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Osteocytes as indicators of bone quality - multiscale structure-composition characterisation of the bone-implant interface

Doctoral thesis
Authors Furqan A. Shah
Date of public defense 2017-09-22
ISBN 978-91-629-0260-5 (print)
Publication year 2017
Published at Institute of Clinical Sciences, Department of Biomaterials
Language en
Links hdl.handle.net/2077/52415
Keywords 3D printing, apatite, biomaterials, biomineralisation, bone, bone quality, canaliculi, CoCr, collagen, electron beam melting, electron microscopy, implant, interface, in vivo, lacuna, micropetrosis, osseointegration, osteocyte, Raman spectroscopy, surface modification, Ti6Al4V, titanium, ultrastructure, whitlockite
Subject categories Biomaterials Science

Abstract

By virtue of certain design features, bone anchored metal implants can be made to elicit a strong initial osteogenic response, i.e., the amount of bone formed. While quantitative differences are often lost at longer follow up times, do differences in the initial osteogenic response lead to long-term alterations in bone quality? This thesis investigates osseointegration in terms of bone quality, with an emphasis on the osteocyte lacuno-canalicular network (Ot.LCN) in relation to compositional and ultrastructural patterns observed at intermediate or late healing. A series of investigations was undertaken to study osteocyte lacunae on the forming bone surface (Paper I), hypermineralised lacunae of apoptotic osteocytes (Paper II), autogenous bone fragments found within healing sites (Paper III), bone formed adjacent to surface modified implants (Papers IV–VI), and bone formed within macroporous implants (Papers VII and VIII) using a range of analytical microscopy and complementary spectroscopic techniques. A directional relationship exists between the shape of the osteocyte lacuna and the underlying bone surface. The physico-chemical environment of the lacunar space is, however, different from the surrounding bone matrix, resulting in formation of a calcium phosphate phase more stable than apatite at lower pH, i.e., magnesium whitlockite. Connectivity between osteocytes within unintentionally generated autogenous bone fragments and de novo formed bone on their surface indicates a regenerative capacity of osteocytes. Laser- ablation creates a hierarchical micro- and nanotopography on titanium implants and enhances their biomechanical anchorage. Osteocytes attach directly to such surfaces, while mineralised collagen fibril organisation at bone-implant and bone-osteocyte interfaces is similar. More osteocytes are retained in the vicinity of Ti6Al4V surface as manufactured by electron beam melting than machined Ti6Al4V. In addition to cp-Ti and Ti6Al4V (ASTM F136), osteocytes also attach to CoCr (ASTM F75) thus indicating a favourable osteogenic response of a material generally considered inferior to Ti6Al4V. Therefore, osteocytes reveal vital information about bone quality and are important structural markers of osseointegration. Evaluation of the Ot.LCN can be extremely beneficial in characterising the bone response to materials intended for bone anchored, load bearing applications.

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