Your search keyword '"Tail physiopathology"' showing total 6 results

1. Lymphatic function is regulated by a coordinated expression of lymphangiogenic and anti-lymphangiogenic cytokines.

Author

Zampell JC, Avraham T, Yoder N, Fort N, Yan A, Weitman ES, and Mehrara BJ

Subjects

Animals, Female, Inflammation metabolism, Inflammation pathology, Interferon-gamma antagonists & inhibitors, Interferon-gamma metabolism, Lymph metabolism, Lymphatic System pathology, Lymphatic System physiopathology, Lymphedema metabolism, Lymphedema pathology, Mice, Mice, Inbred C57BL, Mice, Nude, Regeneration physiology, T-Lymphocytes immunology, Tail anatomy & histology, Tail metabolism, Tail pathology, Tail physiopathology, Cytokines metabolism, Hepatocyte Growth Factor metabolism, Lymphangiogenesis physiology, Lymphatic System physiology, Vascular Endothelial Growth Factor A metabolism, Vascular Endothelial Growth Factor C metabolism

Abstract

Lymphangiogenic cytokines such as vascular endothelial growth factor-C (VEGF-C) are critically required for lymphatic regeneration; however, in some circumstances, lymphatic function is impaired despite normal or elevated levels of these cytokines. The recent identification of anti-lymphangiogenic molecules such as interferon-γ (IFN-γ), transforming growth factor-β1, and endostatin has led us to hypothesize that impaired lymphatic function may represent a dysregulated balance in the expression of pro/anti-lymphangiogenic stimuli. We observed that nude mice have significantly improved lymphatic function compared with wild-type mice in a tail model of lymphedema. We show that gradients of lymphatic fluid stasis regulate the expression of lymphangiogenic cytokines (VEGF-A, VEGF-C, and hepatocyte growth factor) and that paradoxically the expression of these molecules is increased in wild-type mice. More importantly, we show that as a consequence of T-cell-mediated inflammation, these same gradients also regulate expression patterns of anti-lymphangiogenic molecules corresponding temporally and spatially with impaired lymphatic function in wild-type mice. We show that neutralization of IFN-γ significantly increases inflammatory lymph node lymphangiogenesis independently of changes in VEGF-A or VEGF-C expression, suggesting that alterations in the balance of pro- and anti-lymphangiogenic cytokine expression can regulate lymphatic vessel formation. In conclusion, we show that gradients of lymphatic fluid stasis regulate not only the expression of pro-lymphangiogenic cytokines but also potent suppressors of lymphangiogenesis as a consequence of T-cell inflammation and that modulation of the balance between these stimuli can regulate lymphatic function.

Published

2012

2. Locomotion after spinal cord injury depends on constitutive activity in serotonin receptors.

Author

Fouad K, Rank MM, Vavrek R, Murray KC, Sanelli L, and Bennett DJ

Subjects

Aminopyridines pharmacology, Animals, Cordotomy, Electromyography, Female, Gait Disorders, Neurologic drug therapy, Gait Disorders, Neurologic etiology, Hindlimb physiopathology, Indoles pharmacology, Injections, Spinal, Locomotion drug effects, Muscle Hypotonia etiology, Pyridines pharmacology, Rats, Rats, Sprague-Dawley, Recovery of Function, Serotonin analogs & derivatives, Serotonin pharmacology, Serotonin therapeutic use, Serotonin 5-HT2 Receptor Antagonists pharmacology, Serotonin Receptor Agonists pharmacology, Serotonin Receptor Agonists therapeutic use, Spinal Cord Injuries complications, Tail physiopathology, Gait Disorders, Neurologic physiopathology, Locomotion physiology, Receptors, Serotonin, 5-HT2 physiology, Serotonin physiology, Spinal Cord Injuries physiopathology

Abstract

Following spinal cord injury (SCI) neurons caudal to the injury are capable of rhythmic locomotor-related activity that can form the basis for substantial functional recovery of stepping despite the loss of crucial brain stem-derived neuromodulators like serotonin (5-HT). Here we investigated the contribution of constitutive 5-HT(2) receptor activity (activity in the absence of 5-HT) to locomotion after SCI. We used a staggered hemisection injury model in rats to study this because these rats showed a robust recovery of locomotor function and yet a loss of most descending axons. Immunolabeling for 5-HT showed little remaining 5-HT below the injury, and locomotor ability was not correlated with the amount of residual 5-HT. Furthermore, blocking 5-HT(2) receptors with an intrathecal (IT) application of the neutral antagonist SB242084 did not affect locomotion (locomotor score and kinematics were unaffected), further indicating that residual 5-HT below the injury did not contribute to generation of locomotion. As a positive control, we found that the same application of SB242084 completely antagonized the muscle activity induced by exogenous application of the 5-HT(2) receptor agonists alpha-methyl-5-HT (IT). In contrast, blocking constitutive 5-HT(2) receptor activity with the potent inverse agonist SB206553 (IT) severely impaired stepping as assessed with kinematic recordings, eliminating most hindlimb weight support and overall reducing the locomotor score in both hind legs. However, even in the most severely impaired animals, rhythmic sweeping movements of the hindlimb feet were still visible during forelimb locomotion, suggesting that SB206553 did not completely eliminate locomotor drive to the motoneurons or motoneuron excitability. The same application of SB206553 had no affect on stepping in normal rats. Thus while normal rats can compensate for loss of 5-HT(2) receptor activity, after severe spinal cord injury rats require constitutive activity in these 5-HT(2) receptors to produce locomotion.

Published

2010

3. Tail muscles become slow but fatigable in chronic sacral spinal rats with spasticity.

Author

Harris RL, Bobet J, Sanelli L, and Bennett DJ

Subjects

Animals, Female, Muscle Spasticity etiology, Paraparesis, Spastic etiology, Rats, Rats, Sprague-Dawley, Sacrum physiopathology, Spinal Cord Injuries complications, Stress, Mechanical, Tail physiopathology, Muscle Contraction, Muscle Fatigue, Muscle Spasticity physiopathology, Muscle, Skeletal physiopathology, Paraparesis, Spastic physiopathology, Spinal Cord Injuries physiopathology

Abstract

Paralyzed skeletal muscle sometimes becomes faster and more fatigable after spinal cord injury (SCI) because of reduced activity. However, in some cases, pronounced muscle activity in the form of spasticity (hyperreflexia and hypertonus) occurs after long-term SCI. We hypothesized that this spastic activity may be associated with a reversal back to a slower, less fatigable muscle. In adult rats, a sacral (S2) spinal cord transection was performed, affecting only tail musculature and resulting in chronic tail spasticity beginning 2 wk later and lasting indefinitely. At 8 mo after injury, we examined the contractile properties of the segmental tail muscle in anesthetized spastic rats and in age-matched normal rats. The segmental tail muscle has only a few motor units (<12), which were easily detected with graded nerve stimulation, revealing two clear motor unit twitch durations. The dominant faster unit twitches peaked at 15 ms and ended within 50 ms, whereas the slower unit twitches only peaked at 30-50 ms. With chronic injury, this slow twitch component increased, resulting in a large overall increase (>150%) in the fraction of the peak muscle twitch force remaining at 50 ms. With injury, the peak muscle twitch (evoked with supramaximal stimulation) also increased in its time to peak (+48.9%) and half-rise time (+150.0%), and decreased in its maximum rise (-35.0%) and decay rates (-40.1%). Likewise, after a tetanic stimulation, the tetanus half-fall time increased by 53.8%. Therefore the slow portion of the muscle was enhanced in spastic muscles. Consistent with slowing, posttetanic potentiation was 9.2% lower and the stimulation frequency required to produce half-maximal tetanus decreased 39.0% in chronic spinals. Interestingly, in spastic muscles compared with normal, whole muscle twitch force was 81.1% higher, whereas tetanic force production was 38.1% lower. Hence the twitch-to-tetanus ratio increased 104.0%. Inconsistent with overall slowing, whole spastic muscles were 61.5% more fatigable than normal muscles. Thus contrary to the classical slow-to-fast conversion that is seen after SCI without spasticity, SCI with spasticity is associated with a mixed effect, including a preservation/enhancement of slow properties, but a loss of fatigue resistance.

Published

2006

4. Role of L-glutamate in systemic AVP-induced hypothermia.

Author

Paro FM, Almeida MC, Carnio EC, and Branco LG

Subjects

Adipose Tissue, Brown physiopathology, Animals, Blood Pressure drug effects, Body Temperature drug effects, Body Temperature Regulation drug effects, Excitatory Amino Acid Antagonists administration & dosage, Glycine analogs & derivatives, Heart Rate drug effects, Injections, Intravenous, Injections, Intraventricular, Kynurenic Acid administration & dosage, Male, Rats, Rats, Wistar, Receptors, Metabotropic Glutamate antagonists & inhibitors, Tail physiopathology, Thermogenesis drug effects, Arginine Vasopressin administration & dosage, Glutamic Acid metabolism, Glycine administration & dosage, Hypothermia chemically induced, Hypothermia physiopathology

Abstract

It has been reported that systemic injection of arginine vasopressin (AVP) induces a drop in body core temperature (T(c)), but little is known about the mechanisms involved. Because glutamate is an important excitatory neurotransmitter involved in a number of thermoregulatory actions, in the present study, we tested the hypothesis that glutamate plays a role in systemic AVP-induced hypothermia. Wistar rats were pretreated intracerebroventricularly (icv) with kynurenic acid, an antagonist of l-glutamate ionotropic receptors, alpha-methyl-(4-carboxyphenyl)glycine (MCPG), an antagonist of l-glutamate metabotropic receptors, or saline 15 min before intravenous injection of AVP (2 microg/kg) or saline. T(c), brown adipose tissue (BAT) temperature, blood pressure, heart rate, and tail skin temperature were measured continuously. Administration of saline icv followed by intravenous AVP caused a significant drop in T(c) brought about by a reduction in BAT thermogenesis and an increase in heat loss through the tail. MCPG treatment (icv) did not affect the fall in T(c) induced by AVP. Treatment with kynurenic acid (icv) abolished AVP-induced hypothermia but did not affect the AVP-evoked rise in blood pressure or drop in heart rate and BAT temperature. Heat loss through the tail was significantly reduced in animals injected with AVP and pretrated with kynurenic acid. These data indicate that ionotropic receptors of l-glutamate in the central nervous system participate in peripheral AVP-induced hypothermia by affecting heat loss through the tail.

Published

2003

5. Physiological survey of medullary raphe and magnocellular reticular neurons in the anesthetized rat.

Author

Leung CG and Mason P

Subjects

Animals, Autonomic Nervous System physiopathology, Brain Stem cytology, Brain Stem physiopathology, Electromyography, Electrophysiology, Hot Temperature, Male, Muscle, Skeletal physiopathology, Neurons classification, Pain physiopathology, Physical Stimulation, Raphe Nuclei cytology, Raphe Nuclei physiopathology, Rats, Rats, Sprague-Dawley, Tail physiopathology, Brain Stem physiology, Neurons physiology, Raphe Nuclei physiology

Abstract

The present study was designed to provide a detailed and quantitative description of the physiological characteristics of neurons in the medullary raphe magnus (RM) and adjacent nucleus reticularis magnocellularis (NRMC) under anesthetized conditions. The background discharge and noxious stimulus-evoked responses of RM and NRMC neurons were recorded in rats lightly anesthetized with isoflurane. All cells that were isolated successfully were studied. After recording background discharge, the neuronal response to repeated noxious thermal and noxious mechanical stimulation of the tail was recorded. Most cells were identified as nonserotonergic by their irregular or rapid background discharge pattern. Because the spontaneous discharge of most RM nonserotonergic cells contained pauses and bursts, a comparison between the change in rate evoked by tail heat and the range of rate changes that occur spontaneously was used to classify cells. The mean responses of ON and OFF cells were more than four times the standard deviation of the changes in rate observed spontaneously. ON cells were excited in 86% of the tail heat trials tested. Similarly, OFF cells were inhibited in 97% of the noxious tail heat trials tested. The heat-evoked changes in ON and OFF cell discharge varied over more than two orders of magnitude and were greater in cells with greater rates of background discharge. The heat-evoked responses of and cells had durations of tens of seconds to minutes and were always sustained beyond the visible motor response. Most ON and OFF cells responded to noxious tail clamp in a manner that was similar to their response to noxious heat. More than half of the NEUTRAL cells that were unresponsive to noxious heat were responsive to noxious tail clamp. A minority of ON, OFF, and NEUTRAL cells responded to innocuous brush stimulation with weak, transient responses. Although many cells discharged too infrequently to be classified, units with physiological properties that were different from those described above were rare. In conclusion, most RM and NRMC cells belong to three nonserotonergic physiological cell classes that can be distinguished from each other by the consistency, not the magnitude, of their responses to repeated noxious thermal stimulation. Because most of the heat-evoked change in and cell discharge occurs after the conclusion of the initial motor withdrawal, ON and OFF cells are likely to principally modulate the response to subsequent noxious insults.

Published

1998

6. Responses of neurons in the insular cortex to gustatory, visceral, and nociceptive stimuli in rats.

Author

Hanamori T, Kunitake T, Kato K, and Kannan H

Subjects

Afferent Pathways physiology, Animals, Brain Mapping, Cerebral Cortex cytology, Chemoreceptor Cells drug effects, Electric Stimulation, Female, Glossopharyngeal Nerve physiology, Laryngeal Nerves physiology, Rats, Rats, Sprague-Dawley, Tail physiopathology, Tongue innervation, Tongue physiology, Cerebral Cortex physiology, Chemoreceptor Cells physiology, Neurons physiology, Nociceptors physiology, Pain physiopathology, Pressoreceptors physiology, Taste physiology, Viscera innervation

Abstract

Extracellular unit responses to baroreceptor and chemoreceptor stimulation, gustatory stimulation of the posterior tongue, electrical stimulation of the superior laryngeal (SL) nerve, and tail pinch were recorded from the insular cortex of anesthetized and paralyzed rats. Forty-three neurons identified responded to stimulation by at least one of the stimuli used in the present study. Of the 43 neurons, 33 responded to tail pinch, and the remaining 10 had no response; 18 showed an excitatory response, and 15 showed an inhibitory response. Of the 43 neurons, 35 responded to electrical stimulation of the SL nerve; 27 showed an excitatory response, and 8 showed an inhibitory response. Of the 20 neurons that responded to baroreceptor stimulation by an intravenous injection of methoxamine hydrochloride (Mex), 11 were excitatory and 9 were inhibitory. Twenty-seven neurons were responsive to an intravenous injection of sodium nitroprusside (SNP); 10 were excitatory and 17 were inhibitory. Ten neurons were excited and 16 neurons were inhibited by arterial chemoreceptor stimulation by an intravenous injection of sodium cyanide (NaCN). Twenty-six neurons were responsive to at least one of the gustatory stimuli (1.0 M NaCl, 30 mM HCl, 30 mM quinine HCl, and 1.0 M sucrose): four to six excitatory neurons and three to nine inhibitory neurons for each stimulus. A large number of the neurons (42/43) received convergent inputs from more than one stimulus among the nine stimuli used in the present study. Most neurons (38/43) were responsive to two or more stimulus groups when the natural stimuli used in the present study are grouped into three, gustatory, visceral, and nociceptive stimuli. The neurons recorded were located in the insular cortex between 2.8 mm anterior and 1.1 mm posterior to the anterior edge of the joining of the anterior commissure (AC); the mean location was 1.0 mm (n = 43) anterior to the AC. This indicates that most of the neurons identified in the present study were located in the region posterior to the taste area and anterior to the visceral area in the insular cortex. These results indicate that the insular cortex neurons distributing between the taste area and the visceral area receive convergent inputs from baroreceptor, chemoreceptor, gustatory, and nociceptive organs and may have roles in taste aversion or in regulation of visceral responses.

Published

1998