Advances in technology and improvement of efficacy for many neuromodulation applications have been achieved without understanding the relationship between the stimulation parameters and the neural activity which is generated in the nervous system. It is the neural activity that ultimately drives the therapeutic benefit and the advent of evoked compound action potential recording allows this activity to be directly measured and quantified. Closed-loop control adjusts the stimulation parameters to maintain a predetermined level of neural recruitment and has been shown to provide improved pain relief in individuals with spinal cord stimulators. However, no mechanism that relates more consistent neural recruitment to patient outcomes has been proposed. The authors propose a hypothesis that may explain the difference in efficacy between open- and closed-loop operational modes by considering the relationship between measured neural recruitment with hypothetical dose and side effect response curves. This provides a rational basis for directing clinical research and improving therapeutic systems.
Keywords: ECAP-controlled closed-loop systems; bioelectric potentials; biomedical electrodes; clinical research; closed loop systems; closed-loop control adjusts; closed-loop operational modes; evoked compound action potential recording; improved pain relief; improving therapeutic systems; measured neural recruitment; medical computing; nervous system; neural activity; neuromodulation applications; neuromuscular stimulation; neurophysiology; patient treatment; relates more consistent neural recruitment; spinal cord stimulation; spinal cord stimulators; stimulation parameters; therapeutic benefit.