R. A. Berg (1987), Fibroblasts growth on a porous collagen sponge containing hyaluronic acid and fibronectin, Biomaterials 8, 195-200
Doillon , C. J., and F. H. Silver (1986), Collagen-based wound dressing : Effect of hyaluronic acid and fibronectin on wound healing, Biomaterials 7, 3-8
Kubo, K., and Y. Kuroyanagi (2003), Characterization of a cultured dermal Substitute composed of a spongy matrix of hyaluronic acid and collagen comb ined with fibroblasts, J. Artif. Organs 6, 138-144
Kuroyanagi , Y., K. Kubo, S. Kagawa, H. Matsui, H. J. Kim, S. Numari , and Y. Mabuchi (2004), Establishment of banking system for allogeneic cultured dermal substitute, J. Artif. Organs 1, 13-21
Kashiwa , N., O. Ito, T. Ueda, K. Kubo, H. Matsui, and Y. Kuroyanagi (2004), Treatment of full-thickness skin defect with concomitant grafting of 6-fold extended mesh auto-skin and allogeneic cultured dermal substitute, Artif. Organs 5, 444-450
Kubo, K., and Y. Kuroyanagi (2004), Development of a cultured dermal substitute composed of a spongy matrix of hyaluronic acid and atelo-collagen combined with fibrob lasts : cryopreservation, Artif. Organs 2, 182-188
Kubo, K., and Y. Kuroyanagi (2003), Spongy matrix of hyaluronic acid and collagen as a cultured dermal substitute: evaluation in an animal test, Artif. Organs 6, 64-70
Caravaggi, C., R. De Giglio, C. Pritelli, M. Sornmaria, S. Dalla Noce, E. Faglia, M. Mantero, G. Clerici, P. Fratino, L. Dalla Paola, G. Mariani, R. Mingardi, and A. Morabito (2003), HYAFF 11 -based autologous dermal and epidermal grafts in the treatment of noninfected diabetic plantar and dorsal foot ulcers: a prospective, multicenter, controlled, randomized clinical trial, Diabetes Care 26, 2853-2859
Navsaria, H. A., S. R. Myers, I. M. Leigh, and I. A. McKay (1995), Culturing skin in vitro for wound therapy, TIBIOTECH. 13, 91-100
Lee, J. H., Y. S. Cho, H. H. Kim and J. S. Lee (1998), Wound dressing, Biomaterials Res. 2, 180-191
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