Abstract
Cancer survivors rank sensorimotor disability among the most distressing, long-term consequences of chemotherapy. Disorders in gait, balance, and skilled movements are commonly assigned to chemotoxic damage of peripheral sensory neurons without consideration of the deterministic role played by the neural circuits that translate sensory information into movement. This oversight precludes sufficient, mechanistic understanding and contributes to the absence of effective treatment for reversing chemotherapy-induced disability. We rectified this omission through the use of a combination of electrophysiology, behavior, and modeling to study the operation of a spinal sensorimotor circuit invivo in a rat model of chronic, oxaliplatin (chemotherapy)-induced neuropathy (cOIN). Key sequential events were studied in the encoding of propriosensory information and its circuit translation into the synaptic potentials produced in motoneurons. In cOIN rats, multiple classes of propriosensory neurons expressed defective firing that reduced accurate sensory representation of muscle mechanical responses to stretch. Accuracy degraded further in the translation of propriosensory signals into synaptic potentials as a result of defective mechanisms residing inside the spinal cord. These sequential, peripheral, and central defects compounded to drive the sensorimotor circuit into a functional collapse that was consequential in predicting the significant errors in propriosensory-guided movement behaviors demonstrated here in our rat model and reported for people with cOIN. We conclude that sensorimotor disability induced by cancer treatment emerges from the joint expression of independent defects occurring in both peripheral and central elements of sensorimotor circuits.
Highlights
IntroductionSensory abnormalities, fatigue, and impaired mobility and cognition, collectively referred to as chemotherapy-induced neurotoxicity, diminishes quality of life and limits functional capacity in most patients [1,2,3,4]
N eurotoxic effects weigh against the benefits of chemotherapy in treating cancer
We recently reported that motoneurons, the output neuron common to all sensorimotor circuits, exhibit sporadic firing attributable to intrinsic changes in excitability observed in our rat model of chronic oxaliplatin-induced neuropathy [12]
Summary
Sensory abnormalities, fatigue, and impaired mobility and cognition, collectively referred to as chemotherapy-induced neurotoxicity, diminishes quality of life and limits functional capacity in most patients [1,2,3,4] These effects are expressed with platinum-based agents, including oxaliplatin, which are used in 50% of chemotherapy cases worldwide [5, 6]. Together with sensory, motor, and cognitive disorders, are chief among the constellation of side effects that occur with the platinum-based anticancer agents used in a majority of cancer treatments worldwide These disabilities remain clinically unmitigated and empirically unexplained as research concentrates on peripheral degeneration of sensory neurons while understating the possible involvement of neural processes within the central nervous system. S.P. is a guest editor invited by the Editorial Board
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