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Abstract

Background:

Trabecular metal implants with a porous architecture that allows for the incorporation of bone into the implant during healing are gaining popularity in alloplastic revision procedures. The bi-products of drilling titanium alloy (Ti) and tantalum (Ta) implants have not been previously assessed.

Methods:

Four holes were drilled in each of 2 spatially porous trabecular implants, one Ta and the other Ti alloy (Ti-6Al-7Nb), for this pilot in vitro study. The particles were flushed out with a continuous flow of saline. The particles’ weight and the volume were then measured using a Radwag XA 110/2X (USA) laboratory balance. The total volume of the obtained metal fines was measured by titration using a 10 mm³ measurement system.

Results:

A cobalt carbide bit was used since the holes could not be made with a standard bone drill. Each Ti and Ta implant lost 1.26 g and 2.48 g of mass, respectively. The volume of free particles recovered after each stage was 280 mm³ and 149 mm³, respectively. Approximately 0.6% of the total implant mass was not recovered after drilling (roughly 2% of the mass of the particles created by drilling), despite the use of 5 µm filters.

Conclusions:

It is technically difficult to drill holes in Ti and Ta implants using standard surgical tools. The drilling process creates a considerable amount of metal particles, which cannot be recovered despite intensive flushing. This may have an adverse influence on the bio-functionality (survival) of the endoprosthesis and present deleterious systemic consequences.

Keywords

Arthroplasty augments drilling hip loosening revision

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References

Levine

Sporer

Poggie

et al . Experimental and clinical performance of porous tantalum in orthopedic surgery. Biomaterials 2006; 27: 4671–4681.

Meneghini

Ford

McCollough

et al . Bone remodeling around porous metal cementless acetabular components. J Arthroplasty 2010; 25: 741–747.

Meneghini

Meyer

Buckley

et al . Mechanical stability of novel highly porous metal acetabular components in revision total hip arthroplasty. J Arthroplasty 2010; 25: 337–341.

Bobyn

Stackpool

Hacking

et al . Characteristics of bone ingrowth and interface mechanics of a new porous tantalum biomaterial. J Bone Joint Surg Br 1999; 81: 907–914.

Hacking

Bobyn

Toh

et al . Fibrous tissue ingrowth and attachment to porous tantalum. J Biomed Mater Res 2000; 52: 631–638.

Boureau

Putman

Arnould

et al . Tantalum cones and bone defects in revision total knee arthroplasty. Orthop Traumatol Surg Res 2015; 101: 251–255.

Kamada

Mashima

Nakashima

et al . Mid-term clinical and radiographic outcomes of porous tantalum modular acetabular components for hip dysplasia. J Arthroplasty 2015; 30: 607–610.

Papadelis

Karampinas

Kavroudakis

et al . Isolated subtalar distraction arthrodesis using porous tantalum: a pilot study. Foot Ankle Int 2015; 36: 1084–1088.

Papi

Jamshir

Brauner

et al . Clinical evaluation with 18 months follow-up of new PTTM enhanced dental implants in maxillo-facial post-oncological patients. Ann Stomatol (Roma) 2014; 5: 136–141.

10.

Sagherian

Claridge

. Salvage of failed total ankle replacement using tantalum trabecular metal: case series. Foot Ankle Int 2015; 36: 318–324.

11.

Fernandez-Fairen

Hernandez-Vaquero

Murcia

et al . Trabecular metal in total knee arthroplasty associated with higher knee scores: a randomized controlled trial. Clin Orthop Relat Res 2013; 471: 3543–3553.

12.

Eger

Sterer

Liron

et al . Scaling of titanium implants entrains inflammation-induced osteolysis. Sci Rep 2017; 7: 39612.

13.

Hallab

Cunningham

Jacobs

. Spinal implant debris-induced osteolysis. Spine (Phila Pa 1976) 2003; 28: S125–S138.

Unrecoverable bi-products of drilling titanium alloy and tantalum metal implants: a pilot study