Sabhya Rana scite author profile

The present study shows that unilateral contusion injury at C4 results in substantial loss of phrenic motoneurons but increased diaphragm muscle activity across a range of ventilatory and higher force, nonventilatory behaviors. Measures of neural drive indicate increased descending input to phrenic motoneurons that was more pronounced during higher force, nonventilatory behaviors. These findings reveal novel, complex adaptations in neuromotor control following injury, suggestive of increased recruitment of more fatigable, high-threshold motor units.

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Diaphragm muscle function following midcervical contusion injury in rats

Khurram

Fogarty

Rana

et al. 2019

Journal of Applied Physiology

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Mid‐cervical spinal cord contusion injury results in tissue damage, disruption of spinal pathways, and motoneuron loss. Phrenic motoneurons located in C3–5 segments of the cervical spinal cord innervate the diaphragm muscle (DIAm), and unilateral C4 contusion results in loss of 40–50% of motoneurons ipsilateral to the injury (~25% of the total motoneuron pool). Over time after unilateral C4 spinal cord contusion injury, DIAm electromyography (EMG) increases both contralateral and ipsilateral to the side of injury, suggesting compensation due to an increased activation of the surviving motoneurons. However, whether C4 contusion impairs the ability of the DIAm to accomplish higher force motor behaviors is unknown. Transdiaphragmatic pressure (Pdi) was measured across motor behaviors over time after unilateral C4 contusion injury. Maximum Pdi (Pdimax) was elicited by bilateral phrenic nerve stimulation at 7 days post‐injury. We hypothesized that Pdimax is reduced following C4 mid‐cervical contusion injury, which will constrain the Pdi generated during different motor behaviors. Since ventilatory behaviors of the DIAm require <50% Pdimax, we further hypothesized that Pdi generated during ventilatory behaviors of the DIAm is not impaired after unilateral C4 mid‐cervical spinal cord contusion injury. In support of our hypothesis, we observed that Pdimax was reduced by ~25% after C4 mid‐cervical spinal cord contusion injury compared to a laminectomy control group. This decrease in Pdimax is consistent with the extent of phrenic motoneuron loss following contusion injury. We also found that during both eupnea (quiet breathing) and breathing stimulated by 10% O2 (hypoxia) and 5% CO2 (hypercapnia), Pdi generation was unimpaired by C4 mid‐cervical spinal cord contusion injury, again consistent with the lower force requirement of these ventilatory motor behaviors. Prior to injury, Pdi generated during airway occlusion was ~40% of Pdimax. One day following contusion injury, the Pdi amplitude during airway occlusion was reduced from ~30 cm H2O to ~20 cm, but this reduction was completely reversed by 7 days post‐injury. The reduction in Pdi amplitude at one day post‐injury cannot be attributed to the ~25% loss of phrenic motoneurons, and thus, may reflect a disruption of input to phrenic motoneurons or acute inflammation of their surrounding milieu. Over time after injury, changes in the balance between inhibition and excitation may result in recovery of higher‐force behaviors. Support or Funding Information Funded by NIH R01‐HL096750 and T32‐HL105355 This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

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Glutamatergic input varies with phrenic motor neuron size

Rana

Mantilla

Sieck

2019

Journal of Neurophysiology

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Like all skeletal muscles, the diaphragm muscle accomplishes a range of motor behaviors by recruiting different motor unit types in an orderly fashion. Recruitment of phrenic motor neurons (PhMNs) is generally assumed to be based primarily on the intrinsic properties of PhMNs with an equal distribution of descending excitatory inputs to all PhMNs. However, differences in presynaptic excitatory input across PhMNs of varying sizes could also contribute to the orderly recruitment pattern. In the spinal cord of Sprague-Dawley rats, we retrogradely labeled PhMNs using cholera toxin B (CTB) and validated a robust confocal imaging-based technique that utilizes semiautomated processing to identify presynaptic glutamatergic (Glu) terminals within a defined distance around the somal membrane of PhMNs of varying size. Our results revealed an ~10% higher density of Glu terminals at PhMNs in the lower tertile of somal surface area. These smaller PhMNs are likely recruited first to accomplish lower force ventilatory behaviors of the diaphragm as compared with larger PhMNs in the upper tertile that are recruited to accomplish higher force expulsive behaviors. These results suggest that differences in excitatory synaptic input to PhMNs may also contribute to the orderly recruitment of diaphragm motor units. NEW & NOTEWORTHY The distribution of excitatory glutamatergic synaptic input to phrenic motor neurons differs across motor neurons of varying size. These findings support the size principle of motor unit recruitment that underlies graded force generation in a muscle, which is based on intrinsic electrophysiological properties of motor neurons resulting from differences in somal surface area. A higher density of glutamatergic inputs at smaller, more excitable motor neurons substantiates the earlier and more frequent recruitment of these units.

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Spiny mouse (Acomys): an emerging research organism for regenerative medicine with applications beyond the skin

et al. 2021

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The spiny mouse (Acomys species) has emerged as an exciting research organism due to its remarkable ability to undergo scarless regeneration of skin wounds and ear punches. Excitingly, Acomys species demonstrate scar-free healing in a wide-range of tissues beyond the skin. In this perspective article, we discuss published findings from a variety of tissues to highlight how this emerging research organism could shed light on numerous clinically relevant human diseases. We also discuss the challenges of working with this emerging research organism and suggest strategies for future Acomys-inspired research.

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Quantifying mitochondrial volume density in phrenic motor neurons

Fogarty

Rana

Mantilla

et al. 2021

Journal of Neuroscience Methods

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Sabhya Rana

Diaphragm electromyographic activity following unilateral midcervical contusion injury in rats

Diaphragm muscle function following midcervical contusion injury in rats

Glutamatergic input varies with phrenic motor neuron size

Spiny mouse (Acomys): an emerging research organism for regenerative medicine with applications beyond the skin

Quantifying mitochondrial volume density in phrenic motor neurons

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