Effect of a potent new aldose reductase inhibitor, (5-(3-thienyltetrazol-1-yl)acetic acid (TAT), on diabetic neuropathy in rats

(5-(3-Thienyl)tetrazol-1-yl)acetic acid (TAT), a novel potent aldose reductase inhibitor, was administered for 4 weeks to rats with streptozotocin-induced diabetes. Physiological and biochemical studies were subsequently conducted on rat nerve tissue and erythrocyte sorbitol content was estimated. Sciatic nerve blood flow (SNBF) was markedly lower (about 43.4%) in untreated diabetic (DC) rats than in non-diabetic controls (NC). A significant delay in caudal motor nerve conduction velocity (MNCV) and significantly higher glucose, sorbitol and fructose values were observed in the sciatic nerve, accompanied by a markedly higher sorbitol concentration in erythrocytes. In contrast, TAT-treated diabetic groups (DT-10, DT-40 and DT-200) had significantly higher SNBF, MNCV and sciatic nerve myo-inositol values and lower sciatic nerve sorbitol and fructose levels and erythrocyte sorbitol concentration than the DC group. There were good correlations between SNBF and MNCV (r = 0.672, P < 0.001) and between SNBF and erythrocyte sorbitol (r = 0.455, P < 0.003). These findings suggest that both vascular and metabolic factors play an important role in diabetic neuropathy and the effect of aldose reductase inhibitors on diabetic neuropathy may be mediated by at least these two factors.

Postnatal development of tail motoneurons and muscles in cat

The postnatal development of motoneurons in two tail muscles, the extensor caudae medialis (ECM) and extensor caudae lateralis (ECL), and that of ECL muscle fibers were studied in cats 1 week to 2 months old. The location of ECL and ECM motoneurons in cats of different ages did not change postnatally. Somal size (average of maximal and minimal diameters) of ECL and ECM motoneurons gradually increased, and the size distribution of ECL was bimodal at 2 months. The activities of succinate dehydrogenase (SDH) and phosphofructokinase (PFK) were studied to determine oxidative and glycolytic activities in ECL growth. SDH activity rapidly decreased between 1 week and 2 weeks of age, while PFK activities increased gradually.

Rat tail: a useful model for microvascular training

The rat femoral vessel model is widely used as the basic model for microvascular training; however, it offers only a limited number of anastomoses and vessel sizes. Rat tail vessels provide long length, almost as long as the tail; adequate diameters, from about 1 mm to 0.2 mm; as well as the economy and a convenient location for practicing microvascular anastomoses. It is also the best choice for anastomosing vessels smaller than 0.5 mm diameter. Using stored, frozen tails harvested from sacrificed rats of other projects makes it even more frugal and convenient. Hence, it is an ideal model for microvascular training. The related anatomy and dissecting method are described and discussed.

Pharmacological evidence for the involvement of endogenous alpha-MSH-like peptides in peripheral nerve regeneration

The possible involvement of alpha-MSH-like peptides in the regenerative response of peripheral nerves was investigated with a competitive antagonist of alpha-MSH, the synthetic hexapeptide [D-Trp7,Ala8,D-Phe10)alpha-MSH(6-11)-amide. Subcutaneous administration of the alpha-MSH antagonist during the first 10 days following sciatic nerve crush significantly decreased functional recovery as measured by the foot flick withdrawal test and the walking pattern analysis. Hypophysectomy delayed both the initial sprouting response and the outgrowth rate after major caudal nerve crush. When hypophysectomized rats were treated with the alpha-MSH antagonist, a further delay in initial sprouting was observed, whereas the outgrowth rate of nerve fibers was not affected. These results suggest that 1) endogenous alpha-MSH-like peptides stimulate nerve outgrowth following peripheral nerve injury and 2) alpha-MSH-like peptides derived from a source other than the pituitary may contribute to the physiological stimulus leading to sprouting.

Inhibition and facilitation of different nocifensor reflexes by spatially remote noxious stimuli

1. Noxious stimuli have been shown to produce a diffuse inhibition of nociresponsive neurons in the spinal and trigeminal dorsal horns. The present study sought to extend these electrophysiological studies of diffuse noxious inhibitory controls (DNIC) by determining the effect of a spatially remote noxious stimulus on behavioral measures of nociception. Changes in latency for hindpaw withdrawal and tail flick reflexes were measured in lightly halothane-anesthetized or awake, spinally transected rats before, during, and after application of a spatially remote noxious stimulus. 2. Surprisingly, in no case did application of a spatially remote noxious stimulus inhibit the hindpaw withdrawal reflex. The latency for this reflex was either reduced or did not change when the tail or contralateral hindpaw was placed in hot water (50 degrees C) or when a noxious pinch was applied to the ear. In contrast, the latency for the tail flick reflex was consistently increased when the hindpaw was placed in hot water. Both the hindpaw reflex facilitation and the tail flick reflex inhibition produced by a noxious conditioning stimulus were attenuated in spinally transected rats indicating supraspinal modulation of both reflexes. 3. In addition, and consistent with the work of others, placing the tail in hot water reduced the evoked activity of convergent neurons in both the trigeminal and lumbar spinal dorsal horns. Thus inhibition of the activity of nociresponsive neurons in the dorsal horn is consistent with inhibition of the tail flick reflex, but not with facilitation of the hindpaw withdrawal reflex.(ABSTRACT TRUNCATED AT 250 WORDS)

Pronounced changes in the activity of nociceptive modulatory neurons in the rostral ventromedial medulla in response to prolonged thermal noxious stimuli

1. Brain regions that inhibit nociception can be activated by various environmental stimuli, including prolonged noxious stimuli. The present study tested the effect of such a prolonged noxious stimulus on the activity of nociceptive modulatory neurons in the rostral ventromedial medulla (RVM). These neurons, called ON- and OFF-cells because of their respective burst and pause in activity associated with nocifensor reflexes, have been shown to facilitate and inhibit nociception, respectively. 2. Single-unit activity of ON- and OFF-cells was assessed in lightly halothane- or barbiturate-anesthetized rats exposed to prolonged noxious heat (50 degrees C water). This prolonged noxious stimulus caused an increase in ON-cell and a decrease in OFF-cell activity regardless of anesthetic (halothane or barbiturate) or stimulus location (hindpaw or tail). 3. Surprisingly, and despite the consistent changes in RVM cell activity, the prolonged noxious stimulus caused different effects depending on the reflex used to assess nociception. The hindpaw withdrawal reflex was facilitated when the tail was immersed in hot water, whereas the tail flick reflex was inhibited when the hindpaw was immersed in hot water (see preceding manuscript). Lidocaine inactivation of the RVM shortened the latency for both reflexes but had no effect on tail flick inhibition produced by the noxious conditioning stimulus. In contrast, lidocaine inactivation of the RVM completely reversed the hindpaw reflex facilitation produced by tail heat, indicating the involvement of RVM ON-cells in facilitation of this reflex. 4. These data demonstrate that RVM neurons respond in a consistent manner to noxious stimuli whether applied for a brief or prolonged time: ON-cell activity increases and OFF-cell activity decreases. Moreover, the activation of RVM ON-cells produced by a noxious stimulus is sufficient to enhance some nocifensor reflexes, whereas neural structures other than the RVM appear to mediate the antinociceptive effects produced by a prolonged noxious stimulus.

A behavioral model for peripheral neuropathy produced in rat's tail by inferior caudal trunk injury

We attempted to develop an experimental animal model using rat's tail for understanding the mechanisms involving peripheral neuropathic pain. Under sodium pentobarbital anesthesia, the left inferior caudal trunk of the rat was resected between the S3 and S4 spinal nerves. Latencies of tail-flick induced by the stimulus such as warm (40 degrees C) and cold (4 degrees C) water to the tail were measured for the following 30 weeks. In addition, sensitivity of the tail to mechanical stimulation was tested with von Frey hairs on these rats. Operated rats showed abnormal sensitivity of the tail to normally innocuous mechanical and thermal (warm and cold) stimuli. We interpreted these results as signs of neuropathic pain following nerve injury. The present model offers several advantages in performing behavioral tests; (1) it is easy to apply thermal stimulation to the rat's tail using a water bottle; (2) it is easy to apply the mechanical stimulation with von Frey hairs and to localize sensitive areas in the tail; and (3) blind behavioral studies are possible due to the lack of deformity in the tail after surgery.

Vascular responses to neuropeptide Y in the rat: effect of age

Neuropeptide Y (NPY) is co-released with norepinephrine (NE) from sympathetic neurons, which innervate blood vessels, and acts to potentiate NE-induced smooth muscle contraction. This study sought to determine if vascular levels of NPY-like immunoreactivity or the contractile effects of NPY are altered by age in segments of isolated blood vessels from Fischer 344 and Brown Norway-F344-F-1 rats. Tissue extracts of femoral and tail arteries of Fischer 344 rats, aged 6, 12, 20, and 24 months, were analyzed for NPY content by radioimmunoassay. Neither blood vessel showed a significant age-related difference in NPY content. Contractile responses of the tail artery to adrenergic transmural nerve stimulation (TNS) were compared in the same age groups. No significant age-related differences in contractile responses to TNS were observed in either rat strain. NPY, at concentrations of 1 and 10 nM, both potentiated and prolonged the contractile response to TNS; 6-month-old F-344 rats were significantly less responsive to the effects of NPY. However, advancing age from 12 to 24 months did not alter the responses to NPY in either rat strain. We conclude that an age-dependent increase in the contractile responses to NPY occurs from age 6 to 12 months, and this responsiveness to NPY is maintained through senescence.

The onset of response habituation during the growth of the lateral giant neuron of crayfish

1. The postembryonic development of the crayfish LG tailflip command neuron's response to mechanosensory input was studied with standard electrophysiological techniques in animals between 1 and 12 cm long. 2. LG neurons are present in each abdominal hemisegment where they receive direct and indirect excitatory input from mechanosensory afferents. In both small and large crayfish, electrical stimulation of an abdominal ganglionic nerve containing those afferents evoked a compound excitatory postsynaptic potential (EPSP) with an early, reliable alpha component and a later, depression-prone beta wave. It is known that the alpha and beta components are produced by inputs from primary mechanosensory afferents and interneurons, respectively. 3. In crayfish < 2 cm long, LG was excited by the alpha component. When superthreshold, the alpha component triggered a single spike; additional excitation provided by the later beta wave presumably was preempted by refractoriness following the alpha spike and by recurrent inhibition of LG excited by the spike. LG was excited reliably by the alpha component in response to repeated superthreshold stimulation. 4. In crayfish between 2 and 3 cm, LG was excited more readily by the beta wave than by the alpha component. LG's beta spike response habituated to repeated stimulation at 1 Hz, and the beta EPSP depressed whereas the alpha component was largely unchanged. The appearance of the cellular substrates of habituation correlates with the reported onset of behavioral habituation of the tailflip response. Higher stimulus levels brought the alpha EPSP to threshold. Repetitive stimulation at these levels reliably evoked LG spikes from the alpha EPSP.(ABSTRACT TRUNCATED AT 250 WORDS)

Central delay of the laser-activated rat tail-flick reflex

The latency of the heat-activated rat tail-flick (TF) reflex is dependent upon 4 variables, none of which has previously been determined: activation of cutaneous nociceptors (TN); afferent conduction to the dorsal horn (TA); conduction within the central nervous system (CNS) (central delay); and conduction from the ventral horn (VH) to, and activation of, tail muscles (TE). Using a CO2 infrared laser (10 W, 45 msec) to produce synchronous activation of tail-skin nociceptors, TF latency (EMG response) was measured in 10 awake rats. Based on shifts in response latency from points of stimulation near the tip and base of the tail, conduction velocity in the afferent limb of the reflex was estimated to be 0.76 +/- 0.11 m/sec. This indicates that the response is mediated by C fibers. The rats were then anesthetized with pentobarbital and multiple-unit activity and evoked potentials (EPs) were recorded from the superficial dorsal horn at spinal segments S3-CO1 during laser or high-intensity electrical (10 mA, 1 msec) stimulation of the tail. Unit activity and EPs elicited by both stimuli consisted of two distinct components, corresponding to activation of A and C fibers. The difference in latency between laser and electrical evoked activity indicated that 60.00 +/- 7.33 msec was required for activation of nociceptors by the laser. Electrical stimulation of the VH at S3-CO1 in 3 rats produced a TF (EMG) response in 4 msec. Central delay, calculated as total TF time minus (TN+TA+TE), was 82.3 +/- 13.08 msec. This represents the time frame during which modulation of the reflex by an intrinsic, pain-activated, supraspinal system could occur.

Effects of cyclic GMP and analogues on neurogenic transmission in the rat tail artery

1. The effects of membrane permeable analogues of guanosine 3':5'-cyclic monophosphate (cyclic GMP), and of the NO donor, 3-morpholinosydnonimine-N-ethylcarbamide (SIN-1) were investigated on [3H]-noradrenaline release and neurogenic vasoconstriction in electrical field stimulated rat tail arteries. 2. Two 8-substituted analogues of cyclic GMP (8-bromoguanosine 3':5'-cyclic monophosphate; 8-bromo-cyclic GMP and 8-(4-chlorophenylthio)-guanosine 3':5'-cyclic monophosphate; 8-pCPT-cyclic GMP) concentration-dependently enhanced stimulation-induced [3H]-noradrenaline release. These prejunctional effects were antagonized by the cyclic AMP-dependent protein kinase (PKA) inhibitor N-[2-((3-(4-bromophenyl)-2-propenyl)-amino)-ethyl]-5 isoquinolinesulphonamide dihydrochloride (H-89; 100 nM) but not by the cyclic GMP-dependent protein kinase (PKG) inhibitors, Rp-8-bromoguanosine 3':5'-cyclic monophosphorothioate (Rp-8-bromo-cyclic GMPS; 10 microM) or Rp-8-(4-chlorophenylthio)-guanosine 3':5'-cyclic monophosphorothioate (Rp-8-pCPT-cyclic GMPS; 10 microM). 3. beta-Phenyl-1,N2-ethenoguanosine 3':5'-cyclic monophosphate (PET-cyclic GMP) had no effect on stimulation-induced [3H]-noradrenaline release but concentration-dependently decreased the stimulation-induced vasoconstriction. 4. The two 8-substituted cyclic GMP derivatives, PET-cyclic GMP and SIN-1, both decreased stimulation-induced vasoconstriction. In addition, SIN-1 relaxed rat tail arteries precontracted with phenylephrine (1 microM). The SIN-1 concentration-relaxation curve was shifted in parallel manner to the right by Rp-8-bromo-cyclic GMPS (10 microM) and Rp-8-pCPT-cyclic GMPS (10 microM) with no change in the maximum effect, showing that the relaxation was mediated by a cyclic GMP/PKG-dependent mechanism. 5. It is concluded that PKA activation is involved in the noradrenaline release enhancing effect of the two 8-substituted cyclic GMP analogues, whereas a cyclic GMP/PKG-operated pathway accounts for the inhibitory effects of the cyclic GMP and its analogues on vascular smooth muscle contraction.

Identification and characterization of pleural neurons that inhibit tail sensory neurons and motor neurons in Aplysia: correlation with FMRFamide immunoreactivity

Neurons on the rostral edge of the ventral surface of the right pleural ganglion were identified as elements of the circuit mediating the defensive tail withdrawal reflex of Aplysia. These neurons produced IPSPs in tail sensory neurons and were classified into two groups, RPI4 and RPI5, according to their affinity for an antibody directed against FMRFamide. RPI4 was not FMRFamide immunoreactive, and RPI5 was. RPI4 and RPI5 were found to have different electrophysiological profiles. The summated IPSPs in sensory neurons produced by RPI4 developed more rapidly and had a shorter duration than those produced by RPI5. In addition, RPI4 produced IPSPs in the tail motor neurons, whereas RPI5 did not. Both RPI4 and RPI5 received excitatory synaptic inputs from stimulation of the pleural-abdominal connective as well as peripheral nerves P8 and P9, which innervate the tail and posterior part of the animal's body. These inputs were sufficient to elicit spikes. In RPI4, the excitatory synaptic inputs were followed by short and transient hyperpolarization, whereas in RPI5, the excitatory synaptic inputs were followed by slow and long-lasting hyperpolarization. Excitatory inputs elicited in RPI4 by stimulation of peripheral nerves appeared to be mediated, at least in part, by activation of tail sensory neurons. Intracellular stimulation of sensory neurons produced EPSPs in RPI4 that appeared to be monosynaptic. These results suggest that inhibitory interneurons underlying the circuit of the tail withdrawal reflex may play roles in mediating or modulating neuronal responses to tail stimulation. By inhibiting tail sensory and motor neurons, these interneurons may reduce the effectiveness of an animal's response to stimulation of the tail.

Sympathetic activity recorded from the rat caudal ventral artery in vivo

1. In twenty-five sodium pentobarbitone (alpha-chloralose supplemented)-anaesthetized, artificially ventilated and paralysed rats, postganglionic sympathetic single unit activity was recorded at the level of the adventitia of the caudal ventral artery of the tail using a focal recording technique. 2. Ten units were identified as being sympathetic in nature, as they were activated following electrical stimulation of the lumbar sympathetic chain. The on-going activity of seven of these was blocked by hexamethonium (6-12 mg kg-1). 3. The units were not under tonic baroreceptor modulation, as indicated by the lack of pulse modulation of discharge. Respiratory modulation was apparent, with neurones firing mainly during expiration (phrenic silence), and activity was influenced also by the lung inflation cycle. Whole-body warming decreased unit activity. 4. Interspike interval and autocorrelation analysis showed that unit discharge was dominated by the respiratory rhythm and that units tended to discharge in bursts (often duplets). It is suggested that the intraburst interval may be determined by a hypothetical sympathetic oscillator. 5. This study presents the first analysis of single unit activity recorded in vivo from sympathetic fibres innervating an identified blood vessel.

Assessing pain threshold in the rat: changes with estrus and time of day

Pain threshold was determined in female rats using the tail flick test. Latency to respond depended on the locus of the tail heated, with the most distal sites resulting in the shortest response times (Experiment 1). Tail flick latency also varied according to the time of day, with shorter response times recorded around the middle of the dark phase than near its beginning or after its end. This was the case for intact, for ovariectomized, and for ovariectomized, estradiol-treated rats (Experiment 2). However, response times also varied across the estrous cycle, with significantly shorter latencies recorded during estrus and metestrus. Ovariectomy abolished these fluctuations, and whereas administration of estradiol increased response times, progesterone had little effect (Experiment 3). These results suggest that site of tail heating, time of day, and presence of ovarian hormones can influence tail flick latency independently, thus demonstrating the complexity of the mechanisms that may contribute to pain threshold even within the same paradigm.

[Indapamide decreases the sensitivity of the rat tail artery to sympathetic actions and the administration of an alpha 2-adrenoreceptor agonist]

Indapamide was studied for effects on the constrictor responses of the isolated rat tail artery by using the method of "ex vivo" tail artery perfusion with blood from the awake donor rat. In acute experiments, indapamide, 3 mg/kg i. v., significantly decreased the magnitude of the electrical stimulation-induced constrictor responses of the rat tail artery. They were 77.5% (constrictor responses as % of the initial level of perfusion pressure) before indapamide injection and 37.2 and 30.2% at min 30 and 90 min after indapamide injection, respectively. In chronic experiments (15-day treatment with oral indapamide) there was a significant decrease in constrictor responses to alpha 2-agonist injected.

Hypoalgesia in response to sensitization during acute noise stress

Three experiments examined the antinociceptive response shown by rats during exposure to loud noise. Noise exposure resulted in a time-dependent elevation of radiant heat tail flick latency that varied as a function of stimulus intensity. Noise stress hypoalgesia in response to a 90-dB stimulus was blocked by pretreatment with the opioid antagonist naltrexone (0.1-7.0 mg/kg). Systemic administration of midazolam (2 mg/kg) prior to exposure to the stressor attenuated the elevation in tail flick latency. Because topographically similar antinociceptive responses may be elicited with a low intensity noise stimulus that has served as a Pavlovian conditional stimulus for shock, the use of this paradigm may permit direct comparisons of associative and nonassociative fear responses using qualitatively similar auditory stimuli.

Inability of insulin to maintain normal nerve function during high-frequency stimulation in diabetic rat tail nerves

The effect of insulin on the response to long-term high-frequency stimulation (HFS = 143 Hz for 20 min) was studied in mixed tail nerves of acute streptozotocin-induced diabetic rats. In consecutive tests, untreated diabetic rats showed a significant decrease in nerve conduction velocity (NCV) and peak-to-peak amplitude (P-Pamp) and the depression of the P-Pamp during HFS was augmented. In contrast, NCV and P-Pamp in the insulin-treated rats were unchanged from the prediabetic state, but the depression of the P-Pamp during HFS reached the same degree as in untreated rats. This implies that although insulin treatment of acute experimental diabetes is able to preserve a normal NCV and P-Pamp in the resting state, it is unable to preserve normal nerve function under stress produced by HFS. Monitoring of the axon membrane functional capacity may have clinical implications in the control of peripheral neuropathies.

Modality-specific hypersensitivity of dorsal horn convergent neurones during reperfusion of their receptive fields on the rat's tail

In rats anaesthetised with enflurane, we examined the responses of convergent neurones in the dorsal horn of the spinal cord to noxious thermal and mechanical stimulation and to innocuous brushing, during reperfusion of their receptive fields on the tail, following transient ischaemia. Neurones were included if they responded, before induction of ischaemia, to both pinching and brushing of receptive fields restricted to the tail. Ischaemia was induced by occluding the blood supply to the tail for 30 min using a tourniquet. Compared to their own responses before ischaemia, during reperfusion almost all the neurones (17 of 20) exhibited significantly increased activity to noxious pinching and innocuous brushing of their receptive fields, following 30 and 60 min of reperfusion. Receptive field size increased markedly in 16 of 20 of the neurones tested. Only 13 of 35 of the neurones responded to noxious thermal stimulation of the tail before induction of ischaemia, and of these only two exhibited enhanced sensitivity to thermal stimulation during reperfusion. Our results indicate that there is a population of convergent neurones that demonstrates hypersensitivity to mechanical stimulation of the rat's tail, but not to noxious thermal stimulation, during reperfusion of their receptive fields following transient ischaemia.

The role of interneurons in controlling the tail-withdrawal reflex in Aplysia: a network model

1. The contributions of monosynaptic and polysynaptic circuitry to the tail-withdrawal reflex in the marine mollusk Aplysia californica were assessed by the use of physiologically based neural network models. Effects of monosynaptic circuitry were examined by the use of a two-layer network model with four sensory neurons in the input layer and one motor neuron in the output layer. Results of these simulations indicated that the monosynaptic circuit could not account fully for long-duration responses of tail motor neurons elicited by tail stimulation. 2. A three-layer network model was constructed by interposing a layer of two excitatory interneurons between the input and output layers of the two-layer network model. These interneurons had properties mimicking those of the recently described interneuron LP117, receiving excitatory input from pleural sensory neurons and evoking a biphasic excitatory postsynaptic potential (EPSP) in pedal motor neurons (Cleary and Byrne 1993). The three-layer model could account for long-duration responses in motor neurons. 3. Sensory neurons are a known site of plasticity in Aplysia. Synaptic plasticity was incorporated into the three-layer model by altering the magnitudes of conductance changes evoked in motor neurons and interneurons by presynaptic sensory neurons. In these simulations the excitatory interneurons converted an amplitude-coded input into an amplitude- and duration-coded output, allowing the three-layer network to support a large range of output amplitudes and durations. 4. Synaptic plasticity at more than one locus modified dramatically the input-output relationship of the three-layer network model. This feature gave the model redundancy in its plastic properties and points to the possibility of distributed memory in the circuitry mediating withdrawal reflexes in Aplysia. Multiple sites of control over the response of the network would likely allow a more diverse repertoire of responses.

Identification and characterization of a multifunction neuron contributing to defensive arousal in Aplysia

1. The tail withdrawal reflex is mediated by a monosynaptic circuit composed of tail sensory and motor neurons, but there appear to be additional neuronal elements that also contribute to the reflex. A newly identified interneuron, called LP117, was located in the pleural ganglion. This neuron formed a parallel excitatory pathway between sensory and motor neurons. The distinguishing feature of LP117 was its ability to elicit a long-lasting (5-100 s) excitatory postsynaptic potential (EPSP) in the motor neuron. 2. Intracellular labeling of LP117 revealed axons projecting to the cerebral and abdominal as well as the pedal ganglia. Simultaneous intracellular recordings confirmed the widely divergent output of LP117 to tentacle motor neurons in the cerebral ganglion, as well as to gill, siphon, and ink motor neurons in the abdominal ganglion. 3. Also receiving input were abdominal neurons L29, which excites LFs motor neurons and facilitates LE sensory neurons, and L25, which is part of the pattern-generating network underlying respiratory pumping. Thus LP117 appears to be a neural element important for the conduction of information about tail stimulation to ganglia that are not innervated by tail sensory neurons themselves. Moreover, the divergent outputs suggest that LP117 is an element of a neural circuit underlying defensive arousal. 4. LP117 produced slow EPSPs in several motor neurons. The long time course of the EPSP could prolong the burst in the motor neuron produced by LP117 itself as well as increase the effectiveness of coincident synaptic input. This suggests that an important function of this interneuron is to extend the duration of the response to tail stimulation in the motor neuron. This could account for the relatively long time course of the motor neuron response to tail stimulation compared with that of the sensory neuron. 5. Sensitization is a form of nonassociative learning that produces changes in the amplitude and duration of reflex responses. It seems unlikely that all of these changes can be attributed to enhanced amplitude of the sensory-motor synapse, however. Therefore LP117 may itself be a site of plasticity for reflexes elicited by tail stimulation.

Rat tail flick reflex: magnitude measurement of stimulus-response function, suppression by morphine and habituation

1. To quantitatively investigate a nocifensive behavioral response, we developed a method to measure the magnitude of the rat's tail flick reflex and its modulation. A radial array of force transducers measured forces of tail flicks (in rostral, horizontal, and vertical planes) elicited by graded noxious radiant thermal stimulation of the conscious rat's tail, from which the overall movement vector was calculated. 2. The rostrally directed component of tail flicks was always larger than dorsal or horizontal components; the latter was usually in a preferred (left or right) direction regardless of which side of the tail was heated. Tail flick force vectors increased from 40 to 46-52 degrees C and then leveled off. Stimulus-response functions were reproducible within and across rats and were fitted by second-order polynomial functions, whose correlation coefficients were similar when the left or right side of the tail was stimulated in separate sessions (r2 = 0.408 and 0.451, respectively). The inverse latency of tail flicks also increased with temperature in a manner fitted by a second-order polynomial (r2 = 0.707, 0.553 for left and right side, respectively). 3. Systemic administration of morphine (1 or 2 mg/kg ip) usually suppressed tail flicks in an all-or-none manner; i.e., flicks at all stimulus temperatures were either totally abolished (n = 7) or unaffected (n = 5) after morphine. In three rats, 1 mg/kg morphine suppressed tail flick magnitude subtotally, reducing the slope of the linear portion of the stimulus-response function. Morphine effects were reversed by the opiate antagonist naloxone. 4. Tail flick magnitude decreased over repeated trials of 44 degrees C heat stimuli delivered to one tail site, recovered after a 15-min rest period, and decremented more quickly with subsequent stimulus repetition. The decrement was less at long (2 or 4 min) than at short (1 min) interstimulus intervals, and high (50 degrees C) than at low (44 degrees C) stimulus intensities. The reflex decrement transferred to a nearby stimulus site in some rats, and was "dishabituated" after a noxious tail pinch. These observations are consistent with habituation of the tail flick reflex. 5. This method, therefore, provides a quantitative and reproducible measure of tail flick reflex magnitude that is sensitive to morphine. The underlying neural circuitry of the tail flick reflex is discussed in relation to limb withdrawal reflexes.

Electrical stimulation as a substitute for the tail clamp in the determination of minimum alveolar concentration

Circumstances may preclude the use of standard stimuli, namely tail clamp or surgical incision, to determine minimum alveolar concentration. In rats anesthesized with isoflurane, an alternative stimulus, electrical currents (10, 15, 20, or 40 V; biphasic pulses of 6.5 ms duration; 50 Hz), gave results comparable to those obtained with the tail clamp and the results did not change with repeated measurements if care was taken to avoid desensitization by exhaustion of a particular set of electrodes. The 40 V stimulation gave slightly higher values (4%; P < 0.006) than tail clamp, but the difference was too small to be of experimental significance. More importantly, the higher voltages produced desensitization after fewer attempts at stimulation. In addition to these results with isoflurane, we found that 15 V stimulation and tail clamp produced comparable minimum alveolar concentration values for halothane and for desflurane.

Activation of the opioid and nonopioid hypoalgesic systems at the level of the brainstem and spinal cord: does a coulometric relation predict the emergence or form of environmentally induced hypoalgesia?

Prior research suggests that a coulometric relation (Intensity x Duration) determines whether an opioid or nonopioid hypoalgesic system is activated by afferent nociceptive information. Using a paradigm that generates a brainstem-mediated hypoalgesia on the tail-flick test, we found that a coulometric relation does not predict either the emergence or the form of shock-induced hypoalgesia in decerebrate rats. In fact, no evidence was obtained that the brainstem's opioid hypoalgesic system can be activated by ascending neurons. More severe shocks elicited hypoalgesia in spinalized rats. Although a coulometric relation did not predict the emergence of hypoalgesia in spinalized rats, shock severity did predict the form of the hypoalgesia; the least severe shocks elicited an opioid hypoalgesia, and the more severe shocks generated a nonopioid hypoalgesia. A similar pattern of data was observed in intact rats exposed to the least severe shock parameters.

Pharmacological characterization of the effects of 5-hydroxytryptamine and different prostaglandins on peripheral sensory neurons in vitro

The excitatory and sensitizing properties of 5-HT and different prostaglandins (PGD2, PGE1, PGE2, PGF2 alpha, PGI2 and PGI2-analogue, cicaprost) were characterized on an in vitro preparation of the neonatal rat spinal cord with functionally attached tail. Prolonged (10 min) perfusion of the tail with 5-hydroxy-tryptamine (5-HT, 0.5-10 microM) or any of the tested prostaglandins (0.1-5 microM) did not evoke an excitatory response recorded from a lumbar ventral root, but significantly enhanced responses of peripheral nociceptors to thermal and chemical (bradykinin, capsaicin) stimuli. PGD2 did not induce such an enhancement. Following sensitization of peripheral nociceptors with low concentrations of bradykinin or capsaicin, 5-HT (1-10 microM) evoked a ventral root response. Using specific 5-HT-receptor agonists and antagonists, 5-HT-evoked excitation was determined to be mediated via a 5-HT1-like receptor while 5-HT-induced sensitization involved 5-HT2 receptors.

Sensitization of peripheral afferent fibres in the in vitro neonatal rat spinal cord-tail by bradykinin and prostaglandins

The sensitization of peripheral nociceptors by different prostaglandins was studied in an in vitro preparation of the neonatal spinal cord with functionally attached tail. Nociceptors in the rat tail were activated by chemical (bradykinin, capsaicin) and thermal (heated saline) stimuli and responses were recorded as a depolarization of a ventral root in the lumbar region of the spinal cord (L3-L5). Responses evoked by bradykinin, capsaicin or submaximal thermal stimulation were enhanced in the presence of prostaglandin E1, prostaglandin E2, prostaglandin F2 alpha, prostaglandin I2 and the stable prostaglandin I2 analogue cicaprost, but not by prostaglandin D2. Cyclic AMP and threshold concentrations of bradykinin also induced an enhancement of responses to chemical and thermal stimuli. Responses evoked by small concentrations of bradykinin on unsensitized preparations were reduced by indomethacin or aspirin, whereas responses to maximal concentrations of bradykinin were not affected. Immunocytochemical localization of protein gene product 9.5 and growth associated protein 43 indicated that the neuronal innervation of subepidermal skin layers was preserved in the tail following removal of the most superficial skin layers which was performed in order to facilitate drug access to peripheral nerve endings. These results indicate that different prostaglandins and cyclic AMP sensitize peripheral nerve endings to noxious stimulation without directly activating nociceptors. The stimulation of nociceptors by bradykinin was only partially mediated via arachidonic acid metabolites whereas bradykinin-induced sensitization was independent of cyclo-oxygenase activity.