Biomechanical Evaluation of 5 Fixation Devices for Proximal Interphalangeal Joint Arthrodesis

Biomechanical Evaluation of 5 Fixation Devices for Proximal Interphalangeal Joint Arthrodesis

Purpose To determine in a cadaver model which, among 5 fixation methods for proximal interphalangeal (PIP) joint arthrodesis, has the greatest stiffness. Methods Thirty-five cadaver digits were randomly assigned to 1 of 5 fixation groups: oblique K-wire with coronal intraosseous wiring, tension-band...

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Bibliographic Details
Published in:The Journal of hand surgery (American ed.) Vol. 39; no. 10; pp. 1971 - 1977
Main Authors: Capo, John T., MD, Melamed, Eitan, MD, Shamian, Benhoor, MD, Hadley, Scott R., MD, Ng Lai, Whitney, BS, Gerszberg, Kenny, MD, Rivero, Steven, MD, Caravaggi, Paolo, PhD
Format: Journal Article
Language:English
Published: United States Elsevier Inc 01-10-2014
Subjects:
Adult
Arthrodesis
Arthrodesis - instrumentation
Biomechanical Phenomena
biomechanical testing
Bone Plates
Bone Screws
Bone Wires
Cadaver
Female
Finger Joint - diagnostic imaging
Finger Joint - physiopathology
Finger Joint - surgery
fusion
Humans
Male
Middle Aged
Orthopedics
PIP joint arthritis
Radiography
stiffness
fusion
Arthrodesis
stiffness
PIP joint arthritis
biomechanical testing
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Summary:Purpose To determine in a cadaver model which, among 5 fixation methods for proximal interphalangeal (PIP) joint arthrodesis, has the greatest stiffness. Methods Thirty-five cadaver digits were randomly assigned to 1 of 5 fixation groups: oblique K-wire with coronal intraosseous wiring, tension-band wire (TBW), dorsal plate, intramedullary linked screw (IMS), and 90/90 wiring (90/90W). Testing was done by applying bending moments to the PIP joint in the sagittal and frontal planes. The force/displacement curves were used to estimate the stiffness of each construct. Ultimate strength was determined by loading to failure in extension. Results The IMS had significantly higher stiffness than all wiring constructs in all planes of motion and significantly greater stiffness in extension than the dorsal plate. The IMS stiffness exceeded 10 N/mm across all bending directions and showed an ultimate strength of 21 N. The plate demonstrated higher stiffness in radial bending than the oblique K-wire with coronal intraosseous wiring and TBW. There were no differences in stiffness between the IMS and plate in all modes of testing except extension. Load-to-failure testing of the devices showed the IMS device to be significantly stronger than the TBW, 90/90W, and plating constructs. Conclusions The IMS resisted larger bending moments than all wiring constructs and showed the greatest ultimate strength when compared with 3 of the tested arthrodesis techniques. The plate was significantly better than 2 of the wiring constructs, but only in radial bending. No differences were found between the, TBW, and 90/90W when compared with each other. Clinical relevance The stiffness necessary for a successful PIP joint fusion has not been quantified, but according to this study, the IMS was the most favorable biomechanical construct for initial stability.
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ISSN:0363-5023
1531-6564
DOI:10.1016/j.jhsa.2014.07.035