Single flexion-axis selection influences femoral component alignment and kinematics during knee simulation

Abstract

The objective of this paper is to investigate the effect of the implant geometry and alignment on its surface displacement, and to show that the proposed method of alignment can be used to improve the consistency of total knee replacement alignment for knee simulation. Poor femoral flexion-axis selection in the alignment process can possibly alter the intended design's functionality and introduce significant anterior/posterior (A/P), and proximal/distal (P/D) displacements. In the study, four multi-axis femoral components from each of two different manufacturers, NKII and 3DKnee, were used. A custom-built femoral alignment and surface measurement instrument was used to adjust and locate the single femoral axis position for each implant, which would optimally minimize their P/D displacements and A/P translations. The aligned NKII implants yielded a mean implant maximum P/D and A/P contact point shifts of 0.577 ± 0.078 mm (± std. dev.) and of 2.325 ± 0.243 mm between 0 and 60° of flexion, which was significantly different from the aligned 3DKnee, 0.415 ± 0.157 mm and 0.800 ± 0.1512 mm (p < 0.0001, p < 0.0001). Future work is needed to quantify the effect of femoral flexion axis selection on resulting long-term wear, damage areas, and soft tissue loading during simulation.

Keywords

camming flexion axis femoral axis multi-radius femoral component axis of rotation alignment fixture knee simulator total knee replacement femoral component alignment

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References

Harman

M. K.

DesJardins

Benson

Banks

S. A.

LaBerge

Hodge

W. A.

Comparison of polyethylene tibial insert damage from in vivo function and in vivo wear simulation. J. Orthop. Res., 2009, 27, 540–548.

Walker

P. S.

Blunn

G. W.

Perry

J. P.

Bell

C. J.

Sathasivam

Andriacchi

T. P.

Paul

J. P.

Haider

Campbell

P. A.

Methodology for long-term wear testing of total knee replacements. Clin. Orthop. Relat. Res., 2000, 372, 290–301.

McKellop

Clarke

l. C.

Evolution and evaluation of materials screening machines and joint simulators in predicting in vivo wear phenomena. In Functional behavior of orthopedic biomaterials, vol. 2 (Eds Ducheyne

Hastings

G. W.

), 1984, pp. 51–85 (CRC Press, Boca Raton, Florida).

Beaule

P. E.

Campbell

P. A.

Walker

P. S.

Schmalzried

T. P.

Dorey

F. J.

Blunn

G. W.

Bell

C. J.

Yahia

Amstutz

H. C.

Polyethylene wear characteristics in vivo and in a knee stimulator. J. Biomed. Mater. Res., 2002, 60, 411–419.

Clarke

I. C.

Gustafson

Jung

Fujisawa

Hip-simulator ranking of polyethylene wear: comparisons between ceramic heads of different sizes. Acta Orthop. Scand., 1996, 67, 128–132.

Tamura

Clarke

I. C.

Kawanabe

Akagi

Good

V. D.

Williams

P. A.

Masaoka

Schroeder

Oonishi

Micro-wear patterns on UHMWPE tibial inserts in total knee joint simulation. J. Biomed. Mater. Res., 2002, 61, 218–225.

Banks

S. A.

Hodge

W. A.

Implant design affects knee arthroplasty kinematics during stair-stepping. Clin. Orthop. Relat. Res., 2004, 426, 187–193.

Morra

E. A.

Harman

M. K.

Greenwald

A. S.

Computational models can predict polymer insert damage in total knee replacements. In Surgery of the knee, fourth edition (Eds Insall

J. N.

Scott

W. N.

), 2005, pp. 271–283 (Elsevier, New York, New York).

DesJardins

J. D.

Banks

S. A.

Benson

L. C.

Pace

LaBerge

A direct comparison of patient and force-controlled simulator total knee replacement kinematics. J. Biomech., 2007, 40, 3458–3466.

10.

Rawlinson

J. J.

Furman

B. D.

Wright

T. M.

Bartel

D. L.

Retrieval, experimental, and computational assessment of the performance of total knee replacements. J. Orthop. Res., 2006, 24, 1384–1394.

11.

Weiss

J. M.

Noble

P. C.

Conditt

M. A.

Kohl

H. W.

Roberts

Cook

K. F.

Gordon

M. J.

Mathis

K. B.

What functional activities are important to patients with knee replacements?

Clin. Orthop. Relat. Res., 2002, 404, 172–188.

12.

Morrison

J. B.

Function of the knee joint in various activities. Biomed. Engng, 1969, 4, 573–580.

13.

D’Lima

D. D.

Hermida

J. C.

Chen

P. C.

Colwell

C. W.

Polyethylene wear and variations in knee kinematics. Clin. Orthop. Relat. Res., 2001, 392, 124–130.

14.

Johnson

T. S.

Laurent

M. P.

Yao

J. Q.

Gilbertson

L. N.

The effect of displacement control input parameters on tibiofemoral prosthetic knee wear. Wear, 2001, 250, 222–226.

15.

Nozaki

Banks

S. A.

Suguro

Observations of femoral rollback in cruciate-retaining knee arthroplasty. Clin. Orthop., 2002, 404, 308–314.

16.

McEwen

H. M.

Barnett

P. I.

Bell

C. J.

The influence of design, materials and kinematics on the in vitro wear of total knee replacements. J. Biomech., 2005, 38, 357–365.

17.

DesJardins

J. D.

Walker

P. S.

Haider

Perry

The use of a force-controlled dynamic knee simulator to quantify the mechanical performance of total knee replacement designs during functional activity. J. Biomech., 2000, 33, 1231–1242.

18.

Van Houtem

Clough

Khan

Harrison

Blunn

G. W.

Validation of the soft tissue restraints in a force-controlled knee simulator. 2006, Proc. IMechE, Part. H: J. Engng Med., 220, 449–456.

19.

Benson

L. C.

DesJardins

J. D.

LaBerge

Effects of in vitro wear of machined and molded UHMWPE tibial inserts on TKR kinematics. J. Biomed. Mater. Res., 2001, 58, 496–504.

20.

Benson

L. C.

DesJardins

J. D.

Harman

M. K.

LaBerge

Effect of stair descent loading on ultra-high molecular weight polyethylene wear in a force-controlled knee simulator. Proc. IMechE, Part. H: J. Engng Med., 2002, 216, 409–418.

21.

Victor

Rotational alignment of the distal femur: a literature review. Orthop. Traumatol.: Surg. Res., 2009, 95, 365–372.

22.

Skolnick

M. D.

Coventry

M. B.

Ilstruo

D. M.

Geometric total knee arthroplasty. A two-year follow-up study. J. Bone Joint Surg., 1976, 58, 749–753.

23.

Lotke

Ecker

Influence of position of prosthesis in total knee replacement. J. Bone Joint Surg., 1977, 59, 77–79.