Methods for reduced platen compression (RPC) test specimen cutting locations using micro-CT and planar radiographs

Lemmon, Heber

30 September 2004

This study looks at improving reduced platen compression (RPC) specimen preparation procedures by developing a better method for locating the ideal RPC specimen on each bone. These improvements are aimed at decreasing the amount of time required to complete an RPC analysis and improving the quality of the obtained results. High-resolution micro-CT scans are used to gain a better understanding of rat long bone anatomy by quantifying the location, shape, and orientation of the growth plate, primary spongiosa, and secondary spongiosa. Micro-CT analysis shows that there are easily identifiable external landmarks on the anterior side of both tibias and femurs that identify the end of the growth plate and the point at which the top of an ideal RPC specimen should be located. The landmarks are the most proximal tip of the patellar surface for the femur and the base of the tibial tuberosity for the tibia. This study also analyzes the effect of variations in the actual RPC specimen location from the ideal location and the effect of different platen sizes on test results using BMD as a surrogate for mechanical properties. The analysis shows that the BMD increases as the target RPC specimen location approaches the growth plate and decreases on moving away from the growth plate. The study also indicates that consistency is necessary when obtaining RPC specimens to avoid error due to variation from the specified landmark. Additionally, the BMD decreased as the diameter of the platen is reduced. Choosing platen size then becomes a trade off between testing the greatest amount of cancellous bone possible and potentially higher load sharing by the cortical shell with larger platen sizes as well as the risk of compressing cortical bone during the test.

reduced platen compression

BMD

micro-CT

cancellous bone

mechanical properties

rat

primary spongiosa

Characterization of the Bone Loss and Recovery Response at the Distal Femur Metaphysis of the Adult Male Hindlimb Unloaded Rat

Davis, Joshua Morgan

2011 December 1900

Extended periods of mechanical unloading are known to be detrimental to bone health. Astronauts who spend months in microgravity aboard the International Space Station (ISS) are at particular risk. It is anticipated that NASA will not drastically increase the size of the astronaut corps, and this will mean increased likelihood of repeat missions for more astronauts. Thus, it is important to better understand the effects that prolonged, multiple bouts of unloading have on bone. This study utilized the hindlimb unloaded (HU) rat model to examine bone loss and recovery for single and double unloading bouts. Adult male Sprague-Dawley rats (6 months old) were randomized into the following groups: baseline (sacrificed at 6 months), 1HU7 (unloaded for 1 month, weight-bearing recovery for 3 months), 2HU10 (unloaded for 1 month, recovered for 2 months, unloaded for another month, and then recovered 2 months), 1HU10 (normal cage activity until 1 month HU ending at month 10, 2 month recovery followed), and aging controls (remained ambulatory throughout experiment). Every month (28 days), animals were terminated and the left femurs were excised, resulting in n=15 per group for each time point. Mineral and geometric properties were measured using peripheral quantitative computed tomography (pQCT) at the distal femur metaphysis, and quasi-static reduced platen compression (RPC) was used to estimate the mechanical properties of cancellous bone. Strength indices based on pQCT parameters were calculated as predictors of mechanical properties. Bone mass properties decreased due to HU and recovered within 2-3 months post-HU. A combination of increased periosteal apposition and endocortical resorption also occurred during HU. The initial HU bout suppressed normal age-related increases in mechanical properties and recovered within 1-2 months. Cancellous compressive strength index (CSI) most closely matched changes in mechanical properties. A second HU bout after two months recovery had a less detrimental effect on pQCT parameters but a greater negative impact on mechanical properties, when compared to pre-HU values. The opposite is true for mechanical properties if loss is characterized relative to aging controls. Recovery after the second HU period did not appear to be significantly affected by a previous bout of HU.

Hindlimb unloading

distal femur

metaphysis

pQCT

bone

cancellous

trabecular

reduced platen compression

RPC

rat

loss

recovery