Doublet stimulation protocol to minimize musculoskeletal stress during paralyzed quadriceps muscle testing

Graduate Program in Physical Therapy and Rehabilitation Science, The University of Iowa, Iowa City, Iowa Submitted 20 August 2007 ; accepted in final form 18 April 2008 With long-term electrical stimulation training, paralyzed muscle can serve as an effective load delivery agent for the skeletal system. Muscle adaptations to training, however, will almost certainly outstrip bone adaptations, exposing participants in training protocols to an elevated risk for fracture. Assessing the physiological properties of the chronically paralyzed quadriceps may transmit unacceptably high shear forces to the osteoporotic distal femur. We devised a two-pulse doublet strategy to measure quadriceps physiological properties while minimizing the peak muscle force. The purposes of the study were 1 ) to determine the repeatability of the doublet stimulation protocol, and 2 ) to compare this protocol among individuals with and without spinal cord injury (SCI). Eight individuals with SCI and four individuals without SCI underwent testing. The doublet force-frequency relationship shifted to the left after SCI, likely reflecting enhancements in the twitch-to-tetanus ratio known to exist in paralyzed muscle. Posttetanic potentiation occurred to a greater degree in subjects with SCI (20%) than in non-SCI subjects (7%). Potentiation of contractile rate occurred in both subject groups (14% and 23% for SCI and non-SCI, respectively). Normalized contractile speed (rate of force rise, rate of force fall) reflected well-known adaptations of paralyzed muscle toward a fast fatigable muscle. The doublet stimulation strategy provided repeatable and sensitive measurements of muscle force and speed properties that revealed meaningful differences between subjects with and without SCI. Doublet stimulation may offer a unique way to test muscle physiological parameters of the quadriceps in subjects with uncertain musculoskeletal integrity. spinal cord injury; electrical muscle stimulation; potentiation; contractile speed Address for reprint requests and other correspondence: R. K. Shields, 1-252 Medical Education Bldg., Graduate Program in Physical Therapy and Rehabilitation Science, The Univ. of Iowa, Iowa City, IA 52242 (e-mail: richard-shields{at}uiowa.edu )