Effect of intermittent weight bearing on soleus fiber force-velocity-power and force-pCa relationships

Bangart, J. J., J. J. Widrick, and R. H. Fitts. Effectof intermittent weight bearing on soleus fiber force-velocity-power andforce-pCa relationships. J. Appl.Physiol. 82(6): 1905-1910, 1997.Ratpermeabilized type I soleus fibers displayed a 33% reduction in peakpower output and a 36% increase in the freeCa²⁺ concentration required forone-half maximal activation after 14 days of hindlimb non-weightbearing (NWB). We examined the effectiveness of intermittent weightbearing (IWB; consisting of four 10-min periods of weight bearing/day)as a countermeasure to these functional changes. At peak power output,type I fibers from NWB animals produced 54% less force and shortenedat a 56% greater velocity than did type I fibers from controlweight-bearing animals while type I fibers from the IWB rats produced26% more absolute force than did fibers from the NWB group andshortened at a velocity that was only 80% of the NWB group mean. As aresult, no difference was observed in the average peak power of fibers from the IWB and NWB animals. Hill plot analysis of force-pCa relationships indicated that fibers from the IWB group required similarlevels of free Ca²⁺ to reachhalf-maximal activation in comparison to fibers from the weight-bearinggroup. However, at forces <50% of peak force, the force-pCa curvefor fibers from the IWB animals clearly fell between the relationshipsobserved for the other two groups. In summary, IWB treatments1) attenuated the NWB-inducedreduction in fiber Ca²⁺sensitivity but 2) failed to preventthe decline in peak power that occurs during NWB because of opposingeffects on fiber force (an increase vs. NWB) and shortening velocity (adecrease vs. NWB).