Your search keyword '"Fuller, David A."' showing total 23 results

1. Oxygen therapy attenuates neuroinflammation after spinal cord injury.

Author

Sunshine, Michael D., Bindi, Victoria E., Nguyen, Branden L., Doerr, Vivian, Boeno, Franccesco P., Chandran, Vijayendran, Smuder, Ashley J., and Fuller, David D.

Subjects

SPINAL cord injuries, GLIAL fibrillary acidic protein, OXYGEN therapy, NEUROINFLAMMATION

Abstract

Acute hyperbaric O2 (HBO) therapy after spinal cord injury (SCI) can reduce inflammation and increase neuronal survival. To our knowledge, it is unknown if these benefits of HBO require hyperbaric vs. normobaric hyperoxia. We used a C4 lateralized contusion SCI in adult male and female rats to test the hypothesis that the combination of hyperbaria and 100% O2 (i.e. HBO) more effectively mitigates spinal inflammation and neuronal loss, and enhances respiratory recovery, as compared to normobaric 100% O2. Experimental groups included spinal intact, SCI no O2 therapy, and SCI + 100% O2 delivered at normobaric pressure (1 atmosphere, ATA), or at 2- or 3 ATA. O2 treatments lasted 1-h, commenced within 2-h of SCI, and were repeated for 10 days. The spinal inflammatory response was assessed with transcriptomics (RNAseq) and immunohistochemistry. Gene co-expression network analysis showed that the strong inflammatory response to SCI was dramatically diminished by both hyper- and normobaric O2 therapy. Similarly, both HBO and normobaric O2 treatments reduced the prevalence of immunohistological markers for astrocytes (glial fibrillary acidic protein) and microglia (ionized calcium binding adaptor molecule) in the injured spinal cord. However, HBO treatment also had unique impacts not detected in the normobaric group including upregulation of an anti-inflammatory cytokine (interleukin-4) in the plasma, and larger inspiratory tidal volumes at 10-days (whole body-plethysmography measurements). We conclude that normobaric O2 treatment can reduce the spinal inflammatory response after SCI, but pressured O2 (i.e., HBO) provides further benefit. [ABSTRACT FROM AUTHOR]

Published

2023

2. Restoration of breathing after opioid overdose and spinal cord injury using temporal interference stimulation.

Author

Sunshine, Michael D., Cassarà, Antonino M., Neufeld, Esra, Grossman, Nir, Mareci, Thomas H., Otto, Kevin J., Boyden, Edward S., and Fuller, David D.

Subjects

SPINAL cord injuries, OPIOID abuse, RESPIRATORY insufficiency, NEUROMUSCULAR diseases, MINIMALLY invasive procedures

Abstract

Respiratory insufficiency is a leading cause of death due to drug overdose or neuromuscular disease. We hypothesized that a stimulation paradigm using temporal interference (TI) could restore breathing in such conditions. Following opioid overdose in rats, two high frequency (5000 Hz and 5001 Hz), low amplitude waveforms delivered via intramuscular wires in the neck immediately activated the diaphragm and restored ventilation in phase with waveform offset (1 Hz or 60 breaths/min). Following cervical spinal cord injury (SCI), TI stimulation via dorsally placed epidural electrodes uni- or bilaterally activated the diaphragm depending on current and electrode position. In silico modeling indicated that an interferential signal in the ventral spinal cord predicted the evoked response (left versus right diaphragm) and current-ratio-based steering. We conclude that TI stimulation can activate spinal motor neurons after SCI and prevent fatal apnea during drug overdose by restoring ventilation with minimally invasive electrodes. Sunshine et al use a combination of rat models and in silico modeling to show that temporal interference stimulation can prevent fatal apneas after opioid overdose, and can activate the diaphragm after spinal cord injury. This potentially paves the way for an alternative and minimally invasive treatment [ABSTRACT FROM AUTHOR]

Published

2021

3. Forelimb Muscle Plasticity Following Unilateral Cervical Spinal Cord Injury

Author

Gonzalez-Rothi, Elisa J., Armstrong, Gregory T., Cerreta, Anthony J., Fitzpatrick, Garrett M., Reier, Paul J., Lane, Michael A., Judge, Andrew R., and Fuller, David D.

Subjects

Analysis of Variance, Disease Models, Animal, Time Factors, Forelimb, Cervical Vertebrae, Animals, Female, Muscle, Skeletal, Article, Functional Laterality, Spinal Cord Injuries

Abstract

Motor dysfunction and muscle atrophy are well documented in the lower extremity after spinal cord injury. However, the extent and time course of myoplastic changes in forelimb musculature is not clear.Forelimb muscle morphology and fiber type were evaluated after high cervical hemilesion injury in rats.There was significant atrophy of the ipsilateral extensor carpi radialis longus (ECRL) muscle at 2 weeks postinjury, which was subsequently reversed at 8 weeks postinjury. The triceps muscle showed minimal evidence of atrophy after spinal injury. No significant changes in fiber type were observed.These findings indicate a robust capacity for spontaneous myoplasticity after C2 hemisection injury but highlight differential capacity for plasticity within the forelimb muscles.

Published

2016

4. Respiratory neuroplasticity – Overview, significance and future directions.

Author

Fuller, David D. and Mitchell, Gordon S.

Subjects

*NEUROPLASTICITY, *RESPIRATION, *RESPIRATORY organs, *HYPOXEMIA, *SPINAL cord injuries

Abstract

Neuroplasticity is an important property of the neural system controlling breathing. However, our appreciation for its importance is still relatively new, and we have much to learn concerning different forms of plasticity, their underlying mechanisms, and their biological and clinical significance. In this brief review, we discuss several well-studied models of respiratory plasticity, including plasticity initiated by inactivity in the respiratory system, intermittent and sustained hypoxia, and traumatic injury to the spinal cord. Other aspects of respiratory plasticity are considered in other contributions to this special edition of Experimental Neurology on respiratory plasticity. Finally, we conclude with discussions concerning the biological and clinical significance of respiratory motor plasticity, and areas in need of future research effort. [ABSTRACT FROM AUTHOR]

Published

2017

5. Cervical spinal cord injury exacerbates ventilator-induced diaphragm dysfunction.

Author

Smuder, Ashley J., Gonzalez-Rothi, Elisa J., Kwon, Oh Sung, Morton, Aaron B., Sollanek, Kurt J., Powers, Scott K., and Fuller, David D.

Subjects

ARTIFICIAL respiration, SPINAL cord injuries, DIAPHRAGM diseases, RESPIRATORY therapy complications, PROTEOLYSIS, THERAPEUTIC use of antioxidants, LABORATORY rats

Abstract

Cervical spinal cord injury (SCI) can dramatically impair diaphragm muscle function and often necessitates mechanical ventilation (MV) to maintain adequate pulmonary gas exchange. MV is a life-saving intervention. However, prolonged MV results in atrophy and impaired function of the diaphragm. Since cervical SCI can also trigger diaphragm atrophy, it may create preconditions that exacerbate ventilator-induced diaphragm dysfunction (VIDD). Currently, no drug therapy or clinical standard of care exists to prevent or minimize diaphragm dysfunction following SCI. Therefore, we first tested the hypothesis that initiating MV acutely after cervical SCI will exacerbate VIDD and enhance proteolytic activation in the diaphragm to a greater extent than either condition alone. Rats underwent controlled MV for 12 h following acute (~24 h) cervical spinal hemisection injury at C2 (SCI). Diaphragm tissue was then harvested for comprehensive functional and molecular analyses. Second, we determined if antioxidant therapy could mitigate MV-induced diaphragm dysfunction after cervical SCI. In these experiments, SCI rats received antioxidant (Trolox, a vitamin E analog) or saline treatment prior to initiating MV. Our results demonstrate that compared with either condition alone, the combination of SCI and MV resulted in increased diaphragm atrophy, contractile dysfunction, and expression of atrophy-related genes, including MuRF1. Importantly, administration of the antioxidant Trolox attenuated proteolytic activation, fiber atrophy, and contractile dysfunction in the diaphragms of SCI + MV animals. These findings provide evidence that cervical SCI greatly exacerbates VIDD, but antioxidant therapy with Trolox can preserve diaphragm contractile function following acute SCI. [ABSTRACT FROM AUTHOR]

Published

2016

6. The impact of spinal cord injury on breathing during sleep.

Author

Fuller, David D., Lee, Kun-Ze, and Tester, Nicole J.

Subjects

*SPINAL cord injuries, *RESPIRATION, *SLEEP disorders treatment, *SLEEP apnea syndromes, *NEUROPLASTICITY, *NEUROSCIENCES

Abstract

Highlights: [•] Following spinal cord injury (SCI), the incidence of sleep disordered breathing (SDB) is considerably greater than occurs in the general population. [•] Both central and obstructive sleep apnea (OSA) has been reported after SCI, but OSA appears to be much more common. [•] It is not yet possible to pinpoint a “primary factor” which will predispose an individual with SCI to SDB. [•] Following SCI, changes in body mass, lung volume, autonomic function, and sleep position all may be related to increased SDB. [•] The role of respiratory neuroplasticity in SDB following SCI should be an area of further study. [ABSTRACT FROM AUTHOR]

Published

2013

7. Influence of vagal afferents on supraspinal and spinal respiratory activity following cervical spinal cord injury in rats.

Author

Kun-Ze Lee, Sandhu, Milapjit S., Dougherty, Brendan J., Reier, Paul J., and Fuller, David D.

Subjects

SPINAL cord injuries, RESPIRATION, VAGOTOMY, PHRENIC nerve, HYPOGLOSSAL nerve, LABORATORY rats

Abstract

C2 spinal hemisection (C2HS) interrupts ipsilateral bulbospinal pathways and induces compensatory increases in contralateral spinal and possibly supraspinal respiratory output. Our first purpose was to test the hypothesis that after C2HS contralateral respiratory motor outputs become resistant to vagal inhibitory inputs associated with lung inflation. Bilateral phrenic and contralateral hypoglossal (XII) neurograms were recorded in anesthetized and ventilated rats. In uninjured (control) rats, lung inflation induced by positive end-expired pressure (PEEP; 3-9 cmH2O) robustly inhibited both phrenic and XII bursting. At 2 wk post-C2HS, PEEP evoked a complex response associated with phrenic bursts of both reduced and augmented amplitude, but with no overall change in the mean burst amplitude. PEEP-induced inhibition of XII bursting was still present but was attenuated relative to controls. However, by 8 wk post-C2HS PEEP-induced inhibition of both phrenic and XII output were similar to that in controls. Our second purpose was to test the hypothesis that vagal afferents inhibit ipsilateral phrenic bursting, thereby limiting the incidence of the spontaneous crossed phrenic phenomenon in vagal-intact rats. Bilateral vagotomy greatly enhanced ipsilateral phrenic bursting, which was either weak or absent in vagal-intact rats at both 2 and 8 wk post-C2HS. We conclude that 1) compensatory increases in contralateral phrenic and XII output after C2HS blunt the inhibitory influence of vagal afferents during lung inflation and 2) vagal afferents robustly inhibit ipsilateral phrenic bursting. These vagotomy data appear to explain the variability in the literature regarding the onset of the spontaneous crossed phrenic phenomenon in spontaneously breathing (vagal intact) vs. ventilated (vagotomized) preparations. [ABSTRACT FROM AUTHOR]

Published

2010

8. Respiratory neuroplasticity and cervical spinal cord injury: translational perspectives

Author

Lane, Michael A., Fuller, David D., White, Todd E., and Reier, Paul J.

Subjects

*NEUROPLASTICITY, *SPINAL cord injuries, *RESPIRATORY organs, *DIAPHRAGM (Anatomy), *CENTRAL nervous system, *PARALYSIS

Abstract

Paralysis of the diaphragm is a severe consequence of cervical spinal cord injury. This condition can be experimentally modeled by lateralized, high cervical lesions that interrupt descending inspiratory drive to the corresponding phrenic nucleus. Although partial recovery of ipsilateral diaphragm function occurs over time, recent findings show persisting chronic deficits in ventilation and phrenic motoneuron activity. Some evidence suggests, however, that spontaneous recovery can be enhanced by modulating neural pathways to phrenic motoneurons via synaptic circuitries which appear more complex than previously envisioned. The present review highlights these and other recent experimental multidisciplinary findings pertaining to respiratory neuroplasticity in the rat. Translational considerations are also emphasized, with specific attention directed at the clinical and interpretational strengths of different lesion models and outcome measures. [Copyright &y& Elsevier]

Published

2008

9. Synaptic Pathways to Phrenic Motoneurons Are Enhanced by Chronic Intermittent Hypoxia after Cervical Spinal Cord Injury.

Author

Fuller, David D., Johnson, Stephen M., Olson Jr., E. Burdette, and Mitchell, Gordon S.

Subjects

*MOTOR neurons, *NEURONS, *BRAIN, *SPINAL cord injuries, *HYPOXEMIA, *PHYSIOLOGICAL effects of oxygen, *ASPHYXIA

Abstract

Provides information on a study that hypothesized that synaptic pathways to phrenic motoneurons are enhanced by chronic intermittent hypoxia after cervical spinal cord injury. Methodology of the study; Results and discussion on the study.

Published

2003

10. Respiratory Motor Recovery after Unilateral Spinal Cord Injury: Eliminating Crossed Phrenic Activity Decreases Tidal Volume and Increases Contralateral Respiratory Motor Output.

Author

Golder, Francis J., Fuller, David D., Davenport, Paul W., Johnson, Richard D., Reier, Paul J., and Bolser, Donald C.

Subjects

*SPINAL cord injuries, *RESPIRATION, *VAGUS nerve surgery, *ABDOMINAL compression reaction, *CENTRAL nervous system

Abstract

Presents a study that observed respiratory motor recovery after unilateral spinal cord injury using mouse models. Materials and methods; Schematic diagram depicting the location of each injury and recording sites; Breathing of rates with bilateral vagotomy.

Published

2003

11. Hyperbaric Oxygen Treatment Following Mid-Cervical Spinal Cord Injury Preserves Diaphragm Muscle Function.

Author

Smuder, Ashley J., Turner, Sara M., Schuster, Cassandra M., Morton, Aaron B., Hinkley, J. Matthew, and Fuller, David D.

Subjects

REACTIVE oxygen species, SPINAL cord injuries, RESPIRATORY muscles, CERVICAL cord, EXPOSURE therapy, OXYGEN, OXIDANT status, CONTRACTILITY (Biology)

Abstract

Oxidative damage to the diaphragm as a result of cervical spinal cord injury (SCI) promotes muscle atrophy and weakness. Respiratory insufficiency is the leading cause of morbidity and mortality in cervical spinal cord injury (SCI) patients, emphasizing the need for strategies to maintain diaphragm function. Hyperbaric oxygen (HBO) increases the amount of oxygen dissolved into the blood, elevating the delivery of oxygen to skeletal muscle and reactive oxygen species (ROS) generation. It is proposed that enhanced ROS production due to HBO treatment stimulates adaptations to diaphragm oxidative capacity, resulting in overall reductions in oxidative stress and inflammation. Therefore, we tested the hypothesis that exposure to HBO therapy acutely following SCI would reduce oxidative damage to the diaphragm muscle, preserving muscle fiber size and contractility. Our results demonstrated that lateral contusion injury at C3/4 results in a significant reduction in diaphragm muscle-specific force production and fiber cross-sectional area, which was associated with augmented mitochondrial hydrogen peroxide emission and a reduced mitochondrial respiratory control ratio. In contrast, rats that underwent SCI followed by HBO exposure consisting of 1 h of 100% oxygen at 3 atmospheres absolute (ATA) delivered for 10 consecutive days demonstrated an improvement in diaphragm-specific force production, and an attenuation of fiber atrophy, mitochondrial dysfunction and ROS production. These beneficial adaptations in the diaphragm were related to HBO-induced increases in antioxidant capacity and a reduction in atrogene expression. These findings suggest that HBO therapy may be an effective adjunctive therapy to promote respiratory health following cervical SCI. [ABSTRACT FROM AUTHOR]

Published

2020

12. AMPA receptors play an important role in the biological consequences of spinal cord injury: Implications for AMPA receptor modulators for therapeutic benefit.

Author

Witkin, Jeffrey M., Radin, Daniel P., Rana, Sabhya, Fuller, David D., Fusco, Anna F., Demers, Julie C., Pradeep Thakre, Prajwal, Smith, Jodi L., Lippa, Arnold, and Cerne, Rok

Subjects

*AMPA receptors, *CENTRAL nervous system, *SPINAL cord injuries, *NEURAL circuitry, *PERAMPANEL

Abstract

[Display omitted] Spinal cord injury (SCI) afflicts millions of individuals globally. There are few therapies available to patients. Ascending and descending excitatory glutamatergic neural circuits in the central nervous system are disrupted by SCI, making α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors (AMPARs) a potential therapeutic drug target. Emerging research in preclinical models highlights the involvement of AMPARs in vital processes following SCI including breathing, pain, inflammation, bladder control, and motor function. However, there are no clinical trial data reported in this patient population to date. No work on the role of AMPA receptors in sexual dysfunction after SCI has been disclosed. Compounds with selective antagonist and potentiating effects on AMPA receptors have benefit in animal models of SCI, with antagonists generally showing protective effects early after injury and potentiators (ampakines) producing improved breathing and bladder function. The role of AMPARs in pathophysiology and recovery after SCI depends upon the time post injury, and the timing of AMPAR augmentation or antagonism. The roles of inflammation, synaptic plasticity, sensitization, neurotrophic factors, and neuroprotection are considered in this context. The data summarized and discussed in this paper document proof of principle and strongly encourage additional studies on AMPARs as novel gateways to therapeutic benefit for patients suffering from SCI. The availability of both AMPAR antagonists such as perampanel and AMPAR allosteric modulators (i.e., ampakines) such as CX1739, that have been safely administered to humans, provides an expedited means of clinical inquiry for possible therapeutic advances. [ABSTRACT FROM AUTHOR]

Published

2024

13. Hyperbaric Oxygen Therapy after Mid-Cervical Spinal Contusion Injury.

Author

Turner, Sara M.F., Sunshine, Michael D., Chandran, Vijayendran, Smuder, Ashley J., and Fuller, David D.

Subjects

*HYPERBARIC oxygenation, *NF-kappa B, *SPINAL injuries, *SPINAL cord injuries, *SPINAL cord, *DECOMPRESSION sickness

Abstract

Hyperbaric oxygen (HBO) therapy is frequently used to treat peripheral wounds or decompression sickness. Evidence suggests that HBO therapy can provide neuroprotection and has an anti-inflammatory impact after neurological injury, including spinal cord injury (SCI). Our primary purpose was to conduct a genome-wide screening of mRNA expression changes in the injured spinal cord after HBO therapy. An mRNA gene array was used to evaluate samples taken from the contused region of the spinal cord following a lateralized mid-cervical contusion injury in adult female rats. HBO therapy consisted of daily, 1-h sessions (3.0 ATA, 100% O2) initiated on the day of SCI and continued for 10 days. Gene set enrichment analyses indicated that HBO upregulated genes in pathways associated with electron transport, mitochondrial function, and oxidative phosphorylation, and downregulated genes in pathways associated with inflammation (including cytokines and nuclear factor kappa B [NF-κB]) and apoptotic signaling. In a separate cohort, spinal cord histology was performed to verify whether the HBO treatment impacted neuronal cell counts or inflammatory markers. Compared with untreated rats, there were increased NeuN positive cells in the spinal cord of HBO-treated rats (p = 0.004). We conclude that HBO therapy, initiated shortly after SCI and continued for 10 days, can alter the molecular signature of the lesioned spinal cord in a manner consistent with a neuroprotective impact. [ABSTRACT FROM AUTHOR]

Published

2022

14. Spinal circuitry and respiratory recovery following spinal cord injury

Author

Lane, Michael A., Lee, Kun-Ze, Fuller, David D., and Reier, Paul J.

Subjects

*NEURAL circuitry, *SPINAL cord injuries, *NEUROPLASTICITY, *LABORATORY rats, *INTERNEURONS, *PHRENIC nerve, *RESPIRATION, *NEUROANATOMY

Abstract

Abstract: Numerous studies have demonstrated anatomical and functional neuroplasticity following spinal cord injury. One of the more notable examples is return of ipsilateral phrenic motoneuron and diaphragm activity which can be induced under terminal neurophysiological conditions after high cervical hemisection in the rat. More recently it has been shown that a protracted, spontaneous recovery also occurs in this model. While a candidate neural substrate has been identified for the former, the neuroanatomical basis underlying spontaneous recovery has not been explored. Demonstrations of spinal respiratory interneurons in other species suggest such cells may play a role; however, the presence of interneurons in the adult rat phrenic circuit – the primary animal model of respiratory plasticity – has not been extensively investigated. Emerging neuroanatomical and electrophysiological results raise the possibility of a more complex neural network underlying spontaneous recovery of phrenic function and compensatory respiratory neuroplasticity after C2 hemisection than has been previously considered. [Copyright &y& Elsevier]

Published

2009

15. Ampakines Stimulate Diaphragm Activity after Spinal Cord Injury.

Author

Rana, Sabhya, Sunshine, Michael D., Greer, John J., and Fuller, David D.

Subjects

*DIAPHRAGM (Anatomy), *SPINAL cord injuries, *CERVICAL cord, *RATS, *GAS mixtures

Abstract

Respiratory compromise after cervical spinal cord injury (SCI) is a leading cause of mortality and morbidity. Most SCIs are incomplete, and spinal respiratory motoneurons as well as proprio- and bulbospinal synaptic pathways provide a neurological substrate to enhance respiratory output. Ampakines are allosteric modulators of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors, which are prevalent on respiratory neurons. We hypothesized that low dose ampakine treatment could safely and effectively increase diaphragm electromyography (EMG) activity that has been impaired as a result of acute- or sub-acute cervical SCI. Diaphragm EMG was recorded using chronic indwelling electrodes in unanesthetized, freely moving rats. A spinal hemi-lesion was induced at C2 (C2Hx), and rats were studied at 4 and 14 days post-injury during room air breathing and acute respiratory challenge accomplished by inspiring a 10% O2, 7% CO2 gas mixture. Once a stable baseline recording was established, one of two different ampakines (CX717 or CX1739, 5 mg/kg, intravenous) or a vehicle (2-hydroxypropyl-beta-cyclodextrin [HPCD]) was delivered. At 4 days post-injury, both ampakines increased diaphragm EMG output ipsilateral to C2Hx during both baseline breathing and acute respiratory challenge. Only CX1739 treatment also led to a sustained (15 min) increase in ipsilateral EMG output. At 14 days post-injury, both ampakines produced sustained increases in ipsilateral diaphragm EMG output and enabled increased output during the respiratory challenge. We conclude that low dose ampakine treatment can increase diaphragm EMG activity after cervical SCI, and therefore may provide a pharmacological strategy that could be useful in the context of respiratory rehabilitation. [ABSTRACT FROM AUTHOR]

Published

2021

16. Spinal Interneurons and Forelimb Plasticity after Incomplete Cervical Spinal Cord Injury in Adult Rats.

Author

Gonzalez-Rothi, Elisa Janine, Rombola, Angela M., Rousseau, Celeste A., Mercier, Lynne M., Fitzpatrick, Garrett M., Reier, Paul J., Fuller, David D., and Lane, Michael A.

Subjects

*SPINAL cord injuries, *FORELIMB, *NEUROPLASTICITY, *MOTOR neurons, *INTERNEURONS, *LABORATORY rats, *PHYSIOLOGY

Abstract

Cervical spinal cord injury (cSCI) disrupts bulbospinal projections to motoneurons controlling the upper limbs, resulting in significant functional impairments. Ongoing clinical and experimental research has revealed several lines of evidence for functional neuroplasticity and recovery of upper extremity function after SCI. The underlying neural substrates, however, have not been thoroughly characterized. The goals of the present study were to map the intraspinal motor circuitry associated with a defined upper extremity muscle, and evaluate chronic changes in the distribution of this circuit following incomplete cSCI. Injured animals received a high cervical (C2) lateral hemisection (Hx), which compromises supraspinal input to ipsilateral spinal motoneurons controlling the upper extremities (forelimb) in the adult rat. A battery of behavioral tests was used to characterize the time course and extent of forelimb motor recovery over a 16 week period post-injury. A retrograde transneuronal tracer - pseudorabies virus - was used to define the motor and pre-motor circuitry controlling the extensor carpi radialis longus (ECRL) muscle in spinal intact and injured animals. In the spinal intact rat, labeling was observed unilaterally within the ECRL motoneuron pool and within spinal interneurons bilaterally distributed within the dorsal horn and intermediate gray matter. No changes in labeling were observed 16 weeks post-injury, despite a moderate degree of recovery of forelimb motor function. These results suggest that recovery of the forelimb function assessed following C2Hx injury does not involve recruitment of new interneurons into the ipsilateral ECRL motor pathway. However, the functional significance of these existing interneurons to motor recovery requires further exploration. [ABSTRACT FROM AUTHOR]

Published

2015

17. Hypoxia triggers short term potentiation of phrenic motoneuron discharge after chronic cervical spinal cord injury.

Author

Lee, Kun-Ze, Sandhu, Milapjit S., Dougherty, Brendan J., Reier, Paul J., and Fuller, David D.

Subjects

*CEREBRAL anoxia, *PHRENIC nerve, *SPINAL cord injuries, *NEUROPLASTICITY, *MOTOR neurons, *MEDICAL rehabilitation, *PHYSIOLOGY

Abstract

Repeated exposure to hypoxia can induce spinal neuroplasticity as well as respiratory and somatic motor recovery after spinal cord injury (SCI). The purpose of the present study was twofold: to define the capacity for a single bout of hypoxia to trigger short-term plasticity in phrenic output after cervical SCI and to determine the phrenic motoneuron (PhrMN) bursting and recruitment patterns underlying the response. Hypoxia-induced short term potentiation (STP) of phrenic motor output was quantified in anesthetized rats 11 weeks following lateral spinal cord hemisection at C2 (C2Hx). A 3-min hypoxic episode (12–14% O 2 ) always triggered STP of inspiratory burst amplitude, the magnitude of which was greater in phrenic bursting ipsilateral vs. contralateral to C2Hx. We next determined if STP could be evoked in recruited (silent) PhrMNs ipsilateral to C2Hx. Individual PhrMN action potentials were recorded during and following hypoxia using a “single fiber” approach. STP of bursting activity did not occur in cells initiating bursting at inspiratory onset, but was robust in recruited PhrMNs as well as previously active cells initiating bursting later in the inspiratory effort. We conclude that following chronic C2Hx, a single bout of hypoxia triggers recruitment of PhrMNs in the ipsilateral spinal cord with bursting that persists beyond the hypoxic exposure. The results provide further support for the use of short bouts of hypoxia as a neurorehabilitative training modality following SCI. [ABSTRACT FROM AUTHOR]

Published

2015

18. Phrenic motoneuron discharge patterns following chronic cervical spinal cord injury.

Author

Lee, Kun-Ze, Dougherty, Brendan J., Sandhu, Milapjit S., Lane, Michael A., Reier, Paul J., and Fuller, David D.

Subjects

*MOTOR neurons, *SPINAL cord injuries, *BRAIN stem, *APNEA, *LABORATORY rats, *ACTION potentials

Abstract

Abstract: Cervical spinal cord injury (SCI) dramatically disrupts synaptic inputs and triggers biochemical, as well as morphological, plasticity in relation to the phrenic motor neuron (PhMN) pool. Accordingly, our primary purpose was to determine if chronic SCI induces fundamental changes in the recruitment profile and discharge patterns of PhMNs. Individual PhMN action potentials were recorded from the phrenic nerve ipsilateral to lateral cervical (C2) hemisection injury (C2Hx) in anesthetized adult male rats at 2, 4 or 8wks post-injury and in uninjured controls. PhMNs were phenotypically classified as early (Early-I) or late inspiratory (Late-I), or silent according to discharge patterns. Following C2Hx, the distribution of PhMNs was dominated by Late-I and silent cells. Late-I burst parameters (e.g., spikes per breath, burst frequency and duration) were initially reduced but returned towards control values by 8wks post-injury. In addition, a unique PhMN burst pattern emerged after C2Hx in which Early-I cells burst tonically during hypocapnic inspiratory apnea. We also quantified the impact of gradual reductions in end-tidal CO2 partial pressure (PETCO2) on bilateral phrenic nerve activity. Compared to control rats, as PETCO2 declined, the C2Hx animals had greater inspiratory frequencies (breaths∗min−1) and more substantial decreases in ipsilateral phrenic burst amplitude. We conclude that the primary physiological impact of C2Hx on ipsilateral PhMN burst patterns is a persistent delay in burst onset, transient reductions in burst frequency, and the emergence of tonic burst patterns. The inspiratory frequency data suggest that plasticity in brainstem networks is likely to play an important role in phrenic motor output after cervical SCI. [Copyright &y& Elsevier]

Published

2013

19. Respiratory function following bilateral mid-cervical contusion injury in the adult rat

Author

Lane, Michael A., Lee, Kun-Ze, Salazar, Krystal, O'Steen, Barbara E., Bloom, David C., Fuller, David D., and Reier, Paul J.

Subjects

*SPINAL cord injuries, *RESPIRATION, *LABORATORY rats, *BRAIN diseases, *LUMBOSACRAL region, *BRAIN damage

Abstract

Abstract: The consequences of spinal cord injury (SCI) are often viewed as the result of white matter damage. However, injuries occurring at any spinal level, especially in cervical and lumbar enlargement regions, also entail segmental neuronal loss. Yet, the contributions of gray matter injury and plasticity to functional outcomes are poorly understood. The present study addressed this issue by investigating changes in respiratory function following bilateral C3/C4 contusion injuries at the level of the phrenic motoneuron (PhMN) pool which in the adult rat extends from C3 to C5/6 and provides innervation to the diaphragm. Despite extensive white and gray matter pathology associated with two magnitudes of injury severity, ventilation was relatively unaffected during both quiet breathing and respiratory challenge (hypercapnia). On the other hand, bilateral diaphragm EMG recordings revealed that the ability to increase diaphragm activity during respiratory challenge was substantially, and chronically, impaired. This deficit has not been seen following predominantly white matter lesions at higher cervical levels. Thus, the impact of gray matter damage relative to PhMNs and/or interneurons becomes evident during conditions associated with increased respiratory drive. Unaltered ventilatory behavior, despite significant deficits in diaphragm function, suggests compensatory neuroplasticity involving recruitment of other spinal respiratory networks which may entail remodeling of connections. Transynaptic tracing, using pseudorabies virus (PRV), revealed changes in PhMN-related interneuronal labeling rostral to the site of injury, thus offering insight into the potential anatomical reorganization and spinal plasticity following cervical contusion. [Copyright &y& Elsevier]

Published

2012

20. Neuronal progenitor transplantation and respiratory outcomes following upper cervical spinal cord injury in adult rats

Author

White, Todd E., Lane, Michael A., Sandhu, Milapjit S., O'Steen, Barbara E., Fuller, David D., and Reier, Paul J.

Subjects

*BRAIN transplantation, *CERVICAL vertebrae injuries, *SPINAL cord injuries, *HEALTH outcome assessment, *LABORATORY rats, *BRAIN physiology, *NEURAL circuitry

Abstract

Abstract: Despite extensive gray matter loss following spinal cord injury (SCI), little attention has been given to neuronal replacement strategies and their effects on specific functional circuits in the injured spinal cord. In the present study, we assessed breathing behavior and phrenic nerve electrophysiological activity following transplantation of microdissected dorsal or ventral pieces of rat fetal spinal cord tissue (FSCD or FSCV, respectively) into acute, cervical (C2) spinal hemisections. Transneuronal tracing demonstrated connectivity between donor neurons from both sources and the host phrenic circuitry. Phrenic nerve recordings revealed differential effects of dorsally vs. ventrally derived neural progenitors on ipsilateral phrenic nerve recovery and activity. These initial results suggest that local gray matter repair can influence motoneuron function in targeted circuits following spinal cord injury and that outcomes will be dependent on the properties and phenotypic fates of the donor cells employed. [ABSTRACT FROM AUTHOR]

Published

2010

21. Recovery of airway protective behaviors after spinal cord injury

Author

Bolser, Donald C., Jefferson, Stephanie C., Rose, Melanie J., Tester, Nicole J., Reier, Paul J., Fuller, David D., Davenport, Paul W., and Howland, Dena R.

Subjects

*SPINAL cord injuries, *AIRWAY (Anatomy), *REFLEXES, *PULMONARY function tests, *INTERNEURONS, *COUGH, *AXONS

Abstract

Abstract: Pulmonary morbidity is high following spinal cord injury and is due, in part, to impairment of airway protective behaviors. These airway protective behaviors include augmented breaths, the cough reflex, and expiration reflexes. Functional recovery of these behaviors has been reported after spinal cord injury. In humans, evidence for functional recovery is restricted to alterations in motor strategy and changes in the frequency of occurrence of these behaviors. In animal models, compensatory alterations in motor strategy have been identified. Crossed descending respiratory motor pathways at the thoracic spinal cord levels exist that are composed of crossed premotor axons, local circuit interneurons, and propriospinal neurons. These pathways can collectively form a substrate that supports maintenance and/or recovery of function, especially after asymmetric spinal cord injury. Local sprouting of premotor axons in the thoracic spinal cord also can occur following chronic spinal cord injury. These mechanisms may contribute to functional resiliency of the cough reflex that has been observed following chronic spinal cord injury in the cat. [Copyright &y& Elsevier]

Published

2009

22. Single-session effects of acute intermittent hypoxia on breathing function after human spinal cord injury.

Author

Sutor, Tommy, Cavka, Kathryn, Vose, Alicia K., Welch, Joseph F., Davenport, Paul, Fuller, David D., Mitchell, Gordon S., and Fox, Emily J.

Subjects

*SPINAL cord injuries, *OXYGEN in the blood, *HYPOXEMIA, *RESPIRATION, *ADULTS

Abstract

After spinal cord injury (SCI) respiratory complications are a leading cause of morbidity and mortality. Acute intermittent hypoxia (AIH) triggers spinal respiratory motor plasticity in rodent models, and repetitive AIH may have the potential to restore breathing capacity in those with SCI. As an initial approach to provide proof of principle for such effects, we tested single-session AIH effects on breathing function in adults with chronic SCI. 17 adults (13 males; 34.1 ± 14.5 years old; 13 motor complete SCI; >6 months post injury) completed two randomly ordered sessions, AIH versus sham. AIH consisted of 15, 1-min episodes (hypoxia: 10.3% O2; sham: 21% O2) interspersed with room air breathing (1.5 min, 21% oxygen); no attempt was made to regulate arterial CO2 levels. Blood oxygen saturation (SpO2), maximal inspiratory and expiratory pressures (MIP; MEP), forced vital capacity (FVC), and mouth occlusion pressure within 0.1 s (P0.1) were assessed. Outcomes were compared using nonparametric Wilcoxon's tests, or a 2 × 2 ANOVA. Baseline SpO2 was 97.2 ± 1.3% and was unchanged during sham experiments. During hypoxic episodes, SpO2 decreased to 84.7 ± 0.9%, and returned to baseline levels during normoxic intervals. Outcomes were unchanged from baseline post-sham. Greater increases in MIP were evident post AIH vs. sham (median values; +10.8 cmH 2 O vs. -2.6 cmH 2 O respectively, 95% confidence interval (−18.7) – (−4.3), p =.006) with a moderate Cohen's effect size (0.68). P 0.1 , MEP and FVC did not change post-AIH. A single AIH session increased maximal inspiratory pressure generation, but not other breathing functions in adults with SCI. Reasons may include greater spared innervation to inspiratory versus expiratory muscles or differences in the capacity for AIH-induced plasticity in inspiratory motor neuron pools. Based on our findings, the therapeutic potential of AIH on breathing capacity in people with SCI warrants further investigation. [ABSTRACT FROM AUTHOR]

Published

2021

23. Targeted activation of spinal respiratory neural circuits.

Author

Sunshine, Michael D., Sutor, Tommy W., Fox, Emily J., and Fuller, David D.

Subjects

*NEURAL circuitry, *RESPIRATORY muscles, *MOTOR neurons, *SPINAL nerves, *POSTURAL muscles, *SPINAL cord injuries, *INTERNEURONS

Abstract

Spinal interneurons which discharge in phase with the respiratory cycle have been repeatedly described over the last 50 years. These spinal respiratory interneurons are part of a complex propriospinal network that is synaptically coupled with respiratory motoneurons. This article summarizes current knowledge regarding spinal respiratory interneurons and emphasizes chemical, electrical and physiological methods for activating spinal respiratory neural circuits. Collectively, the work reviewed here shows that activating spinal interneurons can have a powerful impact on spinal respiratory motor output, and can even drive rhythmic bursting in respiratory motoneuron pools under certain conditions. We propose that the primary functions of spinal respiratory neurons include 1) shaping the respiratory pattern into the final efferent motor output from the spinal respiratory nerves; 2) coordinating respiratory muscle activation across the spinal neuraxis; 3) coordinating postural, locomotor and respiratory movements, and 4) enabling plasticity of respiratory motor output in health and disease. Unlabelled Image • Spinal interneurons (INs) with respiratory discharge patterns are well described. • Spinal respiratory motoneurons are synaptically coupled to spinal INs. • Spinal INs can modulate respiratory motoneuron activity. • Chemical, electrical and physiological methods can activate spinal respiratory INs. • Targeted activation of spinal INs may restore breathing after spinal cord injury. [ABSTRACT FROM AUTHOR]

Published

2020