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Notes:

Volume 3, Issue 4 (Suppl)

J Clin Exp Orthop

ISSN:2471-8416

Osteoporosis and Arthroplasty 2017

December 04-05, 2017

&

11

th

International Conference on

Joint Event

OSTEOPOROSIS, ARTHRITIS & MUSCULOSKELETAL DISORDERS

December 04-05, 2017 | Madrid, Spain

10

th

INTERNATIONAL CONFERENCE ON ARTHROPLASTY

In vivo

investigation of nanoscale silicon nitride particles

Jayna Patel, S Lal, S P Wilshaw, B von Rechenberg, K Nuss, R M Hall

and

J L Tipper

University of Leeds, UK

Introduction:

Biocompatible coatings, such as silicon nitride (SiN), may improve the performance of joint replacements. SiN particles

dissolve, which would minimize any associated reactions. Furthermore, the ions produced are non-toxic. In this study, SiN particles

were investigated for biocompatibility and isolated using a novel methodology for further analysis.

Methods:

Commercial nanoscale SiN particles, or clinically relevant CoCr or titanium particles generated by pin-on-plate simulation,

were injected into the right stifle joint of rats at a volume of 0.018 mm3 of particles. After seven days of in vivo exposure, animals were

euthanized, and the intact treated and contralateral non-treated stifle joints were formalin fixed and either decalcified and processed

histologically for H&E staining or subjected to a particle isolation protocol. The isolation protocol involved enzymatic digestion

with papain (1.56 mg. mL-1) and proteinase K (1 mg. mL-1, with two subsequent replenishments), and use of sodium polytungstate

(SPT) for density gradient ultracentrifugation. Residual SPT was removed and recovered particles were filtered and analyzed by high

resolution scanning electron microscopy (SEM) coupled with energy dispersive X-ray spectroscopy (EDX) for elemental analysis.

Imaging software (ImageJ) was used to determine size and morphologies (aspect ratio and circularity) of the particles. Particles not

subjected to the isolation procedure were analyzed for comparison.

Results and Discussion:

SiN particles were aggregated, relatively spherical and up to 60 nm in size, with a modal size range of 20-30

nm. Differences in size and morphology of SiN and CoCr particles before and after isolation were statistically insignificant (KS tests,

p>0.05). Titanium particles showed no aggregation characteristics, were of varying morphology, and had a size range from 0.1-100

µm, with a modal size of 10-15 µm. Titanium particles were too few before and after isolation to statistically analyze, though size and

morphologies were similar. Elemental analysis validated particle composition. Particles were not detected in non-treated stifle joints,

demonstrating that particles were not a result of contamination. Initial particle and tissue quantities were low compared to human

periprosthetic tissue samples, indicating technique sensitivity. In the histology analysis, CoCr injected joints displayed necrosis,

which was absent from SiN and titanium injected joints. Inflammation was greater in the CoCr samples.

Conclusion:

Overall the isolation methodology successfully enabled retrieval and characterization of SiN particles, in addition to

CoCr and titanium particles. Histological analysis indicated that SiN is more biocompatible than CoCr. Future work aims to further

evaluate the histology sections through immunolabelling and semi-quantitative scoring.

Biography

Jayna Patel is pursuing her PhD at the University of Leeds. Her research involves wear particle isolation and the evaluation of joint replacement materials for

biocompatibility. Previously, she studied Biological Sciences at Lancaster University.

jaynapatel1@gmail.com

Jayna Patel et al., J Clin Exp Orthop 2017, 3:4(Suppl)

DOI: 10.4172/2471-8416-C1-002