Literature DB >> 947921

Bone growth into porous high-density polyethylene.

M Spector, W R Flemming, A Kreutner.   

Abstract

The purpose of this study was to delineate the process by which bone comes to fill the pores of porous high-density polyethylene (PHDPE) implants. PHDPE (450 mu pore size) pellets 4 mm in diameter and 1 cm long were implanted into the femurs of dogs. A bone biopsy procedure was utilized to obtain PHDPE pellets implanted for periods of 3 days through 8 weeks. A one-year biopsy specimen taken from the PHDPE coating on the stem of a canine total-hip prosthesis was also studied. The results demonstrated that significant amounts of bone formed within the PHDPE pellets as early as 14 days after implantation. Bone was identified throughout the specimens after 4 weeks. After 6 weeks, the tissue in hematopoietic marrow. Scanning electron microscopy was utilized in conjunction with light microscopy and microradiography to study the ultrastructural features of the bone ingrowth process.

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Year:  1976        PMID: 947921     DOI: 10.1002/jbm.820100416

Source DB:  PubMed          Journal:  J Biomed Mater Res        ISSN: 0021-9304


  14 in total

1.  Reconstruction of the skull base and cranium adjacent to sinuses with porous polyethylene implant: preliminary report.

Authors:  W T Couldwell; C B Stillerman; W Dougherty
Journal:  Skull Base Surg       Date:  1997

Review 2.  A review of reconstructive materials for use in craniofacial surgery bone fixation materials, bone substitutes, and distractors.

Authors:  James Tait Goodrich; Adam L Sandler; Oren Tepper
Journal:  Childs Nerv Syst       Date:  2012-08-08       Impact factor: 1.475

3.  Survey of Common Practices among Oculofacial Surgeons in the Asia-Pacific Region: Management of Orbital Floor Blowout Fractures.

Authors:  Victor Koh; Nathalie Chiam; Gangadhara Sundar
Journal:  Craniomaxillofac Trauma Reconstr       Date:  2014-03-17

4.  Micro-computed tomography analysis of early stage bone healing using micro-porous titanium mesh for guided bone regeneration: preliminary experiment in a canine model.

Authors:  Yunia Dwi Rakhmatia; Yasunori Ayukawa; Yohei Jinno; Akihiro Furuhashi; Kiyoshi Koyano
Journal:  Odontology       Date:  2017-04-07       Impact factor: 2.634

5.  Shear strength of loaded porous-glassy-carbon/bone interface--an experimental study on rabbits.

Authors:  T Tarvainen; T Tunturi; J Rautavuori; P Törmälä; H Pätiälä; P Rokkanen
Journal:  Ann Biomed Eng       Date:  1986       Impact factor: 3.934

6.  Long-term results of high-density porous polyethylene implants in facial skeletal augmentation: An Indian perspective.

Authors:  Sanjeev Deshpande; Amarnath Munoli
Journal:  Indian J Plast Surg       Date:  2010-01

7.  Microscopic analysis of autograft bone applied at the interface of porous-coated devices in human cancellous bone.

Authors:  A A Hofmann; R D Bloebaum; M H Rubman; K N Bachus; R L Plaster
Journal:  Int Orthop       Date:  1992       Impact factor: 3.075

8.  Cementless Gustilo-Kyle and BIAS total hip arthroplasty: 2- to 5-year results.

Authors:  H Kienapfel; J Martell; A Rosenberg; J Galante
Journal:  Arch Orthop Trauma Surg       Date:  1991       Impact factor: 3.067

9.  The applicability of porous polyethylene for tympanoplasty; an animal experimental study.

Authors:  M Handrock; G Mulch; C Handrock
Journal:  Arch Otorhinolaryngol       Date:  1979

10.  Porous polyethylene and proplast: their behavior in a bony implant bed.

Authors:  A Berghaus; G Mulch; M Handrock
Journal:  Arch Otorhinolaryngol       Date:  1984
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