Recovery of low volumes of wear debris from rat stifle joint tissues using a novel particle isolation method

Patel, J., Lal, S., Nuss, K., Wilshaw, Stacy-Paul, von Rechenberg, B., Hall, R.M., Tipper, J.L.

02 March 2018

Yes / Less than optimal particle isolation techniques have impeded analysis of orthopaedic wear debris in vivo. The purpose of this research was to develop and test an improved method for particle isolation from tissue. A volume of 0.018 mm3 of clinically relevant CoCrMo, Ti-6Al-4V or Si3N4 particles was injected into rat stifle joints for seven days of in vivo exposure. Following sacrifice, particles were located within tissues using histology. The particles were recovered by enzymatic digestion of periarticular tissue with papain and proteinase K, followed by ultracentrifugation using a sodium polytungstate density gradient. Particles were recovered from all samples, observed using SEM and the particle composition was verified using EDX, which demonstrated that all isolated particles were free from contamination. Particle size, aspect ratio and circularity were measured using image analysis software. There were no significant changes to the measured parameters of CoCrMo or Si3N4 particles before and after the recovery process (KS tests, p > 0.05). Titanium particles were too few before and after isolation to analyse statistically, though size and morphologies were similar. Overall the method demonstrated a significant improvement to current particle isolation methods from tissue in terms of sensitivity and efficacy at removal of protein, and has the potential to be used for the isolation of ultra-low wearing total joint replacement materials from periprosthetic tissues.

Cobalt chromium

Particle isolation

Silicon nitride

Titanium

Total joint replacement

Wear

Validation of a novel particle isolation procedure using particle doped tissue samples

Patel, J., Lal, S., Wilshaw, Stacy-Paul, Hall, R.M., Tipper, J.L.

01 May 2018

Yes / A novel particle isolation method for tissue samples was developed and tested using particle-doped peri-articular tissues from ovine cadavers. This enabled sensitivity of the isolation technique to be established by doping tissue samples of 0.25 g with very low particle volumes of 2.5 µm3 per sample. Image analysis was used to verify that the method caused no changes to particle size or morphologies. / The European Union's Seventh Framework Programme (FP7/2007–2013) under grant agreement no. GA-310477, LifeLongJoints.

Novel particle isolation method

Tissue samples

Doping tissue samples

Image analysis