The influences of sex and posture on joint energetics during drop landings.

Previous observations suggest that females utilize a more erect initial landing posture than males with sex differences in landing posture possibly related to sex-specific energy absorption (EA) strategies. However, sex-specific EA strategies have only been observed when accompanied by sex differences in initial landing posture. This study (a) investigated the potential existence of sex-specific EA strategies; and (b) determined the influences of sex and initial landing posture on the biomechanical determinants of EA. The landing biomechanics of 80 subjects were recorded during drop landings in Preferred, Flexed, and Erect conditions. No sex differences in joint EA were identified after controlling for initial landing posture. Males and females exhibited greater ankle EA during Erect vs Flexed landings with this increase driven by 12% greater ankle velocity, but no change in ankle extensor moment. No differences in hip and knee EA were observed between conditions. However, to achieve similar knee EA, subjects used 7% greater mean knee extensor moment but 9% less knee angular velocity during Flexed landings. The results suggest that sex-specific EA strategies do not exist, and that the magnitude of knee joint EA can be maintained by modulating the relative contributions of joint moment and angular velocity to EA.

Comparison of the mechanical properties of different tension band materials and suture techniques.

OBJECTIVES: This study determined the tensile properties of 18-gauge stainless steel wire, 5-mm woven polyester (Mersilene) tape, and multiple loop configurations of No. 5 braided polyester suture (Ethibond). DESIGN: Mechanical property testing. INTERVENTION: Single loops of stainless steel wire, Mersilene, and Ethibond were tested to determine their mechanical properties. Ethibond was tested with different numbers of loops and different knot configurations. MAIN OUTCOME MEASURES: Stiffness, load at failure, and elongation at failure. RESULTS: One loop of Mersilene and two loops of Ethibond had similar loads at failure, but the load at failure was significantly higher for stainless steel wire. Four loops of Ethibond withstood a similar failure load to stainless steel wire, but the failure load of the Ethibond suture was greater than the yield load of stainless steel wire. Stainless steel wire had a higher stiffness than both Ethibond and Mersilene. No difference was found in the failure load between different Ethibond knot configurations. The individually tied suture configuration resulted in a higher stiffness than the single-knot configuration. The elongation at failure was not statistically different among the different knot configurations and materials, with the exception of Mersilene tape. Mersilene tape demonstrated a significant increase in elongation at failure as compared to the other materials and knot configurations. CONCLUSION: It appears that multiple loops of Ethibond can substitute for stainless steel wire in situations where a compliant repair is suitable (support of a patellar tendon repair), but may not be satisfactory for rigid fixation (tension band fixation of a fracture). There appears to be no significant difference in strength but a small decrease in stiffness between tying multiple suture loops in one knot as opposed to individual knots.

A cyclooxygenase-2 inhibitor impairs ligament healing in the rat.

Celecoxib was the first of a new class of nonsteroidal antiinflammatory drugs, the cyclooxygenase-2 (COX-2) specific inhibitors, marketed as having the same antiinflammatory efficacy as other nonsteroidal antiinflammatory drugs without their increased risk of gastrointestinal ulceration. Among the widest uses of nonsteroidal antiinflammatory drugs is in the treatment of acute soft tissue injuries. Although the benefits of celecoxib have been shown when used for rheumatoid arthritis and osteoarthritis, we are unaware of any studies concerning its effect on soft tissues. We used the surgically incised medial collateral ligament of male Sprague-Dawley rats as an experimental model for acute ligament injuries to investigate the effects of celecoxib on ligament healing. Fifty rats underwent surgical transection of the right medial collateral ligament. Postoperatively, half were given celecoxib for the first 6 days of recovery, the other half were not. The animals were sacrificed 14 days after the operation, and both the injured and uninjured medial collateral ligaments were mechanically tested to failure in tension. Celecoxib-treated/injured ligaments were found to have a 32% lower load to failure than untreated/injured ligaments. The results of this study do not support use of cyclooxygenase-2 specific inhibitors in the treatment of ligament injuries.

Computer simulation of trabecular remodeling using a simplified structural model.

A simplified three-dimensional simulation of trabecular bone remodeling has been developed. The model utilizes 441 planar structural units to represent approximately 50 mm3 of initial bone volume with 199 basic multicellular units (BMUs). The simulation takes into account trabecular perforation in the structural model. The cases of male bone remodeling with no menopause and female bone remodeling with menopause are examined from the period of simulated age 25-80 years. Menopause is arbitrarily started at age 45 and extends for 7.5 years. Zero-, first-, and second-order BMU activation responses are employed to examine how the bone would be affected by the method of increase of BMU activation during menopause. At age 80, the female bone remodeling simulation produced a bone volume loss of approximately 49% for all three activation responses. This compared to a 38% bone volume loss for the case of no menopause. For the menopause simulations, an average of about 40% of the total bone loss was due to perforation.

Assessment of the directional elastic moduli of ewe vertebral cancellous bone by vibrational testing.

The ovariectomized ewe is being used as an animal model for postmenopausal osteoporosis. Data on the mechanical properties of ewe vertebral cancellous bone is needed to assess its effectiveness as a model for vertebral osteoporosis. This study utilized traditional compression testing and a novel nondestructive vibrational testing method to assess the directional mechanical properties of ewe vertebral cancellous bone. Composition and density properties were also assessed. It was hypothesized that vibrational testing would have utility in that it would allow for the anisotropic stiffness of cancellous bone to be assessed nondestructively. The present study has found that ewe vertebral cancellous bone has similar physical and mechanical properties to humans. The vibrational testing method described was able to nondestructively provide a valid measure of stiffness that was correlated with stiffness estimates from traditional compression testing. Furthermore, the stiffness measure from the vibration test was found to be sensitive to the architecture of cancellous bone. These results suggest the promise of this testing method for the nondestructive mechanical assessment of skeletal tissue.

Comparison of tricortical screw fixation versus a modified suture construct for fixation of ankle syndesmosis injury: a biomechanical study.

OBJECTIVE: To assess the viability of using a modified flexible suture implant instead of a tricortical screw for fixation of ankle syndesmosis failures. DESIGN: Randomized biomechanical study. SETTING: Orthopaedic Research Laboratories at the University of North Carolina at Chapel Hill. INTERVENTION: Formalin-preserved cadaveric legs were used in pairs. Two holes, 2.5 millimeters in diameter and 7.0 to 10.0 millimeters apart horizontally, were drilled through the fibula and tibia 2.0 centimeters above the tibial plafond. Two strands of Number 5 suture were passed through the holes and tied. Similarly, a 3.5-millimeter tricortical screw was placed on the opposite leg of each pair at 2.0 centimeters. The ankles were tested to failure. This process was repeated at 5.0 centimeters above the tibial plafond. MAIN OUTCOME MEASUREMENTS: Maximum load and displacement at failure of the suture construct at 2.0 centimeters and at 5.0 centimeters were compared with a tricortical screw at 2.0 centimeters and at 5.0 centimeters. RESULTS: There was no significant difference in strength or displacement between the flexible suture implant and the tricortical screw at either 2.0 centimeters or 5.0 centimeters. The fixations at 5.0 centimeters had significantly increased holding strength over fixations at 2.0 centimeters, and the fixations had significantly greater displacement at 2.0 centimeters than at 5.0 centimeters. CONCLUSION: This study confirms that flexible syndesmosis repair is a viable option for internal fixation of ankle mortise instability due to syndesmosis rupture.

The significance of transient changes in trabecular bone remodeling activation.

After menopause, bone turnover is increased due to an increase in the activation of bone remodeling basic multicellular units (BMUs). The importance of changes in BMU activation to bone histomorphometry data and bone volume has not received adequate attention by many skeletal researchers. Therefore, the influence of BMU activation on the above parameters was modeled by way of computer simulation, and the results were compared to data from published post-menopausal bone loss studies. Using control theory concepts, the increase in BMU activation after menopause was modeled as a zero-, first-, or underdamped (oscillatory) second-order transient BMU activation response to the step input: the decline in estrogen. A computer simulation was developed to model the influence of these three transient BMU activation responses on quantitative histological surface parameters and bone volume. The transient BMU activation responses doubled the number of active BMUs. All three types of transient BMU activation responses produced a rapid 5% decline in bone volume due to increased remodeling space. Oscillations in bone volume and histologic surface parameters over time, similar in nature to those seen in studies of ovariectomized animals, were predicted by the simulation for the oscillatory activation response examined, underdamped second order. An oscillatory BMU activation response may explain some of the transient events during menopause. The increased coherence of BMUs created by such a response may increase the likelihood of trabecular perforations. the inherent nature of an oscillatory activation response may cause its detection to be overlooked and bone remodeling data to be misinterpreted.(ABSTRACT TRUNCATED AT 250 WORDS)

Strain profiles for circular cell culture plates containing flexible surfaces employed to mechanically deform cells in vitro.

Cells in the body are constantly subjected to cyclic mechanical deformation involving tension, compression, or shear strain or all three. A mechanical loading system which deforms cultured cells in vitro was analyzed in order to quantify the deformation or strain to which the cells are subjected. The dynamic system utilizes vacuum pressure to deform a circular silicone rubber substrate on which cells are cultured. These thick circular growth surfaces or plates are formed in the bottoms of the wells of 6-well culture plates. An axisymmetric model was formulated and analyzed using rectangular hyperelastic elements in a finite element analysis (FEA) software package. The thick circular plate has some disadvantages such as difficulty in observing cells and a nonhomogeneous strain profile which is maximum at the periphery and minimal at the center. A thinner circular surface (a thin plate) was also investigated in order to provide a more homogeneous strain profile. The radial strain on the thick circular plate, as determined by FEA, was nonlinear with a peak strain value of 0.30 (vacuum pressure of 22 kPa) about three-quarters of the distance from the center to the edge. In contrast, the radial strain of the thin circular plate was moderately constant across the surface. The circumferential strain for both of these models was less than the radial strain except for the center where they are equal. Avian tendon cells were cultured on the surface of a thick plate and exposed to cyclic strains for 24 h at a rate of 0.17 Hz and observed for cellular alignment.(ABSTRACT TRUNCATED AT 250 WORDS)