Segmental organization of visceral and somatic input onto C3-T6 spinothalamic tract cells of the monkey.

1. Referred pain of visceral origin has three major characteristics: visceral pain is referred to somatic areas that are innervated from the same spinal segments as the diseased organ; visceral pain is referred to proximal body regions and not to distal body areas; and visceral pain is felt as deep pain and not as cutaneous pain. The neurophysiological basis for these phenomena is poorly understood. The purpose of this study was to examine the organization of viscerosomatic response characteristics of spinothalamic tract (STT) neurons in the rostral spinal cord. Interactions were determined among the following: 1) segmental location, 2) effects of input by cardiopulmonary sympathetic, greater splanchnic, lumbar sympathetic, and urinary bladder afferent fibers, 3) location of excitatory somatic field, e.g., hand, forearm, proximal arm, or chest, 4) magnitude of response to hair, skin, and deep mechanoreceptor afferent input, and 5) regional specificity of thalamic projection sites. 2. A total of 89 STT neurons in segments C3-T6 were characterized for responses to visceral and somatic stimuli. Neurons were activated antidromically from the contralateral ventroposterolateral oralis or caudalis nuclei of the thalamus. Cell responses to visceral and somatic stimuli were not different on the basis of the thalamic site of antidromic activation. Recording sites for 61 neurons were located histologically; 87% of lesion sites were located in laminae IV-VII or X. There was no relationship between response properties of the neurons and spinal laminar location. 3. Different responses to visceral stimuli were observed in three zones of the rostral spinal cord: C3-C6, C7-C8, and T1-T6. In C3-C6, urinary bladder distension (UBD) and electrical stimulation of greater splanchnic and lumbar sympathetic afferent fibers inhibited STT cells. Electrical stimulation of cardiopulmonary sympathetic afferents increased cell activity in C5 and C6 and either excited or inhibited STT cells in C3 and C4. In the cervical enlargement (C7-C8), STT cells generally were either inhibited or showed little response to stimulation of visceral afferent fibers. In T1-T6, input from greater splanchnic and cardiopulmonary sympathetic afferent nerves increased activity of STT cells. Lumbar sympathetic afferent input inhibited cells in T1-T2 and had little effect on cells in T3-T6, whereas UBD decreased cell activity in all segments studied. 4. In general, stimulation of somatic structures increased activity of STT neurons in segments that received primary afferent innervation from the excitatory somatic receptive field or in the segments immediately adjacent to these segments. Only input from the forelimb, especially the hand, markedly excited cells in C7 and C8.+     

Convergence of phrenic and cardiopulmonary spinal afferent information on cervical and thoracic spinothalamic tract neurons in the monkey: implications for referred pain from the diaphragm and heart

1. Spinothalamic tract (STT) neurons in the C3-T6 spinal segments were studied for their responses to stimulation of phrenic and cardiopulmonary spinal afferent fibers. A total of 142 STT neurons were studied in 44 anesthetized, paralyzed monkeys (Macaca fascicularis). All neurons were antidromically activated from the ventroposterolateral nucleus and/or medial thalamus. 2. Electrical stimulation of phrenic afferent fibers (PHR) excited 43/58 (74%), inhibited 2/58 (3%), and did not affect 13/58 (13%) of cervical STT neurons. Neurons with excitatory somatic fields confined to the proximal limb or encompassing the whole limb were excited to a significantly greater extent by electrical stimulation of PHR than were neurons with somatic fields confined to the distal limb. Mechanical stimulation of PHR by probing the exposed diaphragm excited 11/22 (50%), inhibited 3/22 (14%), and did not affect 8/22 (36%) cervical STT neurons. 3. The technique of minimum afferent conduction velocity (MACV) was used to obtain information about the identity of the PHR that excited 35 cervical STT neurons. Evidence was obtained for excitation of these neurons by group II and III PHR. The mean +/- SE MACV for all neurons was 14 +/- 2 m/s. 4. Electrical stimulation of cardiopulmonary spinal afferent fibers excited 41/57 (72%), inhibited 8/57 (14%), and did not affect 8/57 (14%) of cervical STT neurons. Neurons with excitatory somatic fields confined to the proximal limb or encompassing the whole limb were excited to a significantly greater extent by electrical stimulation of cardiopulmonary spinal afferents than were neurons with somatic fields confined to the distal limb. 5. Excitatory convergence of PHR and cardiopulmonary spinal afferent input was observed for 36/57 (63%) cervical STT neurons. 6. Electrical stimulation of PHR excited 36/84 (43%), inhibited 25/84 (30%), and did not affect 23/84 (27%) of thoracic STT neurons. All of these neurons received excitatory cardiopulmonary spinal afferent input. 7. Neurons were more likely to be excited by electrical stimulation of PHR if they were located in C3-C6 spinal segments. Furthermore, the net excitatory effect of PHR input decreased in more caudal segments, such that thoracic STT neurons were weakly excited relative to cervical STT neurons. 8. We conclude that cervical STT neurons with excitatory somatic fields that include or are restricted to proximal sites are excited by electrical or mechanical stimulation of PHR. Those effects demonstrate a physiological substrate for pain referred from the diaphragm to the shoulder in patients with pleural effusions or subphrenic abscesses.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evidence that C1 and C2 propriospinal neurons mediate the inhibitory effects of viscerosomatic spinal afferent input on primate spinothalamic tract neurons.

1. Lumbosacral spinothalamic tract (STT) neurons can be inhibited by noxious pinch of the contralateral hindlimb or either forelimb and by electrical stimulation of cardiopulmonary sympathetic, splanchnic, and hypogastric afferents. A previous study found that spinal transections between C2 and C4 sometimes abolished the inhibitory effect of spinal afferent input and sometimes left it intact. This suggested that propriospinal neurons in the C1 and C2 segments might mediate this effect. To test whether neurons in the C1 and C2 segments were involved in producing this inhibitory effect, the magnitude of the reduction in neural activity was measured in the same STT neuron before and after spinal transection at C1 or between C3 and C7. 2. All neurons were antidromically activated from the contralateral thalamus and thoracic spinal cord. For us to accept a neuron for analysis, the characteristics of the somatic input and the latency and shape of the antidromatic spike produced by spinal cord stimulation had to be the same before and after the spinal transection. Also, spinal transection often causes a marked increase in spontaneous cell activity, which may affect the magnitude of an inhibitory response. To avoid this confounding problem, a cell was accepted for analysis only if it showed marked inhibition of high cell activity evoked by somatic pinch before spinal transection. For analysis 13 STT neurons met these criteria: 6 neurons were in monkeys with C1 transections, and 7 neurons were in animals with transections between C3 and C7.(ABSTRACT TRUNCATED AT 250 WORDS)     

Responses and afferent pathways of superficial and deeper c(1)-c(2) spinal cells to intrapericardial algogenic chemicals in rats

Electrical stimulation of vagal afferents or cardiopulmonary sympathetic afferent fibers excites C(1)--C(2) spinal neurons. The purposes of this study were to compare the responses of superficial (depth <0.35 mm) and deeper C(1)--C(2) spinal neurons to noxious chemical stimulation of cardiac afferents and determine the relative contribution of vagal and sympathetic afferent pathways for transmission of noxious cardiac afferent input to C(1)--C(2) neurons. Extracellular potentials of single C(1)--C(2) neurons were recorded in pentobarbital anesthetized and paralyzed male rats. A catheter was placed in the pericardial sac to administer a mixture of algogenic chemicals (0.2 ml) that contained adenosine (10(-3) M), bradykinin, histamine, serotonin, and prostaglandin E(2) (10(-5) M each). Intrapericardial chemicals changed the activity of 20/106 (19%) C(1)--C(2) spinal neurons in the superficial laminae, whereas 76/147 (52%) deeper neurons responded to cardiac noxious input (P < 0.01). Of 96 neurons responsive to cardiac inputs, 48 (50%) were excited (E), 41 (43%) were inhibited (I), and 7 were excited/inhibited (E-I) by intrapericardial chemicals. E or I neurons responsive to intrapericardial chemicals were subdivided into two groups: short-lasting (SL) and long-lasting (LL) response patterns. In superficial gray matter, excitatory responses to cardiac inputs were more likely to be LL-E than SL-E neurons. Mechanical stimulation of the somatic field from the head, neck, and shoulder areas excited 85 of 95 (89%) C(1)--C(2) spinal neurons that responded to intrapericardial chemicals; 31 neurons were classified as wide dynamic range, 49 were high threshold, 5 responded only to joint movement, and no neuron was classified as low threshold. For superficial neurons, 53% had small somatic fields and 21% had bilateral fields. In contrast, 31% of the deeper neurons had small somatic fields and 46% had bilateral fields. Ipsilateral cervical vagotomy interrupted cardiac noxious input to 8/30 (6 E, 2 I) neurons; sequential transection of the contralateral cervical vagus nerve (bilateral vagotomy) eliminated the responses to intrapericardial chemicals in 4/22 (3 E, 1 I) neurons. Spinal transection at C(6)--C(7) segments to interrupt effects of sympathetic afferent input abolished responses to cardiac input in 10/10 (7 E, 3 I) neurons that still responded after bilateral vagotomy. Results of this study support the concept that C(1)-C(2) superficial and deeper spinal neurons play a role in integrating cardiac noxious inputs that travel in both the cervical vagal and/or thoracic sympathetic afferent nerves.     

Vagal afferent inhibition of primate thoracic spinothalamic neurons

Spinothalamic (ST) neurons in the C8-T5 segments of the spinal cord were examined for responses to electrical stimulation of the left thoracic vagus nerve (LTV). Seventy-one ST neurons were studied in 39 anesthetized monkeys (Macaca fascicularis). Each neuron could be excited by manipulation of its somatic field and by electrical stimulation of cardiopulmonary sympathetic afferent fibers. LTV stimulation resulted in inhibition of the background activity of 43 (61%) ST neurons. Nine (13%) were excited, 3 (4%) were excited and then inhibited, while 16 (22%) did not respond. There was little difference among these groups in terms of the type of somatic or sympathetic afferent input although inhibited cells tended to be more prevalent in the more superficial laminae. The degree of inhibition resulting from LTV stimulation was related, in a linear fashion, to the magnitude of cell activity before stimulation. LTV inhibition of background activity was similar among wide dynamic range, high threshold, and high-threshold cells with inhibitory hair input. Any apparent differences in LTV inhibitory effects among these groups were accounted for by the differences in ongoing cell activity as predicted by linear regression analysis. LTV stimulation inhibited responses of 32 of 32 ST cells to somatic stimuli. In most cases the stimulus was a noxious pinch; however, LTV stimulation also inhibited responses to innocuous stimuli such as hair movement. Bilateral cervical vagotomy abolished the inhibitory effect of LTV stimulation on background activity (six cells) or responses to somatic stimuli (seven cells). Stimulation of the cardiac branch of the vagus inhibited activity of three cells to a similar degree as LTV stimulation, while stimulation of the vagus below the heart was ineffective in reducing activity of 10 cells. We conclude that LTV stimulation alters activity of ST neurons in the upper thoracic spinal cord. Vagal inhibition of ST cell activity was due to stimulation of cardiopulmonary vagal afferent fibers coursing to the brain stem, which appear to activate descending inhibitory spinal pathways. Vagal afferent activity may participate in processing of somatosensory information as well as information related to cardiac pain.     

Spinal cord stimulation modulates intraspinal colorectal visceroreceptive transmission in rats

Previous studies have shown that spinal cord stimulation (SCS) of upper lumbar segments decreases visceromotor responses to mechanical stimuli in a sensitized rat colon and reduces symptoms of irritable bowel syndrome in patients. SCS applied to the upper cervical spinal dorsal column reduces pain of chronic refractory angina. Further, chemical stimulation of C1-C2 propriospinal neurons in rats modulates the responses of lumbosacral spinal neurons to colorectal distension. The present study was designed to compare the effects of upper cervical and lumbar SCS on activity of lumbosacral neurons receiving noxious colorectal input. Extracellular potentials of L6-S2 spinal neurons were recorded in pentobarbital anesthetized, paralyzed and ventilated male rats. SCS (50 Hz, 0.2 ms) at low intensity (90% of motor threshold) was applied to the dorsal column of upper cervical (C1-C2) or upper lumbar (L2-L3) ipsilateral spinal segments. Colorectal distension (CRD, 20 mmHg, 40 mmHg, 60 mmHg, 20s) was produced by air inflation of a latex balloon. Results showed that SCS applied to L2-L3 and C1-C2 segments significantly reduced the excitatory responses to noxious CRD from 417.6+/-68.0 to 296.3+/-53.6 imp (P<0.05, n=24) and from 336.2+/-64.5 to 225.0+/-73.3 imp (P<0.05, n=18), respectively. Effects of L2-L3 and C1-C2 SCS lasted 10.2+/-1.9 and 8.0+/-0.9 min after offset of CRD. Effects of SCS were observed on spinal neurons with either high or low-threshold excitatory responses to CRD. However, L2-L3 or C1-C2 SCS did not significantly affect inhibitory neuronal responses to CRD. C1-C2 SCS-induced effects were abolished by cutting the C7-C8 dorsal column but not by spinal transection at cervicomedullary junction. These data demonstrated that upper cervical or lumbar SCS modulated responses of lumbosacral spinal neurons to noxious mechanical stimulation of the colon, thereby, proved two loci for a potential therapeutic effect of SCS in patients with irritable bowel syndrome and other colonic disorders.     

Responses and afferent pathways of C1-C2 spinal neurons to cervical and thoracic esophageal stimulation in rats

Because vagal and sympathetic inputs activate upper cervical spinal neurons, we hypothesized that stimulation of the esophagus would activate C(1)-C(2) neurons. This study examined responses of C(1)-C(2) spinal neurons to cervical and thoracic esophageal distension (CED, TED) and afferent pathways for CED and TED inputs to C(1)-C(2) spinal neurons. Extracellular potentials of single C(1)-C(2) spinal neurons were recorded in pentobarbital-anesthetized male rats. Graded CED or TED was produced by water inflation (0.1-0.5 ml) of a latex balloon. CED changed activity of 48/219 (22%) neurons; 34 were excited (E), 12 were inhibited (I), and 2 were E-I. CED elicited responses for 18/18 neurons tested after ipsilateral cervical vagotomy, for 12/14 neurons tested after bilateral vagotomy and for 9/11 neurons tested after bilateral vagotomy and C(6)-C(7) spinal cord transection. TED changed activity of 31/190 (16%) neurons (28E, 3 I). Ipsilateral cervical vagotomy abolished TED-evoked responses of 5/12 neurons. Bilateral vagotomy eliminated responses of 2/4 neurons tested, and C(6)-C(7) spinal transection plus bilateral vagotomy eliminated responses of 2/2 neurons. Thus inputs from CED to C(1)-C(2) neurons most likely entered upper cervical dorsal roots, whereas inputs from TED were dependent on vagal pathways and/or sympathetic afferent pathways that entered the thoracic dorsal roots. These results supported a concept that C(1)-C(2) spinal neurons play a role in integrating visceral information from cervical and thoracic esophagus.     

Chemical activation of cervical cell bodies: effects on responses to colorectal distension in lumbosacral spinal cord of rats

We have shown that stimulation of cardiopulmonary sympathetic afferent fibers activates relays in upper cervical segments to suppress activity of lumbosacral spinal cells. The purpose of this study was to determine if chemical excitation (glutamate) of upper cervical cell bodies changes the spontaneous activity and evoked responses of lumbosacral spinal cells to colorectal distension (CRD). Extracellular potentials were recorded in pentobarbital-anesthetized male rats. CRD (80 mmHg) was produced by inflating a balloon inserted in the descending colon and rectum. A total of 135 cells in the lumbosacral segments (L(6)-S(2)) were activated by CRD. Seventy-five percent (95/126) of tested cells received convergent somatic input from the scrotum, perianal region, hindlimb, and tail; 99/135 (73%) cells were excited or excited/inhibited by CRD; and 36 (27%) cells were inhibited or inhibited/excited by CRD. A glutamate (1 M) pledget placed on the surface of C(1)-C(2) segments decreased spontaneous activity and excitatory CRD responses of 33/56 cells and increased spontaneous activity of 13/19 cells inhibited by CRD. Glutamate applied to C(6)-C(7) segments decreased activity of 10/18 cells excited by CRD, and 9 of these also were inhibited by glutamate at C(1)-C(2) segments. Glutamate at C(6)-C(7) increased activity of 4/6 cells inhibited by CRD and excited by glutamate at C(1)-C(2) segments. After transection at rostral C(1) segment, glutamate at C(1)-C(2) still reduced excitatory responses of 7/10 cells. Further, inhibitory effects of C(6)-C(7) glutamate on excitatory responses to CRD still occurred after rostral C(1) transection but were abolished after a rostral C(6) transection in 4/4 cells. These data showed that C(1)-C(2) cells activated with glutamate primarily produced inhibition of evoked responses to visceral stimulation of lumbosacral spinal cells. Inhibition resulting from activation of cells in C(6)-C(7) segments required connections in the upper cervical segments. These results provide evidence that upper cervical cells integrate information that modulates activity of distant spinal neurons responding to visceral input.     

Suppressive effect of vagal afferents on cervical dorsal horn neurons responding to tooth pulp electrical stimulation in the rat

The aim of the present study was to test the hypothesis that vagal afferent (VA) inputs modify the tooth pulp (TP) stimulation-evoked activity of the first cervical dorsal horn (C1) neurons via the activation of endogenous noradrenergic and serotonergic systems. In 30 anesthetized rats, the activity of 56 C1 spinal neurons and the amplitude in a digastric muscle electromyogram (dEMG, n=30) increased proportionally during TP stimulation at an intensity of 1-3.5 times the threshold for the jaw-opening reflex (JOR). The activity in 46 of these C1 neurons (82.1%) was suppressed by VA stimulation (1.0 mAx0.1 ms, 50 Hz for 30 s) of the right vagus nerve. The suppressive effects of VA stimulation on C1 spinal neuron activity were significantly reduced after intravenous administration of either the alpha-adrenergic receptor antagonist phenoxybenzamine (POB, 2.0 mg/kg and 4.0 mg/kg) or the 5-hydroxytryptamine-3 (5-HT(3)) receptor antagonist ICS 205-930 (1.0 mg/kg and 2.0 mg/kg). But the 5-HT(1/2) receptor antagonist methysergide (1.0 mg/kg and 2.0 mg/kg) had no significant effect on VA stimulation-induced inhibition of the C1 spinal neuron activity. These results suggest that VA stimulation inhibits nociceptive transmission in the C1 spinal neuron activity via the activation of both noradrenergic and serotonergic (5-HT(3)) descending inhibitory systems.     

Urinary bladder and hindlimb afferent input inhibits activity of primate T2-T5 spinothalamic tract neurons

1. Extracellular recordings were made from 41 spinothalamic tract (STT) neurons on the left side of the T2-T5 spinal segments of 20 monkeys (Macaca fascicularis) anesthetized with alpha-chloralose. Manipulation of the left triceps-chest region and electrical stimulation of cardiopulmonary sympathetic afferent fibers excited these cells. 2. Isotonic urinary bladder distensions (UBD) to pressures between 20 and 80 cmH2O reduced the spontaneous activity in 33 of 41 cells. Cell activity was significantly reduced by UBD at 20 cmH2O. Distensions to 40, 60, and 80 cmH2O produced progressively greater reductions in spontaneous discharge. Activity was decreased throughout distension in 29 cells (tonic inhibition) and at the onset of distension in 3 neurons (phasic inhibition). In one cell, inhibition followed a brief excitation at the onset of distension (phasic excitation-tonic inhibition). Spontaneous bladder contractions also inhibited STT cell activity. 3. Inhibition by UBD was observed in STT cells characterized as wide dynamic range, high threshold, and high threshold inhibitory. No correlation existed between cell type or laminar location and inhibition by urinary bladder distension. Cells excited by cardiopulmonary sympathetic afferent A delta- and C-fibers had a significantly greater tendency to be inhibited by UBD (17 of 18) than cells activated by A delta- but not C-fibers (13 of 20). 4. Urinary bladder distension and pinch of the hindlimbs also reduced activity of STT cells excited by input from cardiopulmonary sympathetic afferents and from the proximal forelimb. 5. Urinary bladder distension to 40, 60, or 80 cmH2O produced a greater absolute but smaller relative reduction in the firing frequency of STT cells as spontaneous activity increased. Thus the magnitude of this inhibitory effect may depend on whether the inhibitory effect is measured as an absolute or relative change in cell activity. 6. Convergent inhibitory input from somatic regions also was observed. Noxious pinch of the hamstring region of the right hindlimb decreased activity in 32 of 39 cells. Left hindlimb pinch inhibited 21 of 38 cells, and 15 of 29 cells were inhibited by right triceps pinch. 7. Convergent inhibitory input from the hamstring region of the hindlimbs and from the urinary bladder to upper thoracic STT cells may be important for coding the intensity and location of noxious visceral and somatic stimuli and for organizing the appropriate sequence of motor responses when multiple noxious stimuli are present.     

Electrical stimulation of visceral afferent pathways in the pelvic nerve increases c-fos in the rat lumbosacral spinal cord.

Electrical stimulation (20-35 Hz, 2-5 V, 1.5 h) of the pelvic nerve in urethane-anesthetized rats increased the expression of c-fos protein-immunoreactivity primarily in neurons in the L6-S1 segments of the spinal cord. The neurons were localized to areas receiving afferent input from the pelvic viscera including the superficial dorsal horn, the dorsal commissure, and lateral laminae V-VII in the region of the sacral parasympathetic nucleus. These experiments indicate that (1) electrical stimulation of abdominal nerves following surgical exposure is a useful method for tracing visceral afferent pathways and (2) afferent information from the pelvic viscera is received by neurons in specific areas of the dorsal horn.     

Integration in descending motor pathways controlling the forelimb in the cat

Summary Recording was made in the C3-C4 segments from cell bodies of propriospinal neurones identified by their antidromic activation from more caudal segments. Monosynaptic excitatory effects from descending motor pathways and primary afferents were investigated by electrical stimulation of higher motor centres and peripheral nerves in the forelimb and neck.The cell bodies were located mainly laterally in Rexed's layer VII. Threshold mapping for single axons showed that they descend in the lateroventral part of the lateral funicle. Antidromic stimulation at different spinal cord levels showed that some neurones terminated in the forelimb segments, others in the thoracic cord or in the lumbar segments. Terminal slowing of the conduction velocity suggested axonal branching over some segments.Monosynaptic EPSPs were evoked in the neurones by stimulation of the contralateral pyramid, red nucleus and dorsal tegmentum-superior colliculus. It is concluded that corticospinal, rubrospinal and tectospinal fibres project directly to both short and long propriospinal neurones. There was marked frequency potentiation in tectospinal synapses. Convergence from two descending tracts was common and in half of the tested cells all three tracts contributed monosynaptic excitation. Experiments with collision of descending volleys and antidromic volleys from the brachial segments demonstrated that the corticospinal and rubrospinal monosynaptic projection to the propriospinal neurones is by collaterals from fibres continuing to the forelimb segments.Stimulation of cervical primary afferents in the dorsal column gave monosynaptic EPSPs in somewhat less than half of the tested propriospinal neurones. The further analysis with stimulation of forelimb nerves and C2-C3 dorsal rami showed that monosynaptic EPSPs may be evoked from low threshold cutaneous and group I muscle afferents in the forelimb and from C2-C3 neck afferents entering close to the spinal ganglia, possibly from joint receptors. Convergence from cervical afferents and at least two of the above descending tracts was common.It is postulated that the propriospinal neurones previously indirectly defined by their action on motoneurones as relaying disynaptic excitation from higher motor centres to forelimb motoneurones (Illert et al., 1977) belong to those neurones of the C3-C4 propriospinal systems which terminate in the cervical enlargement. The function of the neurones projecting beyond the upper thoracic segments is discussed.Supported by the Deutsche ForschungsgemeinschaftIBRO/UNESCO Fellow     

Cardiopulmonary sympathetic afferent excitation of lower thoracic spinoreticular and spinothalamic neurons

1. Responses of spinoreticular (SRT) and spinothalamic (STT) neurons located in the T7-T9 segments to cardiopulmonary sympathetic afferent (CPS) stimuli were studied in 27 cats that were anesthetized with alpha-chloralose. 2. CPS stimulation excited 32 SRT and 10 STT neurons. Each neuron was also excited by stimulation of the left greater splanchnic nerve (SPL) and had a somatic receptive field that was most commonly located on the upper abdomen and over the lower rib cage. An additional 12 SRT and 3 STT neurons received input from SPL and somatic structures but failed to respond to CPS stimulation. 3. CPS stimulation evoked early responses (23 cells) or both early and late responses (19 cells) that had average latencies of 12.7 +/- 1.8 and 88.2 +/- 13.1 (SE) ms, respectively. Latencies of responses to SPL stimulation were significantly shorter and averaged 8.1 +/- 0.9 and 46.1 +/- 7.1 ms. Magnitudes of early responses to SPL stimulation were significantly greater than responses to CPS stimulation; however, late responses were not different. 4. Responses to CPS stimulation were inhibited by a prior conditioning stimulus applied to SPL. Greatest inhibition occurred at a conditioning-test interval of 40 ms, and inhibition lasted for at least 300 ms. Inhibition of responses to SPL stimulation could be evoked by conditioning stimuli applied to CPS; however, the inhibition was significantly less than that evoked by SPL stimulation on responses to CPS stimulation. 5. Thirty-eight neurons were tested for responses to injection of bradykinin (4 micrograms/kg) into the left atrium. Discharge rate of 17 cells increased from 5 +/- 2 to 12 +/- 4 Hz. Four cells were tachyphylactic to repeated injections. Injections of bradykinin into the thoracic aorta did not significantly alter cell activity. Bilateral cervical vagotomy had no effect on responses to intracardiac bradykinin. 6. The results indicate that lower thoracic SRT and STT neurons are excited by CPS stimuli including noxious stimulation of the heart. However, comparison of these responses with previously reported responses of upper thoracic SRT and STT neurons indicate that there is a decrease in effectiveness of CPS stimuli from upper to lower thoracic segments. Convergence of CPS and abdominal inputs onto lower thoracic pain pathways could explain abdominal pain that is occasionally associated with cardiac disease.     

Propriospinal neurons are sufficient for bulbospinal transmission of the locomotor command signal in the neonatal rat spinal cord

We recently showed that propriospinal neurons contribute to bulbospinal activation of locomotor networks in the in vitro neonatal rat brainstem–spinal cord preparation. In the present study, we examined whether propriospinal neurons alone, in the absence of long direct bulbospinal transmission to the lumbar cord, can successfully mediate brainstem activation of the locomotor network. In the presence of staggered bilateral spinal cord hemisections, the brainstem was stimulated electrically while recording from lumbar ventral roots. The rostral hemisection was located between C1 and T3 and the contralateral caudal hemisection was located between T5 and mid-L1. Locomotor-like activity was evoked in 27% of the preparations, which included experiments with staggered hemisections placed only two segments apart. There was no relation between the likelihood of developing locomotor-like activity and the distance separating the two hemisections or specific level of the hemisections. In some experiments, where brainstem stimulation alone was ineffective, neurochemical excitation of propriospinal neurons (using 5-HT and NMDA) at concentrations subthreshold for producing locomotor-like activity, promoted locomotor-like activity in conjunction with brainstem stimulation. In other experiments, involving neither brainstem stimulation nor cord hemisections, the excitability of propriospinal neurons in the cervical and/or thoracic region was selectively enhanced by bath application of 5-HT and NMDA or elevation of bath K⁺ concentration. These manipulations produced locomotor-like activity in the lumbar region. In total, the results suggest that propriospinal neurons are sufficient for transmission of descending locomotor command signals. This observation has implications for regeneration strategies aimed at restoration of locomotor function after spinal cord injury.     

Behavior of upper cervical inspiratory propriospinal neurons during fictive vomiting

1. The role of upper cervical inspiratory (UCI)-modulated neurons in respiratory muscle control during vomiting was examined by recording the impulse activity of these neurons during fictive vomiting in decerebrate, paralyzed cats. Fictive vomiting was identified by a characteristic series of bursts of coactivation of phrenic and abdominal muscle nerves, elicited either by electrical stimulation of supradiaphragmatic vagal nerve afferents or by emetic drugs, which would be expected to produce expulsion of gastric contents in nonparalyzed animals. 2. Data were recorded from 43 propriospinal UCI neurons, located in the C1-C3 spinal segments near the border of the intermediate gray matter and lateral funiculus, which were antidromically activated with floating pin electrodes placed in the ipsilateral lateral funiculus, usually at T1-T3. Some cells (9/21 tested) were also activated from the upper lumbar cord (L1). During respiration, most neurons (n = 40) had an augmenting discharge pattern during inspiration. In addition, more than one-half (55%) fired tonically during the remainder of the respiratory cycle. About 40% of UCI neurons showed variations in their firing pattern during the noninspiratory portion of respiration. These latter two properties of UCI neurons were not observed in dorsal and ventral respiratory group (DRG and VRG-, respectively) bulbospinal inspiratory (I) neurons previously recorded under similar conditions. 3. During fictive vomiting, the firing pattern of most UCI neurons fell into one of three main categories. More than one-half (53%) were active in phase with bursts of phrenic discharge and were thus classified as Active-type cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Response properties of the brainstem neurons of the cat following intra-esophageal acid-pepsin infusion

Studies in humans have documented that acute acid infusion into the esophagus leads to decrease in threshold for sensations to mechanical distension of the esophagus. It is not known whether acid infusion leads to sensitization of brainstem neurons receiving synaptic input from vagal afferent fibers innervating the esophagus. The aim of this study was to investigate the correlation of responses of vagal afferents and brainstem neurons after acute infusion of acid (0.1 N HCl)+pepsin (1 mg/ml) into the esophagus of cats. The vagal afferent fibers (n=20) exhibited pressure-dependent increase in firing to graded esophageal distension (5-80 mm Hg). Infusion of acid+pepsin into the esophagus produced a significant increase in ongoing resting firing of five of 16 fibers (31%) tested. However, their responses to graded esophageal distension did not change when tested 30 min after infusion. Pepsin infusion did not change the resting firing and response to esophageal distension (n=4). Twenty-one brainstem neurons were recorded that responded in an intensity-dependent manner to graded esophageal distension. Responses of 12 excited neurons were tested after intra-esophageal acid+pepsin infusion. Neurons exhibited a decrease in threshold for response to esophageal distension and increase in firing after acid+pepsin infusion. The sensitization of response after intra-esophageal acid remained unaffected after cervical (C1-C2) spinal transection (n=3). Results indicate that the esophageal distension-sensitive neurons in the brainstem exhibit sensitization of response to esophageal distension after acute acid+pepsin exposure. The sensitization of brainstem neurons is possibly initiated by increased spontaneous firing of the vagal afferent fibers to acid+pepsin, but not to sensitized response of vagal distension-sensitive afferent fibers to esophageal distension. Results also indicate that spinal pathway does not contribute to sensitization of brainstem neurons.     

Motor and sensory re-innervation of the lung and heart after re-anastomosis of the cervical vagus nerve in rats

There is no study in the literature dealing with re-innervation of the cardiopulmonary vagus nerve after its transection followed by re-anastomosis. In the present study, we explored the bronchomotor, heart rate and respiratory responses in rats at 2, 3 and 6 months after re-anastomosis of one cervical vagus trunk. The conduction velocity of A, B and C waves was calculated in the compound vagal action potential. We searched for afferent vagal activities in phase with pulmonary inflation to assess the persistence of pulmonary stretch receptor (PSR) discharge in re-innervated lungs. In each animal, data from the stimulation or recording of one re-anastomosed vagus nerve were compared with those obtained in the contra-lateral intact one. Two and three months after surgery, the conduction velocities of A and B waves decreased, but recovery of conduction velocity was complete at 6 months. By contrast, the conduction velocity of the C wave did not change until 6 months, when it was doubled. The PSR activity was present in 50% of re-anastomosed vagus nerves at 2 and 3 months and in 75% at 6 months. Respiratory inhibition evoked by vagal stimulation was significantly weaker from the re-anastomosed than intact nerve at 2 but not 3 months. Vagal stimulation did not elicit cardiac slowing or bronchoconstriction 6 months after re-anastomosis. Our study demonstrates the capacity of pulmonary vagal sensory neurones to regenerate after axotomy followed by re-anastomosis, and the failure of the vagal efferents to re-innervate both the lungs and heart.     

Chemical communication between vagal afferent somata in nodose Ganglia of the rat and the Guinea pig in vitro

The cell bodies of spinal afferents, dorsal root ganglion neurons, are depolarized several millivolts, and their probability of spiking increased when axons of neighboring somata in the same ganglion are electrically stimulated repetitively. This form of neural communication has been designated cross-depolarization (CD) and cross-excitation (CE). The existence of CD and CE between somata of vagal afferents (nodose ganglion neurons, NGNs) of rats and guinea pigs was investigated by electrically stimulating the vagus nerve while recording the electrical activity of NGNs in intact nodose ganglia with sharp intracellular microelectrodes. CD and CE in NGNs were manifested by a membrane depolarization (approximately 4 mV), the presence of spontaneous action potentials, and a decreased spike threshold. CD was dependent on the frequency and intensity of vagal nerve stimulation. Two distinct types of CD were observed: 1) in NGNs with large input resistances (R(in)), CD was dependent on [Ca2+]o, associated with increased membrane conductance, and had an extrapolated reversal potential (E(rev)) value of about -25 mV; and 2) in NGNs with low R(in), CD was independent of [Ca2+]o, not accompanied by a membrane conductance change, or a measurable E(rev) value. These data reveal the existence of a chemical communication pathway between vagal afferent somata and suggest the possibility that communication between different visceral organs may occur at the level of the primary vagal afferent neuron.     

Raphe magnus inhibition of feline T1-T4 spinoreticular tract cell responses to visceral and somatic inputs

Background activity of spinoreticular tract neurons in the T1-T4 segments was on average inhibited 80% by electrical stimulation of nucleus raphe magnus. Nucleus raphe magnus stimulation inhibited responses of spinoreticular tract neurons to somatic input produced by touching the skin and hair (innocuous stimulus) or pinching the skin and muscle (noxious stimulus). Inhibition of responses to noxious and innocuous somatic inputs was not significantly different. Inhibition produced during nucleus raphe magnus stimulation was less effective when the activity of spinoreticular tract cells increased. This relationship was consistent for both background activity and responses to somatic noxious or innocuous input. Nucleus raphe magnus stimulation inhibited responses of spinoreticular tract neurons to visceral input produced by electrical stimulation of cardiopulmonary sympathetic afferent fibers. Responses to C-fiber sympathetic afferent fibers were more effectively inhibited than were responses to A-delta sympathetic afferent fibers. In conclusion, stimulation of the nucleus raphe magnus inhibits T1-T4 spinoreticular tract neuronal responses to visceral and somatic inputs. Since spinoreticular neurons project to the medullary reticular formation, activation of the nucleus raphe magnus could modulate affective-motivational behavior and cardiovascular adjustments that often occur during angina pectoris.     

Tonic descending influences on receptive-field properties of nociceptive dorsal horn neurons in sacral spinal cord of rat

1. Single-unit electrical activity has been recorded from 34 dorsal horn neurons in the sacral segments (S1-2) of the spinal cord in halothane-anesthetized rats. All of the neurons had cutaneous receptive fields (RFs) on the rat's tail. The neurons were classified according to their responses to both innocuous and noxious mechanical stimulation of their RFs. Twenty-five cells were driven by both innocuous and noxious skin stimulation (multireceptive or class 2), and 9 neurons were driven only by noxious skin stimulation (nocireceptive or class 3). 2. The RF size, mechanical threshold, and afferent input properties of these neurons were determined in the intact anesthetized and spinalized states. Reversible spinalization was achieved by cooling the cervical spinal cord to 4 degrees C. 3. The class 2 neurons had a mean RF size of 919.8 +/- 112.0 (SE) mm2 in the intact animal. Fourteen of the 25 class 2 cells had larger RFs in the spinal state (mean increase = 330.0 mm2, SE = 79.2) and so were under tonic descending inhibition. Five neurons, all with C-fiber input, had smaller RFs (mean decrease = 247.6 mm2, SE = 136.6) and higher mechanical thresholds in the spinal state and so were under tonic descending excitation. Six neurons were unaffected by spinalization. 4. Five class 3 neurons recorded in the superficial dorsal horn had small RFs in the intact animal (mean = 201.0 mm2, SE = 48.8) and showed little or no change in RF size on spinalization (mean increase = 33.4 mm2, SE = 16.7), but their mechanical thresholds did decrease, indicating weak tonic descending inhibition. In contrast, four class 3 neurons recorded in the deep dorsal horn had larger RFs in the intact animal (mean = 566.8 mm2, SE = 156.8), and were under strong tonic descending inhibition, because they had much larger RFs (mean increase = 461.0 mm2, SE = 68.3), lower mechanical thresholds, and stronger C-fiber afferent input in the spinal state. 5. We conclude that the majority of nociceptive dorsal horn neurons are subject to a net tonic descending control of their RF properties. The class 2 neurons in the deep dorsal horn appear to be a heterogeneous population, some cells being under tonic descending excitation and others under tonic descending inhibition. Class 3 cells can be separated into those located in the superficial dorsal horn, whose RF properties show very little change on spinalization, and those in the deep dorsal horn, whose RF properties change markedly on spinalization.(ABSTRACT TRUNCATED AT 400 WORDS)