Predicting the Bending of 3D Printed Hyperelastic Polymer Components.

The advancement of 3D printing has led to its widespread use. NinjaFlex®, a thermoplastic polyurethane (TPU) filament, is a highly durable and flexible material that has been used to create flexible parts. While this material has been available for nearly two decades, the mechanical properties of 3D printed NinjaFlex® parts are not well-understood, especially in bending. The focus of this research was predicting the behavior of small 3D printed NinjaFlex® components. Three-dimensionally printed rectangular specimens of varying lengths and aspect ratios were loaded as cantilevers. The deflection of these specimens was measured using a computer. The experimental results were compared to a modified form of the Euler-Bernoulli Beam Theorem (MEB), which was developed to account for nonlinearities associated with large deflection. Additionally, experimental results were compared to the finite element analysis (FEA). The results showed that both modeling approaches were overall accurate, with the average difference between experimental deflection data and MEB predictions ranging from 0.6% to 3.0%, while the FEA predictions ranged from 0.4% to 2.4%. In the case of the most flexible specimens, MEB underestimated the experimental results, while FEA led to higher retraction.

Bone strength is maintained after 8 months of inactivity in hibernating golden-mantled ground squirrels, Spermophilus lateralis.

Prolonged inactivity leads to disuse atrophy, a loss of muscle and bone mass. Hibernating mammals are inactive for 6-9 months per year but must return to full activity immediately after completing hibernation. This necessity for immediate recovery presents an intriguing conundrum, as many mammals require two to three times the period of inactivity to recover full bone strength. Therefore, if hibernators experience typical levels of bone disuse atrophy during hibernation, there would be inadequate time available to recover during the summer active season. We examined whether there were mechanical consequences as a result of the extended inactivity of hibernation. We dissected femur and tibia bones from squirrels in various stages of the annual hibernation cycle and measured the amount of force required to fracture these bones. Three groups were investigated; summer active animals were captured during the summer and immediately killed, animals in the 1 month detraining group were captured in the summer and killed following a 1-month period of restricted mobility, hibernating animals were killed after 8 months of inactivity. A three-point bend test was employed to measure the force required to break the bones. Apparent flexural strength and apparent flexural modulus (material stiffness) were calculated for femurs. There were no differences between groups for femur fracture force, tibia fracture force, or femur flexural strength. Femur flexural modulus was significantly less for the 1 month detraining group than for the hibernation and summer active groups. Thus, hibernators seem resistant to the deleterious effects of prolonged inactivity during the winter. However, they may be susceptible to immobilization-induced bone loss during the summer.

Functional and dynamic response characteristics of a custom composite ankle foot orthosis for Charcot-Marie-Tooth patients.

BACKGROUND: Custom carbon-fiber composite ankle foot orthoses (AFOs) have been anecdotally reported to improve gait of Charcot-Marie-Tooth (CMT) patients. The purpose of the study was to characterize the spatio-temporal, joint kinetic and mechanical responses of a custom carbon fiber AFO during locomotion for persons diagnosed with CMT. METHODS: Eight volunteers were fitted with custom AFOs. Three of the devices were instrumented with eight strain gauges to measure surface deformation of the shell during dynamic function. Following a minimum 10 weeks accommodation period, plantar- and dorsiflexor strength was measured bilaterally. Volunteers then walked unbraced and braced, at their preferred pace over a force platform and instrumented walkway while being tracked with a 12-camera motion capture system. Strength, spatio-temporal and lower extremity joint kinetic parameters were evaluated between conditions (single subject) using the model statistic procedure. Mechanical loads were presented descriptively. RESULTS: All participants walked faster (89.4 ± 13.3 vs 115.6 ± 18.0 cm/s) in the braced condition with ankle strength negatively correlated to speed increase. As Δ velocity increased, maximum joint moments during loading response shifted from the hip joint to the ankle and knee joints. During propulsion, the hip joint moment dominated. Subjects exhibiting the greatest and least Δ velocity imposed an average load of 54.6% and 16.6% of body weight on the braces, respectively. Energy storage in the brace averaged 9.6 ± 6.6J/kg. CONCLUSION: Subject-specific effects of a custom AFO on gait for CMT patients were documented. The force-deflection properties of carbon-fiber composite braces may be important considerations in their design.