Zusammenfassung
Das Prinzip des Plattenfixateurs hat sich in der Wirbelsäulenchirurgie bewährt [2]. Für den Einsatz eines derartigen Plattenfixateurs im Bereich der langen Röhrenknochen sind jedoch zusätzliche Forderungen zu berücksichtigen.
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References
CCA Biochem BV (1988) Polyactide. Information Bulletin, Gorinchem, Holland
Boehringer Ingelheim KG (1985) Resorbable Polyesters. Information Bulletin - Product Range, Ingelheim, FRG
Du Pont Company (1988) Medisorb, bioresorbable polymers, Bulletin 8/88, 138489A, Wilmington, Del., USA
Holmes PA (1985) Applications of PHB — a microbially produced biodegradable thermoplastic. Phys Tfechnol 16:32
Brown DJ, Ragg PL, Webb A (1987) The potential medical applications of hydroxybutyrate-hydroxy-valerate copolymers. Proceedings, Medical Plastics ’87, Copenhagen, Denmark, 28.1
Katz AR, Himer RJ (1970) Evaluation of tensile and absorption properties of polyglycolic acid sutures. Surg Gynecol Obstet 131:701
Postlethwait RW, Durham NC (1970) Polyglycolic acid surgical sutures. Arch Surg 101:489
Postlethwait RW (1974) Further study of polyglycolic acid suture. Am J Surg 127:617
Pavan A, Bosio M, Longo T (1979) A comparative study of poly(glycolic acid) and catgut suture materials: Histomorphology and mechanical properties. J Biomed Mater Res 13:477
Hermann JB, Kelly RJ, Higgins GA (1970) Polyglycolic acid sutures. Arch Surg 100:486
Craig PH, Williams JA, Davis KW, Magoun AD, Levy AJ, Bogdansky IS, Jones JP (1975) A biologic comparison of Polyglactin 910 and polyglycolic acid synthetic absorbable sutures. Surg Gynecol Obstet 141:1
Conn J, Oyasu P, Welsh M, Beal JM (1974) Vicryl (Polyglactin 910) synthetic absorbable sutures. Am J Surg 128:19
Matlaga BF, Salthouse TN (1983) Ultrastructural observations of cells at the interface of a biodegradable polymer: Polyglactin 910. J Biomed Mater Res 17:185
Salthouse TN (1984) Some aspects of macrophage behavior at the implant interface. J Biomed Mater Res 18:395
Salthouse TN (1986) Cellular enzyme activity at the polymer-tissue interface: A review. J Biomed Mater Res 10:197
Salthouse TN, Matlaga BF (1976) Polyglactin 910 suture absorption and the role of cellular enzymes. Surg Gynecol Obstet 142:544
Katz AR, Mukherjee DP, Kaganov AL, Gordon S (1985) A new synthetic monofilament absorbable suture made from polytrimethylene carbonate. Surg Gynecol Obstet 161:213
Ray JA, Doddi N, Regula D, Williams JA, Melveger A (1981) Polydioxanone (PDS), a novel monofilament synthetic absorbable suture. Surg Gynecol Obstet 13:644
Blaydes JE, Werblin TP (1982) 9–0 monofilament polydioxanone (PDS): A new synthetic absorbable suture for cataract wound closure. Ophtal Surg 13: 644
Delamy HM, Rudavsky AZ, Lans Z (1985) Preliminary clinical experience with the use of absorbable mesh splenorrhapy. J Ttauma 25:909
Dayton MT, Buchele BA, Shirazi SS, Hunt LB (1986) Use of absorbable mesh to repair contaminated abdominal-wall defects. Arch Surg 121:954
Maurer PK, McDonald JV (1985) Vicryl(Polyglactin 910) mesh as a dural substitute. J Neurosurg 63:448
Eigler FW, Gross E, Klaes W (1985) Resorbierbare Kunststoffnetze in der Abdominalchirurgie. Chirurg 56:376
Lyrell J, Silberman H, Chandrasoma P, Niland J, Shull J (1989) Absorbable versus permanent mesh in abdominal operations. Surg Gynecol Obstet 168:227
Kronenthal RL (1975) Biodegradable polymers in medicine and surgery. In: Kronenthal R, Oser Z, Martin E (eds) Polymers in Medicine and Surgery. Plenum, New York, p 119
Reed AM, Gilding DK (1981) Biodegradable polymers for use in surgery — Poly(glycolic)/poly(lactic acid) homo and copolymers: 2. In vitro degradation. Polymer 22:494
Holland SJ, Tighe BJ, Gould PL (1986) Polymers for biodegradable medical devices. 1. The potential of polyesters as controlled macromolecular release systems. J Controlled Rel 4:155
Ginde RM, Gupta RK (1987) In vitro chemical degradation of poly(glycolic acid) pellets and fibers. J Appl Polym Sci 33:2411
Pitt CG, Gu Z (1987) Modification of the rates of chain cleavage of poly(E-caprolactone) and related polyesters in the solid state. J Controlled Rel 4:283
Kenley RA, Lee MO, Mahoney TR, Sanders LM (1987) Poly(lactide-co-glycolide) decompositions kinetics in vivo and in vitro. Macromolecules 20:2398
Chu CC (1981) An in vivo study of the effect of buffer on the degradation of poly(glycolic acid) sutures. J Biomed Mater Res 15:19
Chu CC (1985) Degradation phenomena of two linear aliphatic polyester fibres used in medicine and surgery. Polymer 26:591
Chu CC, Campbell ND (1982) Scanning electron microscopic study of the hydrolytic degradation of poly(glycolic acid) suture. J Biomed Mater Res 16:417
Chu CC (1982) The effect of pH on the vitro degradation of poly(glycolide lactide) copolymer absorbable sutures. J Biomed Mater Res 16:117
Williams DF, Mort E (1977) Enzyme accelerated hydrolysis of polyglycolic acid. J Bioeng 1:231
Williams DF (1979) Some observations on the role of cellular enzymes in the in vitro degradation of polymers. In: Syrett BC, Acharya A (eds) Corrosion and Degradation of Implant Materials, ASTM STP 684, ASTM, 61
Miller ND, Williams DF (1984) The in vivo and in vitro degradation of poly(glycolic acid) suture materials as function of applied strain. Biomaterials 5:365
Williams DF (1981) Enzymatic hydrolysis of polylactic acid. Engl Med 10:5
Miller ND, Williams DF (1987) On the biodégradation of poly-B-hydroxybutyrate (PHB) homopolymer and poly-B-hydroxybutyrate-hydroxyvalerate copolymers. Biomaterials 8:129
Williams DF, Miller ND (1987) The degradation of polyhydroxybutyrate (PHB). In: Pizzoferato A, Marchetti PG, Ravaglioli, Lee AJC (eds) Biomaterials and Clinical Applications. Elsevier, Amsterdam, p 471
Holland SJ, Jolly AM, Yasin M, Tighe BJ (1987) Polymers for biodegradable medical devices II. Hydroxybutyrate-hydroxyvalerate copolymers: hydrolytic degradation studies. Biomaterials 8:289
Knowles JC, Hastings GW (1989) Physical characteristics of polyhydroxybutyrate degradation, Proceedings PIMS VI, Norwijkerhout, Holland, 38/1
Gilding DK (1981) Biodegradable polymers. Biocompat Clin Implant Mater 2:209
Pittman CU Jr, Iqbal M, Chen CY, Heibert JN (1978) Radiation degradation of poly(a-hydroxybutyric acid) and poly(glycolic acid). J Poly Sci Polym Chem Ed 16:2721
Gupta MC, Deshmukh VG (1983) Radiation effects on poly(lactic acid). Biomaterials 24:827
Fredericks RJ, Melveger AJ, Dolegiewitz LJ (1984) Morphological and structural changes in a copolymer of glycolide and lactide occuring as a result of hydrolysis. J Appl Polym Sci Polym Phys Ed 22:57
Kulkarni RK, Pani KC, Neuman BS, Leonard F (1966) Polylactic acid for surgical implants. Arch Surg 93:839
Cutright DE, Hunsuck EE (1971) Tissue reaction to the biodegradable polylactic acid suture. Oral Surg 31:134
Cutright DE, Hunsuck EE, Beasley JD (1971) Fracture reduction using a biodegradable material, polylactic acid. J Oral Surg 29:393
Outright DE, Hunsuck EE (1972) The repair of fractures of the orbital floor using biodegradable polylactic acid. Oral Surg 33:28
Cutright DE, Perez B, Beasley JD, Larson WJ, Posey WR (1974) Degradation rates of polymers and copolymers of polylactic and polyglycolic acids. Oral Surg 37:142
Brady JM, Cutright DE, Miller RA, Battistone GC (1973) Resorption rate, route of elimination, and ultrastructure of the implant site of polylactic acid in the abdominal wall of the rat. J Biomed Mater Res 7:155
Getter L, Cutright DE, Bhaskar SN, Augsburg JK (1972)A biodegradable intraosseous applicance in the treatment of mandibular fractures. J Oral Surg 30:344
Ruderman RJ, Bernstein E, Kairinen E, Hegyeli AF (1973) Scanning electron microscopic study of surface changes on biodegradable sutures. J Biomed Mater Res 7:215
Jamshidi K, Hyon SH, Nakamura T, Ikada Y, Shimizu Y, Teramatsu T (1986) In vitro and in vivo degradation of poly(L-lactide) fibres. In: Christel P, Meunier A, Lee AJC (eds) Biological and Biomechanical Performance of Biomaterials. Elsevier, Amsterdam, p 227
Bos RRM, Rozema FR, Boering G, Leenslag JW, Pennings A J, Verwey AB (1988) In vivo and in vitro degradation of poly(L-lactide) used for fracture fixation. In: de Putter C, de Lange GL, de Groot K, Lee AJC (eds) Implant Materials in Biofunction. Elsevier, Amsterdam, p 245
Leenslag JW, Pennings AJ, Bos RRM, Rozema FR, Boering G (1987) Resorbable materials of poly(L-lac-tide). VI. Plates and screws for internal fracture fixation. Biomaterials 8:70
Vert M, Christel P, Chabot F, Leray J (1984) Bioresorbable plastic materials for bone surgery. In: Hastings GW, Ducheyne P (eds) Macromolecular BiomaterialsCRC Press, Boca Raton, FL, p 119
Vert M, Chabot F (1981) Stereoregular bioresorbable polyesters for orthopedic surgery. Makromol Chem [Suppl 5]
Chawla AS, Chang TMS (1985–86) In vivo degradation of poly(lactic acid) of different molecular weights. Biomat Med Dev Art Org 13(3&4):153
Pitt CG, Gratzl MM, Kimmel GL, Surles J, Schindler A (1981) Aliphatic polyesters II. The degradation of poly(DL-lactide), poly(E-caprolactone), and their copolymers in vivo. Biomaterials 2:215
Woodward SC, Brewer PS, Moatamed F, Schindler A, Pitt CG (1985) The intracellular degradation of poly(E-caprolactone). J Biomed Mater Res 19:437
Pitt CG, Hendren RW, Schindler A, Woodward SC (1984) The enzymatic surface errosion of aliphatic polyesters. J Control Rel 1:3
Gilbert RD, Stannett V, Pitt CG, Schindler A (1982) The design of biodegradable polymers: Two approaches. In: Grassie N (ed) Development in Polymer Degradation, vol 4. Applied Science, London, p 259
Mason NS, Miles CS, Sparks RE (1985) Hydrolytic degradation of poly(DL-lactide). Polym Mater Sci Eng 53:436
Schindler A, Harper D (1979) Polylactide. II. Viscosity-molecular weight relationships and unperturbed chain dimensions. J Polym Sci Chem Ed 17:2593
Vert M, Chabot F, Leray J, Christel P (1978) French Pat Appl 78/29978
Garreau H, Vert M (1986) Dynamic mechanical properties of a bioresorbable composite material aimed at internal fixation of bone fractures. Proc 5th PIMS Conference, Nordwijkerhout, Holland, 17/1
Törmälä P, Rokkanen P, Laiho J, Tamminmäki M (1985) Finish Pat Appl 85/1828
Törmälä P, Laiho J, Helevirata P, Rokkanen P, Vainionpää S, Böstman O, Kilpikari J (1986) Resorbable surgical device. Proc 5th PIMS Conference, Nordwijkerhout, Holland, 16/1
Tunc DC (1988) Absorbable bone fixation device, European Pat Spec, 0108635 (Appl 83306762.2)
Tunc DC, Balkrishna J (1988) Development of absorbable, ultra high strength polylactide. Polym Preprints (ACS) 29:383
Ciferri A, Ward IM (eds) (1979) Ultra-high modulus polymers. Applied Science, London
Eling B, Gogolewski S, Pennings A J (1982) Biodegradable materials of poly(L-lactide). Melt-spun and solution-spun fibres. Polymer 23:1587
Gogolewski S, Pennings A J (1983) Resorbable materials of poly(L-lactide). II. Fibres spun from solution of poly(L-lactide) in good solvents. J Appl Polym Sci 28:1045
Törmälä P, Rokkanen P, Vainionpää S, Laiho J, Heponen VP, Pohjonen T (1988) New surgical materials and devices, Intern Pat Appl W088/05312
Tunc DC, Lehman WB, Strongwater A, Kummer F, Kramer M (1986) Osteosynthesis device. Trans 12th Soc Biomat Meeting, Minneapolis-St Paul, USA, p 166
Tunc DC, Rohovsky MW, Jadhav B, Lehman WB, Strongwater A, Kummer F (1987) Body absorbable osteosynthesis device. Polym Sci Technol 35:87
Tunc DC (1986) State-of-the art in absorbable polymers in hard tissue repair. Polymer Preprints 27:431
Tunc DC, Rohovsky MW, Jadhav B, Lehman WB, Strongwater A, Kummer F (1985) Evaluation of body absorbable bone fixation device. Polym Mater Sci Eng 53:502
Hyon SH, Ikada Y (1986) Some surgical applications of poly(lactic acid). Proc 5th PIMS Conference, Nordwijkerhout, Holland, 40/1
Kelly BS, Dunn RL, Casper RA (1985) Totally resorbable high-strength composite material. Polym Sci Technol 35:75
Casper RA, Kelly BS, Dunn RL, Potter AG, Ellis DN (1985) Fiber-reinforced absorbable composite for orthopedic surgery. Polym Mater Sci Eng 53:497
Hollinger JO (1983) Preliminary report on the osteogenic potential of polylactide (PLA) and polyglycolide (PGA). J Biomed Mater Res 17:71
Hollinger JO, Battistone GC (1986) Biodegradable bone repair materials. Synthetic polymers and ceramics. Clin Orthop 27:290
Gay B, Bucher H (1985) Tierexperimentelle Untersuchungen zur Anwendung von absorbierbaren Osteosyntheseschrauben aus Polydioxanon (PDS). Unfallchirurg 88:126
Gerlach KL, Eitenmüller J (1987) In vivo evaluation of 8 different polymers for use as osteosynthesis material in maxillofacial surgery. In: Pizzoferrato A, Marchetti PG, Ravaglioli A, Lee AJC (eds) Biomaterials & Clinical Applications. Elsevier, Amsterdam, p 439
Eitenmüller J (1988) Biodegradierbare Plattenmaterialien im Tierversuch. In: Pannike A (ed) Unfallheilkunde, Heft 200. Springer, Berlin Heidelberg New York Tokyo, p 648
Greve H, Holste J (1985) Synthetic absorbable material for refixation of small fragments or of tendon or ligament osseous disrupture in animal experiments. In: Stelzner F (ed) Chirurgisches Forum ’85. Springer, Berlin Heidelberg New York Tokyo, p 9
Greve H, Clajus P, Dittrich H (1986) Verschluß der medianen Sternotomie mit resorbierbaren Kunststoffkordeln. Langenbecks Arch Chir 368:65
Cornah J, Wallace J (1988) Polydioxanone (PDS): A new material for internal suspension and fixation. Br J Oral Maxillofacial Surg 26:250
Rehm KE, Schultheis KH (1985) Bandersatz mit Polydioxanon (PDS). Unfallchirurgie 11:264
Schweiberer L, Habermeyer P, Kruger P, Schiller K, Wiedeman E (1988) Der heutige Stand der Bandverletzungen großer Gelenke. Chirurg 59:689
Tscherne H, Lebenhoffer P, Blauth M, Hoffmann R (1987) Primäre Rekonstruktion von Kapselbandverletzungen des Kniegelenkes. Orthopäde 16:113
Haupt PR, Duspiva W (1988) PDS-Augmentationplastik bei Kreuzbandverletzungen. Unfallchirurg 91:97
Lebenhoffer P, Blauth M, Tscherne H (1988) Resorbierbare Augumentationplastik und funktionelle Nachbehandlung bei frischer vorderer Kreuzbandruptur. Z Orthop 126:296
Aragona J, Parsons JR, Alexander H, Weiss AB (1983) Medical collateral ligament replacement with a partially absorbable tissue scaffold. Am J Sports Med 11:228
van Lack W, Casser HR (1989) Arthroscopic treatment of osteochondritis dissecans of the femoral condyle. Arthroskopie 2:16
Dürnbach J (1987) Osteosynthese mit resorbierbaren PDS-Stiften nach sagittaler Spaltung und Rückversetzung des Unterkiefers. Dtsch Zahnärtzl Z 42:825
Greve H, Holste J (1985) Refixation osteochondraler Fragmente durch resorbierbare Kunststoffstifte. Akt Traumatol 15:145
Claes L, Burri C, Kiefer H, Mutschier W (1986) Resorbierbare Implantate zur Refixierung von osteochondralen Fragmenten in Gelenkflächen. Akt Traumatol 16:74
Haas HG (1986) PDS-Splinte zur Frakturbehandlung. Handchirurgie 18:295
Dürnbach J (1987) Osteosynthese mit resorbierbaren PDS-Stiften nach sagittaler Spaltung und Rückversetzung des Unterkiefers, erste Ergebnisse. Dtsch Zahnärztl Z 42:825
Becker D (1988) Erhaltungsoperation bei Radiusköpfchenfraktur mittels Pinnung mit dem resorbierbaren Material Biofix. Handchirurgie 20:157
Leixnering M, Moser KL, Poigenfürst J (1989) Die Verwendung von Biofix C zur Stabilisierung von In- nenknöchelfrakturen. Akt Traumatol 19:113
Hoffmann R, Krettek C, Haas N, Tscherne H (1989) Die distale Radiusfraktur. Frakturstabilisierung mit biodegradablen Osteosynthese-Stiften (Biofix). Unfallchirurg 92:430
Urist MR (1986) Biodegradable organic polymer delivery system for bone morphogenetic protein. US Patent 4.563.489
Brekke JH (1980) Device and method for treating and healing a newly created bone void. US Patent 4.186.448
Higashi S, Yamamuro T, Nakamura T, Ikada Y, Hyon SH, Jamashidi K (1986) Polymer-hydroxyapatite composites for biodegradable bone fillers. Biomaterials 7:183
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© 1991 Springer-Verlag
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Wolter, D. (1991). Der Plattenfixateur interne für lange Röhrenknochen. In: Wolter, D., Zimmer, W. (eds) Die Plattenosteosynthese und ihre Konkurrenzverfahren. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-76328-1_38
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