Initial biocompatibility studies of a novel degradable polymeric bone substitute that hardens in situ

Initial biocompatibility studies of a novel degradable polymeric bone substitute that hardens in situ

Clinical management of osseous defects often requires bone grafts. The standard for treatment is autogenous bone harvested from sites such as either the iliac crest or the outer table of the calvaria. In addition to the problem of donor site morbidity and the limited supply of graft material, there...

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Bibliographic Details
Published in:Bone (New York, N.Y.) Vol. 19; no. 1; pp. S101 - S107
Main Authors: Bennett, Steven, Connolly, Kevin, Lee, Daniel R., Jiang, Ying, Buck, Dave, Hollinger, Jeffrey O., Gruskin, Elliott A.
Format: Journal Article Conference Proceeding
Language:English
Published: New York, NY Elsevier Inc 01-07-1996
Elsevier Science
Subjects:
Animals
Biodegradation, Environmental
Biological and medical sciences
Bone Substitutes - chemistry
Hardness
Materials Testing
Medical sciences
Molecular Structure
Orthopedic surgery
Polymers
Prostheses and Implants
Rats
Surgery (general aspects). Transplantations, organ and tissue grafts. Graft diseases
Dioxane derivatives
Implant
Rat
Rodentia
Diseases of the osteoarticular system
Glycolic acid polymer
Design
Vertebrata
Mammalia
Surgery
Animal
Biocompatibility
Biomaterial
Copolymer
Bone
Biomedical engineering
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Summary:Clinical management of osseous defects often requires bone grafts. The standard for treatment is autogenous bone harvested from sites such as either the iliac crest or the outer table of the calvaria. In addition to the problem of donor site morbidity and the limited supply of graft material, there is the additional operating time associated with harvesting procedures. A synthetic, bone graft substitute that can match the clinical performance of autogenous bone could alleviate these deficiencies. Therefore, a polymeric bone substitute was developed that consists of a four-armed star polymer of poly(dioxanone-co-glycolide) endcapped at each termini with a biocompatible lysine-based diisocyanate crosslinker. The polymer can be mixed with inorganic fillers such as either hydroxyapatite or tricalcium phosphate to form either injectable or moldable putty. The addition of a catalyst (for example, diethylaminoethanol and water) to the polymer produces a crosslinking reaction causing the combination to harden. This reaction is nontoxic, normo-thermic and can be performed in situ. During the course of the polymerization, carbon dioxide is liberated, producing an interconnected porous network within the implant, suitable for bone ingrowth. This paper will describe a preliminary biocompatibility assay of the bone substitute.
ISSN:8756-3282
1873-2763
DOI:10.1016/S8756-3282(96)00130-5