Effect of optogenetic excitation of non-orexinergic neurons in the hypothalamic perifornical area on motor behaviors and cardiovascular parameters in rats.

Central command, a motor volition originating in the rostral part of the brain, plays a pivotal role in the precise regulation of autonomic nervous and cardiovascular systems. Central neuronal substrates responsible for transmitting central command signals remain incompletely understood. This study aimed to investigate the effect of optogenetic excitation of non-orexinergic (NOrx) neurons in the hypothalamic perifornical area (PeFA), where orexinergic neurons are densely distributed, on motor behaviors and cardiovascular parameters in rats.

Orexinergic neurons contribute to autonomic cardiovascular regulation for locomotor exercise.

While the hypothalamic orexinergic nervous system is established as having a pivotal role in the long-term regulation of various organismic functions, including wakefulness, metabolism and hypertensive states, whether this system contributes to the rapid autonomic cardiovascular regulation during physical activity remains elusive. This study aimed to elucidate the role of the orexinergic nervous system in transmitting volitional motor signals, i.e.

Hypothalamic Orexinergic Neurons Projecting to the Mesencephalic Locomotor Region Are Activated by Voluntary Wheel Running Exercise in Rats.

Background: Cardiovascular changes during exercise are regulated by a motor volitional signal, called central command, which originates in the rostral portions of the brain and simultaneously regulates somatomotor and autonomic nervous systems. Whereas we recently elucidated mesencephalic locomotor region (MLR) neurons projecting to the rostral ventrolateral medulla as a crucial component of the central circuit responsible for transmitting central command signals, upstream circuits that regulate the MLR neurons remain unknown. Orexinergic neurons, which primarily originate from the perifornical area (PeFA) of the hypothalamus and reportedly play roles in eliciting locomotion and elevating sympathetic activity, send axonal projection to the MLR.

A brainstem monosynaptic excitatory pathway that drives locomotor activities and sympathetic cardiovascular responses.

Exercise including locomotion requires appropriate autonomic cardiovascular adjustments to meet the metabolic demands of contracting muscles, yet the functional brain architecture underlying these adjustments remains unknown. Here, we demonstrate brainstem circuitry that plays an essential role in relaying volitional motor signals, i.e.

Accelerometer-Based Monitoring of Upper Limb Movement in Older Adults With Acute and Subacute Stroke.

Background And Purpose: Use of the affected extremity during daily life is important if disuse atrophy is to be prevented after stroke. This study examined whether objectively measured real-world upper limb movement is associated with the amount of use of the affected upper limb, as assessed by a standardized assessment tool in older adults with acute or subacute stroke. This study also examined whether the real-world upper limb movement is associated with the extent of impairment of upper and lower extremities.