Effect of simulated muscle activity on distal radioulnar joint loading in vitro

Gordon, Karen D.; Kedgley, Angela E.; Ferreira, Louis M.; King, Graham J.W.; Johnson, James A.

doi:10.1002/jor.20138

Cited by 7 publications

(21 citation statements)

References 19 publications

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“…11,12 Therefore, during wear testing, 10 N of normal force should be sufficient. However, to quantify the worst-case scenario, we chose a force 11 times greater than that predicted and consistently used 110 N for both friction measurements and the wear test.…”

Section: Discussionmentioning

confidence: 99%

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Isoelastic Distal Ulnar Head Prosthesis: An In Vitro Joint Simulator Study

Naidu

Radin

2009

The Journal of Hand Surgery

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Section: Discussionmentioning

confidence: 99%

“…com; Vashon, WA). A specialized fixture with a built-in spring that generated 110 N (25 lb) of normal (perpendicular) force 11,12 was mounted to the fixture housing the synthetic bone counterface (Fig. 1).…”

Section: Lubricitymentioning

confidence: 99%

Isoelastic Distal Ulnar Head Prosthesis: An In Vitro Joint Simulator Study

Naidu

Radin

2009

The Journal of Hand Surgery

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“…7–11,13,14,28 However, prior methods have all involved major disruptions of periarticular soft tissues, which likely altered normal joint mechanics. In addition, methods that involve capsulotomy for sensor insertion result in loss of negative intra-articular pressure and its stabilizing suction effect.…”

Section: Discussionmentioning

confidence: 99%

“…The periarticuar soft tissue dissection required in these studies altered the normal mechanics of the DRUJ. 13,14 …”

mentioning

confidence: 99%

A Nondestructive, Reproducible Method of Measuring Joint Reaction Force at the Distal Radioulnar Joint

Canham¹,

Schreck²,

Maqsoodi³

et al. 2015

The Journal of Hand Surgery

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Purpose To develop a nondestructive method of measuring distal radioulnar joint (DRUJ) joint reaction force (JRF) that preserves all periarticular soft tissues and more accurately reflects in vivo conditions. Methods Eight fresh-frozen human cadaveric limbs were obtained. A threaded Steinmann pin was placed in the middle of the lateral side of the distal radius transverse to the DRUJ. A second pin was placed into the middle of the medial side of the distal ulna colinear to the distal radial pin. Specimens were mounted onto a tensile testing machine using a custom fixture. A uniaxial distracting force was applied across the DRUJ while force and displacement were simultaneously measured. Force-displacement curves were generated and a best-fit polynomial was solved to determine JRF. Results All force-displacement curves demonstrated an initial high slope where relatively large forces were required to distract the joint. This ended with an inflection point followed by a linear area with a low slope, where small increases in force generated larger amounts of distraction. Each sample was measured 3 times and there was high reproducibility between repeated measurements. The average baseline DRUJ JRF was 7.5 N (n = 8). Conclusions This study describes a reproducible method of measuring DRUJ reaction forces that preserves all periarticular stabilizing structures. This technique of JRF measurement may also be suited for applications in the small joints of the wrist and hand. Clinical relevance Changes in JRF can alter native joint mechanics and lead to pathology. Reliable methods of measuring these forces are important for determining how pathology and surgical interventions affect joint biomechanics.

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“…Specifically, changes in both muscle force and moment arms have been demonstrated. Altered muscle forces may lead to an altered joint reaction force, which is an important consideration in implant design [11]. Joint reaction force plays a crucial role in joint stability, counterbalancing the forces transmitted across the joint surface due to body weight, muscle contraction and other applied loads [2].…”

Section: Introductionmentioning

confidence: 99%

The effect of elbow joint centre displacement on force generation and neural excitation

Doheny

Lowery

O’Malley

et al. 2009

Med Biol Eng Comput

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Joint centre displacement may occur following total elbow replacement due to aseptic loosening or surgical misalignment, and has been linked to implant failure. In this study, the effects of joint centre displacement were examined using a neuromusculoskeletal model of the elbow joint. Isometric contractions were simulated at a range of joint angles during elbow flexion and extension. Displacement of the joint centre affected the force-generating capacity about the joint, due to changes in both muscle lengths and moment arms. The magnitude and direction of the maximum joint reaction force were also altered, potentially contributing to aseptic loosening and compromising joint stability. The relationship between force generated and the level of neural excitation to the elbow flexor and extensor muscles was also affected, suggesting that altered neural control patterns could be required following joint centre displacement.

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Effect of simulated muscle activity on distal radioulnar joint loading in vitro

Cited by 7 publications

References 19 publications

Isoelastic Distal Ulnar Head Prosthesis: An In Vitro Joint Simulator Study

Isoelastic Distal Ulnar Head Prosthesis: An In Vitro Joint Simulator Study

A Nondestructive, Reproducible Method of Measuring Joint Reaction Force at the Distal Radioulnar Joint

The effect of elbow joint centre displacement on force generation and neural excitation

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