Whole joint embedding in polymethylmethacrylate: a method for preparing intact musculoskeletal organ systems for histomorphology and 3-D reconstruction.

Large and medium size undecalcified joints were embedded in methylmethacrylate resin. Sections of 600 microns prepared from polymethylmethacrylate blocks show minimal distortion and are suitable for surface staining and three-dimensional reconstruction. The 5 microns sections prepared from these slabs retain good cytological detail. This method permits the examination of musculoskeletal organ systems at both macroscopic and microscopic levels.

Stress governs tissue phenotype at the femoral insertion of the rabbit MCL.

The cells in the midsubstance portion of skeletal ligaments typically have elongated shapes, but where ligaments insert into bone the cells appear very rounded and the tissue phenotype is that of fibrocartilage. Between the midsubstance and the insertions there is a gradient in cell shape and tissue phenotype that has been hypothesized to reflect a gradient of mechanical stresses. To test this hypothesis, cell shapes (an index of tissue phenotype) were quantified in the central part of the femoral insertion of the rabbit medial collateral ligament by computer-assisted histomorphometry. Morphometric measurements were correlated with the mechanical stresses and strains in the central part of the insertion as predicted by finite element analysis. Throughout the ligament the direction of the predicted principal tensile stresses coincides with the direction of the collagen fibers which curve from the midsubstance to meet the femur at nearly right angles. Principal compressive stresses also occur within the ligament: the highest are localized near the bone; the lowest in the midsubstance. The areas with the roundest cells correspond to the areas with the highest principal compressive stresses in the model; the areas with the flattest cells correspond to the areas with the lowest compressive stresses in the model. A correlation between cell shape and mechanical stresses suggests that physiological loading of the MCL is important for the maintenance of tissue phenotype throughout this insertion. We theorize that the cells in ligament insertions adapt to the prevailing local mechanical environment.

Moment-length relations of rectus femoris muscles of speed skaters/cyclists and runners.

The purpose of this study was to investigate the possible existence of systematic differences between moment-length properties of the rectus femoris muscle of cyclists/speed skaters and runners. In cycling/speed skating the rectus femoris is used at a shorter length than in running because of the pronounced flexion at the hip joint. It was speculated that using the rectus femoris chronically at different lengths would result in different moment-length relations for the two groups of athletes. Moment-length relations of rectus femoris muscles were determined using an adaptation of procedures outlined in the literature. Four subjects in each group performed 13 isometric knee extensions on a Cybex II dynamometer in each of three testing sessions. Knee and hip angles were varied in a systematic way to allow the determination of moment-length relations over a wide range of normal rectus femoris lengths. It was found that cyclists tended to be stronger at short compared with long rectus femoris lengths, whereas the opposite was true for runners. This finding may be associated with an adaptation of the rectus femoris muscle to the requirements of cycling and running or may show an inherited difference in the muscles of the athletes that existed before they became involved in their respective sports. The data of this study do not allow us to distinguish between these two possible factors.