Site-Dependent Osseointegration of Biodegradable High-Purity Magnesium for Orthopedic Implants in Femoral Shaft and Femoral Condyle of New Zealand Rabbits

doi:10.1016/j.jmst.2016.03.012

Abstract

Abstract:

Magnesium (Mg) has been widely accepted as osteoconductive biomaterial, but osseointegration of Mg device at different implantation sites is still unclear. In the present study, high-purity magnesium (HP Mg) pins were implanted into femoral shaft and condyle of New Zealand rabbits concurrently. 2, 8, 12 and 16 weeks after surgery, rabbit femurs were harvested for micro-computed tomography (micro-CT) scanning and subsequent histological examinations. HP Mg pins were retrieved for scanning electron microscope and energy dispersive spectrum (SEM/EDS) analyses. HP Mg pins at both implantation sites performed stable corrosion with mineral deposition and bone incorporation on surface. However, difference in distribution of contact osteogenesis centers and biological properties of peri-implant bone tissues was detected between femoral shaft and femoral condyle. In femoral condyle, contact osteogenesis centers originated from both periosteum and cancellous bones and the whole HP Mg pin was encapsuled in trabecular bone at 16 weeks. Meanwhile, bone volume to total bone volume (BV/TV) and bone mineral density (BMD) of peri-implant bone tissues were above those of normal bone tissues. In femoral shaft, contact osteogenesis centers were only from periosteum and direct bone contact was confined in cortical bone, while BV/TV and BMD kept lower than normal. Furthermore, new formation of peri-implant bone tissues was more active in femoral condyle than in femoral shaft at 16 weeks. Therefore, although HP Mg performed good biocompatibility and corrosion behavior in vivo, its bioadaption of osseointegration at different implantations sites should be taken into consideration. Bone metaphysic was suitable for Mg devices where peri-implant bone tissues regenerated rapidly and the biological properties were close to normal bone tissues.

Key words: Osseointegration, High-purity magnesium, Site-dependent, Femoral shaft and condyle, Bioadaption

Cheng Pengfei,Zhao Changli,Han Pei,Ni Jiahua,Zhang Shaoxiang,Zhang Xiaonong,Chai Yimin. Site-Dependent Osseointegration of Biodegradable High-Purity Magnesium for Orthopedic Implants in Femoral Shaft and Femoral Condyle of New Zealand Rabbits[J]. J. Mater. Sci. Technol., 2016, 32(9): 883-888.

Figures/Tables 7

Fig. 1. (a) Picture of HP Mg pins; (b) diagrammatic drawing showing the implantation of HP Mg pins in femoral shaft (red arrow) and condyle (black arrow).

Fig. 2. (a) In vivo 3-D μCT images of the implanted HP Mg pins; (b) pin surface of HP Mg pins in femora shaft and condyle at 2, 8, 12 and 16 weeks; (c) volume loss of HP Mg pins in femora shaft and condyle at 2, 8, 12 and 16 weeks (#p?>?0.05, *p?<?0.05, **p?<?0.01).

Fig. 3. SEM images of HP Mg pins in femoral shaft (a) and femoral condyle (c) and the corresponding EDS spectrum of the region in red rectangular (b, d).

Fig. 4. 2-D slices of micro-CT scans exhibiting the femoral shaft and femoral condyle. HP Mg pins are shown at the full length at 2, 8, 12 and 16 weeks.

Fig. 5. (a) 3-D reconstruction of peri-implant bone tissues and HP Mg pins (cortical portion and bone marrow portion) in femoral shaft at 16 weeks; (b) 3-D reconstruction of peri-implant bone tissues and HP Mg pins (cortical portion and bone marrow portion) in femoral condyle at 16 weeks.

Fig. 6. BV/TV (a) and BMD (b) of peri-implant bone tissues calculated from micro-CT scanning (#p?>?0.05, *p?<?0.05, **p?<?0.01).

Fig. 7. (a) Representative microphotographs showing bone regeneration and incorporation on the surface of HP Mg pins. The green line indicates new bone formation at 16 weeks, and white arrow reflects bone ingrowth on pin surface; (b) BIC calculated by histological slices (#p?>?0.05, **p?<?0.01).

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