Enhanced Responses of Spinal Dorsal Horn Neurons to Heat and Cold Stimuli Following Mild Freeze Injury to the Skin

Sergey G. Khasabov,1 David M. Cain,2 Dinh Thong,3 Patrick W. Mantyh,1 and Donald A. Simone2,3

 1Department of Preventive Science,  2Department of Oral Science, and  3Department of Psychiatry, Schools of Dentistry and Medicine, University of Minnesota, Minneapolis, Minnesota 55455


    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Khasabov, Sergey G., David M. Cain, Dinh Thong, Patrick W. Mantyh, and Donald A. Simone. Enhanced Responses of Spinal Dorsal Horn Neurons to Heat and Cold Stimuli Following Mild Freeze Injury to the Skin. J. Neurophysiol. 86: 986-996, 2001. The effects of a mild freeze injury to the skin on responses of nociceptive dorsal horn neurons to cold and heat stimuli were examined in anesthetized rats. Electrophysiological recordings were obtained from 72 nociceptive spinal neurons located in the superficial and deep dorsal horn. All neurons had receptive fields (RFs) on the glabrous skin of the hindpaw, and neurons were functionally divided into wide dynamic range (WDR) and high-threshold (HT) neurons. Forty-four neurons (61%) were classified as WDR and responded to both innocuous and noxious mechanical stimuli (mean mechanical threshold of 12.8 ± 1.6 mN). Twenty-eight neurons (39%) were classified as HT and were excited only by noxious mechanical stimuli (mean mechanical threshold of 154.2 ± 18.3 mN). Neurons were characterized for their sensitivity heat (35 to 51°C) and cold (28 to -12°C) stimuli applied to their RF. Among WDR neurons, 86% were excited by both noxious heat and cold stimuli, while 14% responded only to heat. For HT neurons, 61% responded to heat and cold stimuli, 32% responded only to noxious heat, and 7% responded only to noxious cold. Effects of a mild freeze injury (-15°C applied to the RF for 20 s) on responses to heat and cold stimuli were examined in 30 WDR and 22 HT neurons. Skin freezing was verified as an abrupt increase in skin temperature at the site of injury due to the exothermic reaction associated with crystallization. Freezing produced a decrease in response thresholds to heat and cold stimuli in most WDR and HT neurons. WDR and HT neurons exhibited a mean decrease in response threshold for cold of 9.0 ± 1.3°C and 10.0 ± 1.6°C, respectively. Mean response thresholds for heat decreased 4.0 ± 0.4°C and 4.3 ± 1.3°C in WDR and HT neurons, respectively. In addition, responses to suprathreshold cold and heat stimuli increased. WDR and HT neurons exhibited an 89% and a 192% increase in response across all cold stimuli, and a 93 and 92% increase in responses evoked across all heat stimuli, respectively. Our results demonstrate that many spinal neurons encode intensity of noxious cold as well as noxious heat over a broad range of stimulus temperatures. Enhanced responses of WDR and HT neurons to cold and heat stimuli after a mild freeze injury is likely to contribute to thermal hyperalgesia following a similar freeze injury in humans.


    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Unlike most somatosensory modalities, relatively little is known regarding the neural mechanisms that underlie the sensations of cold pain and cold-evoked hyperalgesia following injury. Previous studies of the spinal cord have demonstrated that many nociceptive neurons, both wide dynamic range (WDR) and high-threshold (HT) cells in the superficial and deep dorsal horn, are excited by cold stimuli and can, in addition to encoding the intensity of noxious heat stimuli, respond to noxious cold stimuli to 0°C (Craig and Bushnell 1994; Craig and Serrano 1994; Dado et al. 1994; Ferrington et al. 1987; Kenshalo et al. 1982). However, the capacity of WDR and HT neurons to encode the intensity of noxious cold over a wide range of stimulus temperatures, including those below 0°C, has not been explored. Two lines of evidence support the hypothesis that dorsal horn neurons can encode the intensity of cold at temperatures well below 0°. First, intensity-dependent c-Fos expression is observed in the superficial and deep dorsal horn of the rat spinal cord in response to cold stimuli of approximately -15°C and below applied to the hindpaw (Abbadie et al. 1994a; Doyle and Hunt 1999). Second, subpopulations of Adelta and C-fiber cutaneous nociceptors in the rat are excited by noxious cold (LaMotte and Thalhammer 1982; Saumet et al. 1985) and can encode the intensity of cold at stimulus temperatures well below 0°C (Simone and Kajander 1996, 1997). We therefore hypothesized that this encoding capacity is conserved in response properties of nociceptive spinal neurons to noxious cold stimuli extending well below 0°C.

Hyperalgesia, defined as a decrease in pain threshold and increased pain to normally painful stimuli, often follows tissue injury and inflammation. Although hyperalgesia is mediated in part by sensitization of nociceptors at the site of injury, sensitization of spinal dorsal horn neurons also contributes to hyperalgesia (see reviews; Baranauskas and Nistri 1998; Millan 1999; Treede et al. 1992). Hyperalgesia to cold as well as to heat and mechanical stimuli occurs following a mild freeze injury to the skin (Beise et al. 1998; Kilo et al. 1994; Lewis and Love 1926). Interestingly, freeze injury to the skin evokes a well-defined sensation of pricking/stinging pain at the time of freezing, and the ensuing cold hyperalgesia is characterized by decreased cold pain threshold and a change in the quality of pain from a cold aching sensation to a burning sensation. It is unknown whether responses of HT and WDR neurons evoked by cold stimuli are enhanced following freeze injury. Therefore the second aim of this study was to determine the response characteristics of nociceptive spinal neurons at the time of cold injury to the skin and whether responses evoked by cold and heat stimuli are facilitated following a freeze injury. Preliminary results have been reported (Khasabov et al. 1999).


    METHODS
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects

Fifty-seven adult male Sprague-Dawley rats (Harlan Industries, Indianapolis, IN) weighing 290-470 g were housed in pairs on a 12:12 h light-dark cycle. Food and water were provided ad libitum. All animal procedures were approved by the Animal Care Committee at the University of Minnesota, and experiments were conducted according to the guidelines set forth by the International Association for the Study of Pain.

Surgical preparation

Rats were anesthetized by injection of ketamine (100 mg/kg) and acepromazine (45 mg/kg). The trachea was cannulated to provide unobstructed ventilation, and a catheter was inserted into the external jugular vein for supplemental anesthesia with pentobarbital sodium (5-10 mg · kg-1 · h-1). Areflexia was maintained by monitoring the corneal reflex at frequent intervals throughout the experiment. Also, there were no withdrawal responses to mild pinching of the hind paw. The carotid artery was cannulated and blood pressure was monitored with a pressure transducer. Experiments were terminated if mean pressure dropped below 60 mmHg. Core body temperature was maintained at 37-38°C by a feedback-controlled heating pad. After shaving the hair over the midline of the animal's back, an incision was made preceding a blunt dissection of the muscles and connective tissue to expose the vertebral column. The animal was secured within a stereotaxic frame, and the lumbar enlargement was exposed by laminectomy. The spinal cord was continually bathed in a pool of warm (37°C) mineral oil.

Electrophysiological recording

Extracellular recordings of single dorsal horn neurons with receptive fields (RFs) located on the plantar surface of the hindpaw were obtained using stainless steel microelectrodes (Frederick Haer, Brunswick, ME). Recording electrodes were lowered into the spinal cord using an electronic micromanipulator (Burleigh) in 5-µm steps. Recordings were made only from single neurons whose amplitude could be easily discriminated. Electrophysiological activity was amplified, audio-monitored, and displayed on an oscilloscope before being sent to a computer for data collection using a customized version of Lab View (National Instruments, Austin, TX) software that enabled storage of raw data, discriminated impulses, and stimulus temperature.

Functional classification of spinal neurons

Search stimuli consisted of mechanical stimulation (stroking the skin and mild pinching with the experimenter's fingers) of the rat hindpaw. The RFs of isolated neurons were mapped with a supratheshold von Frey monofilament. Each spinal neuron was characterized based on its response to graded intensities of mechanical stimulation applied to the RF. Innocuous stimuli consisted of stroking the skin with a cotton swab. Noxious stimulation included mild pinching with the experimenter's fingers and with serrated forceps, but this latter stimulus was applied sparingly to avoid neuronal sensitization. Neurons were classed functionally according to responses evoked by mechanical stimuli as 1) low-threshold (LT) if they were excited maximally by innocuous stimulation, 2) wide dynamic range (WDR) if they responded in a graded fashion to increasing intensity of stimulation, and 3) high-threshold (HT) if responses were evoked by noxious stimulation only. Only WDR and HT neurons were studied.

Thermal stimulation

All thermal stimuli were applied by a feedback-controlled Peltier device (contact area of 1 cm2) to RFs located on the plantar surface of the hindpaw. A series of nine heat stimuli from 35 to 51°C (each with a duration of 5 s) was delivered in ascending steps of 2° increments. The rise/fall rate for each heat stimulus was 18°C/s. An interval of 60 s occurred between each pair of heat stimuli.

A series of 11 cold stimuli was applied in descending increments of 4° from 28 to -12°C. Cold stimuli were each delivered with a rise/fall rate of 5°C/s and applied for 10 s. The interstimulus interval was 180 s. The baseline temperature for both heat and cold stimuli was 32°C.

Experimental design

Following identification and general functional characterization of a neuron as WDR or HT, the RF was mapped by stroking and mildly pinching with forceps and outlined on the skin with a felt-tip pen. Mechanical threshold (mN) was determined using calibrated von Frey monofilaments applied to the most sensitive area of the RF. Before the freeze injury, heat stimuli were applied first followed after 10 min by cold stimuli. At 10 min following freeze injury produced by -15°C applied for 20 s, cold stimuli and then heat stimuli were reapplied to the RF. Freezing of the skin was documented by an abrupt increase in skin temperature at the site of injury due to the exothermic reaction associated with crystallization (Beise et al. 1998). In most experiments one neuron was studied on each side of the spinal cord. After each cell was studied the recording site was marked by passing current (20 µA for 20 s) through the recording electrode.

Histology

At the end of each experiment, animals received an overdose of pentobarbital sodium and were perfused with normal saline followed by 10% Formalin containing 1% potassium ferrocyanide. Serial transverse sections (50 µm) were stained with neutral red. Recording sites were identified by Prussian Blue marks or by small lesions.

Data analysis

Electrophysiological responses were recorded on videotape and analyzed off-line with the use of a customized LabView software and a computer interface. Discriminated responses and raw spike data were stored as retrievable events on a laboratory computer. To assess responses evoked by thermal stimuli, spontaneous activity was measured for a period of 10 s before each thermal stimulus and was subtracted from the response evoked during (and for 10 s after) each thermal stimulus. Comparisons between WDR and HT neurons in mean response thresholds for mechanical, cold, and heat stimuli were made using Student's t-tests. Paired t-tests were used to determine the effect of cold injury on response thresholds of WDR and HT neurons. Responses evoked by suprathreshold cold and heat stimuli before and after injury were compared using two-way ANOVAs with repeated measures. Post hoc comparisons between mean responses evoked by individual stimulus temperatures before and after injury were made using the Tukey test. For each neuron, the total sum of impulses evoked by the full range of heat or cold stimuli was calculated. The mean sums of impulses of WDR and HT neurons evoked by heat or cold stimulation were compared using paired t-tests.

To further determine effects of cold injury on stimulus-response relationships for heat and cold stimuli, power functions were generated for each neuron before and after injury. Thermal stimuli were normalized by defining a "zero point" as the highest stimulus temperature that did not evoke a response. Stimulus intensities were defined as the difference in intensity from the zero point. For example, since cold stimuli were delivered in increments of 4°C, the threshold intensity was assigned an intensity of 4°C, and the subsequent stimulus was assigned an intensity of 8°C, and so on. After log-log transformation, slopes of stimulus-response functions between WDR and HT neurons before and after injury were compared using Student's t-tests. A probability value of 0.05 was considered significant for all statistical analyses. Data are presented as means ± SE unless stated otherwise.


    RESULTS
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

General characteristics of WDR and HT neurons

A total of 72 thermal-sensitive dorsal horn neurons with RFs located on the glabrous surface of the hindpaw were selected for study. Forty-four neurons (61%) were classified as WDR and were excited by both innocuous and noxious mechanical stimuli, while 28 neurons (39%) were classified as HT and excited only by noxious mechanical (pinch) stimuli. The mean mechanical threshold of 12.8 ± 1.6 mN (mean ± SE; range, 0.4-30.1 mN) for WDR neurons was significantly lower than the mean threshold of 154.2 ± 18.3 mN (44.1-431.2 mN) for HT neurons (P < 0.001).

Spontaneous activity was exhibited by 25 of 44 WDR neurons (56.8%) at a rate ranging from 0.1 to 3.2 Hz. Only 3 of 28 HT neurons (10.7%) were spontaneously active (0.1-1.1 Hz).

All 72 neurons were excited by heat and/or cold stimuli. However, there were differences between cell types in their proportion excited by heat and cold (Table 1). With the use of a wide range of stimulus temperatures, it was found that 86.4% (38 of 44) of WDR cells were excited by both noxious heat and noxious cold stimuli, whereas only six WDR neurons (13.6%) were only sensitive to heat. No WDR neurons were excited by cold stimuli but not to heat. As for HT neurons, 60.7% (17 of 28) responded to both heat and cold stimuli, and 9 of 28 HT neurons (32.1%) were excited only by noxious heat. The remaining two HT neurons (7.2%) were excited only by noxious cold and not by noxious heat.


                              
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Table 1. Proportion of WDR and HT neurons that responded to heat and/or cold stimuli

Recording sites of 21 neurons (12 WDR and 9 HT) were identified histologically. Each of these neurons was excited by both heat and cold stimuli, and their recording sites were distributed throughout the dorsal horn in both superficial and deep laminae. The schematic in Fig. 1 illustrates the location of recording sites for WDR and HT neurons.



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Fig. 1. The location of recording sites for spinal neurons as determined by Prussian blue staining or by microlesions. open circle , recording sites for wide dynamic range (WDR) neurons; , recording sites for high-threshold (HT) neurons. Note that recording sites for both types of neurons are localized in superficial as well as deep dorsal horn.

Response characteristics of WDR and HT neurons to thermal stimuli

RESPONSE THRESHOLDS. Mean responses to cold and heat stimuli were obtained only from those neurons that were sensitive to thermal stimulation. As illustrated in Fig. 2, the mean response threshold of WDR neurons for cold differed significantly from that of HT neurons (Fig. 2A). The mean cold threshold for 38 WDR neurons was 14.6 ± 1.3°C (range: 28 to 0°C) compared with -0.6 ± 1.1°C (range: 8 to -12°C; P < 0.001) for 19 HT neurons. The greater sensitivity of WDR neurons to cold is further illustrated in Fig. 2B, which shows the cumulative proportion of WDR and HT neurons excited by each cold stimulus. Although 71% of WDR neurons were excited by 12°C, none of the HT neurons responded to this temperature. Nearly all (97%) WDR neurons were excited by stimulus temperatures >0°C, and 100% of these neurons were excited by a stimulus temperature of 0°C. In contrast, only 26% of HT neurons were excited by stimulus temperatures >0°C. Furthermore, 0°C excited only 58% of HT neurons, and 100% of these neurons responded only when the stimulus temperature reached -12°C.



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Fig. 2. Comparison of response properties of WDR and HT neurons to cold and heat stimuli. A: mean ± SE response thresholds to cold and heat stimuli. B: cumulative percentage of WDR and HT neurons excited by each cold stimulus intensity. C: cumulative percentage of WDR and HT neurons excited by each heat stimulus intensity. WDR neurons are represented by the solid black columns and HT neurons by the gray columns. * Significant difference between WDR and HT neurons.

A small but significant difference was also found in mean heat thresholds of WDR and HT neurons (Fig. 2A). The mean response threshold for WDR neurons was 42.2 ± 0.6°C (range: 35-49°C), and 44.0 ± 0.6°C (39-49°C) for HT neurons (P < 0.04). The cumulative proportion of WDR and HT neurons excited by the various heat stimuli is illustrated in Fig. 2C. For example, 77% of WDR and 69% of HT neurons responded to a stimulus temperature of 45°C, and 100% of both cell types were excited by 49°C.

RESPONSES TO SUPRATHRESHOLD STIMULI. Figure 3 shows a representative example of the responses of a WDR and a HT neuron to cold and heat stimuli. In general, neurons encoded the intensity of cold and heat stimuli; however, WDR neurons exhibited lower response thresholds to cold stimuli than did HT neurons. As can be seen from Fig. 4A, cold evoked a greater number of impulses from WDR (n = 38) than from HT (n = 19) neurons. A two-way ANOVA with repeated measures revealed significant differences in stimulus-response curves, which plot the number of impulses evoked by each cold stimulus, of WDR and HT neurons to stimulus temperatures between 28 and -12°C (P < 0.01). For example, -4°C evoked a mean of 139.8 ± 27.7 impulses/response in WDR neurons, but only 31.3 ± 8.9 impulses/response in HT neurons. A significant difference between WDR and HT neurons was also found in the average cumulative sum of impulses evoked by all stimulus temperatures (Fig. 4B). The mean number of cumulative impulses for WDR neurons was 829.6 ± 141.0 impulses, whereas HT neurons exhibited a mean cumulative total of 320.4 ± 97.7 impulses to all cold stimuli (P < 0.004). Thus the mean cumulative response of WDR neurons evoked by all cold stimuli was 159% greater than the cumulative response of HT neurons.



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Fig. 3. Responses of a single WDR and a single HT neuron to cold and heat stimuli. An analog trace of stimulus temperature is presented above each example of action potentials with stimulus temperatures. A base temperature of 32°C was maintained between stimuli. Note different time scales for cold and heat stimuli.



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Fig. 4. Mean ± SE responses of WDR and HT neurons evoked by cold and heat stimuli. A: mean number of impulses (±SE), for WDR () and HT () neurons as a function of cold intensity. B: mean ± SE cumulative sum of impulses evoked by all cold stimuli for WDR () and HT () neurons. C: mean number of impulses (±SE), for WDR () and HT () neurons as a function of heat intensity. D: mean ± SE cumulative sum of impulses evoked by all heat stimuli for WDR () and HT () neurons. * Significant difference between WDR and HT neurons (P <=  0.05).

Although WDR neurons discharged a greater number of impulses to each cold stimulus compared with HT neurons, stimulus-response functions were typically steeper for HT neurons. For each WDR and HT neuron, the number of impulses evoked by each cold stimulus was fit to a power function. For WDR neurons, the slope of the power function was 1.3 ± 0.1 (range: 0.5-3.3), whereas HT neurons exhibited a greater slope of 1.9 ± 0.2 (range: 0.9-3.6; P < 0.03).

As illustrated in Fig. 4C, heat evoked a greater number of impulses from WDR than from HT neurons. A two-way ANOVA with repeated measures revealed significant differences in the stimulus response functions of 44 WDR and 26 HT neurons in response to stimulus temperatures between 35 and 51°C (P < 0.04). The mean number of impulses evoked by each heat stimulus was greater for WDR neurons than for HT neurons. However, the mean slope of the power function was 2.0 ± 0.1 (range: 0.9-4.1) for WDR neurons and 2.1 ± 0.2 (range: 1.1-4.2) for HT neurons. These slopes did not differ from each other. Additionally the mean cumulative number of impulses evoked by all heat stimuli was greater for WDR neurons (858.8 ± 138.7 impulses) compared with HT neurons (450.3 ± 104.0 impulses; P < 0.02) as shown in Fig. 4D. Thus WDR neurons exhibited a 91% greater number of impulses than HT neurons in their cumulative response across all heat stimuli.

Responses of WDR and HT neurons during skin freezing

The effects of a mild cold injury to the skin, produced by -15°C applied for 20 s, were studied for 30 WDR and 22 HT neurons. Skin freezing was verified by the sudden increase in skin temperature, measured at the skin-thermode interface, that occurs during the process of fluid crystallization. We consider the freeze injury mild since it produced erythema but not blistering of the skin. Freezing occurred between 0.7 and 6 s after the thermode reached a temperature of -15°C and resulted in an abrupt, high-frequency discharge of all neurons tested. A representative response of an individual WDR neuron evoked during freezing is provided in Fig. 5. This neuron was excited by noxious cold prior to skin freezing and exhibited a high-frequency discharge at the onset of freezing. Following injury, spontaneous activity developed in neurons that were quiescent prior to injury, and the rate increased in those neurons that had exhibited spontaneous activity before freezing occurred. The increase in spontaneous activity persisted for 5-60 min. Mean discharge rates of WDR and HT neurons increased significantly during the first 10 s immediately following the onset of skin freezing as compared with the level of spontaneous activity prior to freezing (P < 0.03). Mean discharge rates of WDR and HT neurons increased from 0.9 ± 0.4 to 53.3 ± 9.7 Hz and from 0.4 ± 0.3 to 31.0 ± 7.1 Hz, respectively. Moreover, mean discharge rates of evoked by freezing were higher for WDR neurons (P < 0.04).



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Fig. 5. Representative example of the response of a WDR neuron to skin freezing. Top: analog trace of temperature at the interface between the thermode and the skin. Arrow indicates the sudden increase in skin temperature at the time of freezing. Bottom: responses of a single WDR neuron. Dashed line indicates the beginning of the response to freezing. Temperature that induced skin injury and a time scale are provided.

Effect of mild freeze injury on responses evoked by thermal stimuli

RESPONSE THRESHOLDS. Skin freezing increased the thermal sensitivity for each of the 25 WDR neurons and each of the 18 HT neurons. As illustrated in Fig. 6, response threshold to cold stimuli decreased after injury. For WDR neurons, mean cold threshold decreased from 12.2 ± 1.5°C to 20.6 ± 1.4°C (P < 0.001). For HT neurons, cold threshold decreased from 0.3 ± 1.5°C, to 10.6 ± 1.9°C (P < 0.001). The average decrease in cold thresholds was 9.0 ± 1.3°C for WDR neurons and 10.0 ± 1.6°C for HT neurons. For individual WDR and HT neurons the range of threshold change was 4-20°C.



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Fig. 6. Mean response thresholds (±SE) of WDR and HT neurons to heat and cold stimuli before () and after () freeze injury. * Significant difference in thresholds after freeze (P <=  0.05).

Freeze injury resulted in decreased thermal thresholds for both WDR and HT neurons, although mean heat thresholds decreased less than cold thresholds (Fig. 6). The mean heat threshold of WDR neurons decreased from 43.6 ± 0.9°C to 40.1 ± 0.8°C (P < 0.005), whereas HT neurons exhibited a decrease from 45.6 ± 1.4°C to 41.3 ± 1.0°C (P < 0.03). Thus the average change in heat threshold before and after injury was 4.0 ± 0.4°C and 4.3 ± 1.3°C for WDR and HT neurons, respectively. For individual WDR and HT neurons, the range of threshold decrease was 2-8°C.

The decrease in thermal thresholds changed the proportion of WDR and HT neurons excited by specific stimulus temperatures. Figure 7A shows the shift to the left in the proportion of neurons excited by specific stimulus intensities after cold injury. For example, before injury 35% of WDR neurons were excited by 16°C and 80% were excited by 8°C. After cold injury, 80% of WDR neurons were excited by 16°C and 100% by 8°C. Before injury, none of the HT neurons responded to 16°C, and only 10% were excited by 8°C. After the cold injury, however, 20% of HT neurons were excited by 16°C, and 70% responded to 8°C.



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Fig. 7. The cumulative percentage of WDR and HT neurons excited by each cold (A) and heat (B) stimulus before () and after () freeze injury. Note the leftward shifts that occurred after injury.

Figure 7B illustrates that a leftward shift also occurred in the proportion of WDR and HT neurons that were excited by various intensities of heat stimuli after freeze injury. For example, before injury 37% of WDR neurons were excited by 41°C, and 84% responded to 47°C. These proportions increased after cold injury to 58 and 100%, respectively. The proportion of HT neurons that was excited by these same heat stimuli increased from 14 and 71% before injury to 57 and 100% after injury. Collectively, these data indicate that cold injury increases the proportion of nociceptive dorsal horn neurons that are excited by heat and cold stimuli.

RESPONSES TO SUPRATHRESHOLD STIMULI. Figure 8 compares the responses of a single WDR neuron to cold (20, 8, and -12°C) and heat (39, 43, and 51°C) stimuli before and after injury. After freeze injury the typical changes observed were a decrease in thermal thresholds and an increase in the number of impulses to suprathreshold stimuli. As shown in Fig. 9A, the average number of impulses of WDR neurons to suprathreshold cold stimuli increased after cold injury (P < 0.02). Figure 9B shows that WDR neurons exhibited an 89% increase in the mean cumulative sum of evoked action potentials across all cold stimuli after injury (P < 0.001).



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Fig. 8. Responses of a single WDR neuron to cold and heat stimuli before and after freeze injury. Stimulus temperature is provided above each neuronal response. There was a decrease in response threshold and increased discharge to suprathreshold stimuli. Note different time scales for cold and heat stimuli.



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Fig. 9. Effect of freeze injury on responses of WDR neurons to thermal stimuli. A: mean ± SE number of impulses before () and after (open circle ) cold injury as a function of cold stimulus intensity. B: mean ± SE cumulative sum of impulses evoked by all cold stimuli before () and after () freeze. C: mean ± SE number of impulses before () and after (open circle ) injury as a function of heat stimulus intensity. D: mean ± SE cumulative sum of impulses evoked by all heat stimuli before () and after () cold injury. * Significant difference after freeze injury (P <=  0.05).

Similarly, responses of WDR neurons to heat stimuli were also increased after cold injury. Freeze injury produced a significant (P < 0.001) leftward shift in the stimulus-response function for heat (Fig. 9C) and evoked a 93% increase (P < 0.001) in the mean cumulative number of impulses to all heat stimuli (Fig. 9D).

Mean evoked responses of HT neurons to cold (Fig. 10A) and heat (Fig. 10C) stimuli also increased significantly after cold injury as illustrated by the leftward shift in their stimulus-response functions (P < 0.001). The mean cumulative sum of action potentials evoked across all cold stimuli increased 192% after cold injury (P < 0.001; Fig. 10B), whereas the mean cumulative response to all heat stimuli increased 92% after injury (P < 0.004; Fig. 10D). Thus responses to cold and heat stimuli were enhanced in both WDR and HT neurons following freeze injury, but HT neurons exhibited a greater facilitation than WDR neurons in responses to cold stimuli. Responses to heat following cold injury were enhanced to a similar degree for WDR and HT neurons.



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Fig. 10. Effect of freeze injury on responses of HT neurons to thermal stimuli. A: mean ± SE number of impulses before () and after (open circle ) cold injury as a function of cold stimulus intensity. B: mean ± SE cumulative sum of impulses evoked by all cold stimuli before () and after () freeze. C: mean ± SE number of impulses before () and after (open circle ) freeze injury as a function of heat stimulus intensity. D: mean ± SE cumulative sum of impulses evoked by all heat stimuli before () and after () freeze. * Significant difference after freeze (P <=  0.05).

Five WDR and four HT neurons were exposed to the freezing stimulus (-15°C for 20 s), but the skin did not exhibit freezing as defined by a sudden increase in skin temperature. Changes in response thresholds and responses evoked by suprahreshold cold and heat stimuli were not altered. Mean response threshold of the WDR neurons for cold and heat were identical before and after the freezing stimulus (9.3 ± 2.6°C and 42.7 ± 1.7°C, respectively). Similarly, mean response thresholds of HT neurons for cold and heat were -1.0 ± 3.0°C and 43.0 ± 1.2°C, respectively.

Newly acquired responses to thermal stimuli following freeze injury

All neurons described above that developed enhanced responses to cold and heat stimuli after freeze injury were excited by both cold and heat stimuli prior to injury. However, we also studied the effects of freeze injury on five neurons (3 WDR and 2 HT) that were initially sensitive to heat but not to cold stimuli (down to -12°C). Each of these neurons was excited by cold only at the time of skin freezing, but not before, and freeze-evoked discharge rates were similar to those of cold-sensitive neurons. A representative example is provided in Fig. 11A. The response occurred at the onset of freezing, which is indicated by the sudden rise in skin temperature. After injury, each neuron was excited by cold stimuli, with response thresholds ranging from 24 to -8°C (mean threshold: 11.2 ± 4.6°C). Responses of each neuron evoked by cold stimuli after injury are provided in Fig. 11B. Responses to heat also increased and were similar to the increased responses to heat described above. Mean response threshold decreased from 45.0 ± 1.3°C before injury to 41.4 ± 1.6°C after injury (P < 0.02), and responses evoked by suprathreshold heat stimuli increased (data not shown).



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Fig. 11. Newly acquired responses to cold stimuli after freeze injury. A: response of a single WDR neuron to skin freezing. It can be seen that this neuron was not excited by -15°C until injury occurred (dashed line). B: number of impulses as a function of cold intensity for each of 5 neurons (, WDR neurons; , HT neurons). Prior to freeze injury (-15°C), these 5 neurons were heat sensitive but not cold sensitive.

In addition to the 72 neurons that were excited by thermal stimulation of the skin, we also determined whether freeze injury could elicit novel responses from nociceptive neurons that were not excited by heat and cold stimuli prior to injury. Four such cells (2 WDR and 2 HT) were tested, none of which developed sensitivity to cold or to heat. Although these neurons were excited during skin freezing, their mean discharge rate was much lower (14.7 ± 7.5 Hz) than those of thermosensitive neurons. In addition, responses evoked by freezing were transient and lasted approximately 1 min.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Proportion and location of spinal neurons excited by noxious thermal stimuli

Our results indicate that a majority of the nociceptive spinal dorsal horn neurons that encode mechanical stimulus intensity in rats are excited by and encode the intensity of noxious heat. This finding agrees with earlier studies of the rat dorsal horn (Menetrey et al. 1979; Mitchell and Hellon 1977) and with similar results from spinothalamic tract (STT) neurons (Dado et al. 1994; Douglass and Carstens 1997) and from lamina I spinoparabrachial (SPB) neurons (Bester et al. 2000). The data are also in agreement with results obtained from STT neurons in cats (Christensen and Perl 1970; Craig and Kniffki 1985; Henry 1976) and monkeys (Ferrington et al. 1987; Kenshalo et al. 1979; Price et al. 1978).

Earlier studies of the responses of nociceptive dorsal horn neurons to innocuous or noxious cold stimuli (Christensen and Perl 1970; Craig and Kniffki 1985; Menetrey et al. 1979) utilized methods in which stimulus intensity either could not be precisely controlled (e.g., evaporation of ethyl chloride, application of ice), or in which a more restricted range of stimulus intensities was delivered. Studies using thermodes with Peltier devices for precise control of stimulus temperature enabled quantitative analysis of response thresholds to noxious cold to 0°C and demonstrated that many nociceptive dorsal horn neurons encoded intensity of noxious cold, at least to 0°C (Craig and Bushnell 1994; Craig and Serrano 1994; Dado et al. 1994; Ferrington et al. 1987; Kenshalo et al. 1982). We have extended previous results by delivering controlled stimulus intensites in discrete stimulus increments to as cold as -12°C. Using this paradigm, we found that cold thresholds of HT neurons can extend to -12°C (compared with 0°C for WDR neurons), and that the majority of WDR (86.4%) and HT (60.7%) neurons were responsive to noxious heat as well as to noxious cold stimuli. Another two HT neurons (7.1%) were sensitive to noxious mechanical and cold stimuli, but not to noxious heat. In addition, it was recently reported that approximately 35% of SPB neurons responsive to heat were also excited by and encoded the intensity of noxious cold at stimulus temperatures below 0°C (Bester et al. 2000). Thus using cold stimuli with intensities below 0°C is necessary to fully characterize the proportion of neurons excited by cold and reflects findings of response thresholds for cold and encoding of stimulus intensities below 0°C among many cutaneous Adelta and C-fiber nociceptors (Simone and Kajander 1996, 1997).

The use of cold stimuli at intensities below 0°C is also required to evoke Fos-like immunoreactivity in the spinal cord by cold (Abbadie et al. 1994a; Doyle and Hunt 1999). Stimuli of approximately -15°C and below produced labeling for c-Fos in the superficial (laminae I-II) and deep (laminae III-VI) dorsal horn and were intensity dependent. Interestingly, noxious heat stimulation of the hind paw induced expression of c-Fos in the spinal cord with a distribution similar to that produced by noxious cold stimuli (Abbadie et al. 1994b), suggesting that many dorsal horn neurons may process information from heat- and cold-sensitive nociceptors. Collectively, these findings suggest that dorsal horn neurons encode the intensity of cold at temperatures well below 0°C and that earlier studies may have underestimated the proportion of spinal dorsal horn neurons that are excited by noxious cold.

Similar to previous reports, the recording sites of WDR and HT neurons were located throughout the dorsal horn including in both superficial and deep dorsal horn (Burstein et al. 1991; Dado et al. 1994). No relationship could be discerned between the observed response properties of WDR and HT neurons and their location in the dorsal horn, which is consistent with similar results obtained from lumbar dorsal horn neurons in rats (Menetrey et al. 1979), lumbar STT neurons in monkeys (Kenshalo et al. 1979), and from cervical STT cells in rats (Dado et al. 1994). HT neurons that were responsive to noxious heat and to noxious cold may correspond to the STT neurons found in lamina I of cats that are responsive to noxious heat, pinch, and cold stimuli (HPC cells) (Han et al. 1998). In the present study, these cells were found in the superficial as well as the deep dorsal horn, although we do not know whether any were projection neurons.

Of 72 thermal-sensitive nociceptive neurons, 21% were exclusively heat-sensitive neurons, and only 3% were exclusively cold-sensitive neurons. This difference may reflect psychophysical results reporting a greater ability to detect and discriminate small changes in the intensity of noxious heat compared with noxious cold, and a steeper slope of stimulus-intensity functions for heat relative to cold stimulation (Morin and Bushnell 1998). However, the number of neurons that did not respond to cold stimuli may have been underestimated since some Adelta nociceptors in rat skin have cold response thresholds as low as -18°C (Simone and Kajander 1997). We did not use cold stimulus temperatures lower than -12°C because of possible skin freezing and sensitization.

Comparison of responses of dorsal horn neurons to noxious heat and cold stimuli

For both WDR and HT neurons, differences were observed in terms of the temperature-response curve, cumulative number of impulses, cumulative number of neurons responding to each temperature, and thermal thresholds. However, for both groups of neurons, the magnitudes of these differences were greater in their responses to cold than to heat.

Regarding heat sensitivity, WDR neurons exhibited a small but significantly lower mean response threshold, and greater discharge of impulses to suprathreshold stimuli than did HT neurons. These results agree with previous reports in rats (Bester et al. 2000), cats (Craig and Serrano 1994), and monkeys (Bushnell et al. 1984; Ferrington et al. 1987), whereas other studies found no significant differences between WDR and HT neurons in their responses to heat (Dado et al. 1994; Kenshalo et al. 1979; McHaffie et al. 1994; Surmeier et al. 1986). We found that the mean slopes of the power functions for both WDR and HT heat-sensitive neurons were nearly identical, suggesting that these neurons encode stimulus intensity similarly.

Regarding cold stimulation, we observed a greater difference between WDR and HT neurons. Nearly one-half (42.1%) of WDR but none of the HT neurons had response thresholds for cold in the innocuous range (>= 20°C). Also, the mean cold threshold for WDR neurons was lower (response to higher stimulus temperatures) than the mean threshold of HT neurons (14.6 vs. -0.6°C). In addition, the evoked number of impulses as a function of stimulus intensity was greater for WDR neurons. However, the slopes of power functions that related the number of evoked impulses to stimulus intensity were greater for HT neurons. One interesting observation is that the difference between WDR and HT in their sensitivity to cold stimuli is consistent with differences in responses to cold of subpopulations of cutaneous nociceptors. We found that C-fiber nociceptors were more sensitive to cold (lower response threshold) than Adelta nociceptors (Simone and Kajander 1996, 1997). Most Adelta nociceptors thresholds for cold occurred near or below 0°C. Response thresholds of Adelta nociceptors were significantly higher (colder stimulus temperatures) than thresholds of C fibers, and many exhibited response thresholds below 0°C. Responses of both WDR and HT nociceptors increased as stimulus temperature decreased. These data demonstrate that Adelta and C nociceptors are excited by a wide range of cold stimuli and suggest that the proportion of cutaneous nociceptors excited by noxious cold has been underestimated in previous studies. Thus one possibility is that WDR neurons receive more input from C-fiber nociceptors that are sensitive to cold stimuli and perhaps also from innocuous cold-specific fibers than HT neurons, whereas HT neurons receive more input from Adelta nociceptors that have high response thresholds for cold stimuli. This is supported by psychophysical studies in humans that have shown different qualities of cold pain sensation. The quality of cold pain evoked by moderately noxious cold temperatures has been described as a dull, aching pain but changes to a sharp and pricking pain as stimulus intensity is increased (Davis 1998; Lewis and Love 1926; Wolf and Hardy 1941). Thus the change in the quality of sensation from aching to pricking with increasing stimulus intensity may involve the recruitment of HT neurons by colder stimuli. The separate qualities of dull aching and pricking pain evoked by cold stimuli might be theoretically similar to the classic first and second pain sensations evoked by noxious heat. First pain, which is characterized as pricking pain, has been shown to be mediated by activation of Adelta nociceptors (Campbell and LaMotte 1983), whereas second pain is characterized as a dull, burning sensation and has been shown to be mediated primarily by activation of C-fibers (Beitel and Dubner 1976; Gybels et al. 1979; Torebjörk and Hallin 1974).

Responses of dorsal horn neurons during skin freezing

During the process of skin freezing, the interstitial fluid crystallizes, which results in an exothermic reaction due to condensation. The exothermic reaction can be measured objectively as a rapid increase in skin temperature (Beise et al. 1998; Keatinge and Cannon 1960). Since our Peltier device measured the temperature of the interface between the skin and the thermode, we were able to record the increase in skin temperature during freezing, thus providing an accurate measure of the time of skin freezing. It was found that all WDR and HT neurons exhibited a high-frequency discharge at the onset of skin freezing. This discharge was not due to skin temperature per se because it never occurred in the absence of freezing, regardless of stimulus temperature. Psychophysical studies in humans have shown that the onset of skin freezing is associated with an abrupt sensation of pricking or stinging pain (Beise et al. 1998; Granberg 1991; Kilo et al. 1994; Lewis and Love 1926). The abrupt pricking/stinging sensation did not occur in the absence of freezing. Our results suggest that both WDR and HT neurons contribute to pain sensation associated with skin freezing, although WDR neurons exhibited a greater discharge during freezing. It is not presently known which specific subtypes of peripheral afferent fibers are excited at the onset of freeze injury to provide the afferent drive for WDR and HT neurons.

Sensitization of dorsal horn neurons following a mild freeze injury: potential mechanisms and relation to psychophysical studies

Our results show that a mild freeze injury to the skin enhances activity of both WDR and HT neurons to heat and cold stimuli applied at the site of injury. This finding of cross sensitization between different modalities of thermal stimulation may suggest that a common mechanism accounts for the increase in responses to heat and cold. However, enhanced responses of WDR and HT neurons to both noxious heat and cold were not found following repeated noxious heating of the skin (Kenshalo et al. 1982). Rather, only heat-evoked responses were increased (Kenshalo et al. 1979). Our finding of cross-sensitization for heat and cold stimuli may result from properties of sensitization that are unique to cold injury to the skin, and must be different from sensitization induced by heating.

Previous psychophysical studies of cutaneous hyperalgesia following freeze injury have reported hyperalgesia to mechanical, heat, and cold stimuli applied to the injured skin, although the magnitude and duration of hyperalgesia is related to the severity of injury. A brief, mild freeze injury similar to that used in the present study produced a lowering of cold and heat pain thresholds soon after injury (Beise et al. 1998; Kilo et al. 1994). More severe freeze injuries (e.g., produced by -28°C) also produced mechanical hyperalgesia both within and surrounding the injured skin (secondary hyperalgesia) that developed several hours after injury and persisted for 24 h or more (Kilo et al. 1994; Lewis and Love 1926). In the present study we did not investigate whether responses evoked by mechanical stimulation increased, nor whether the increase in responses to heat and cold stimuli occurred in areas of the RF other than the contact area of the Peltier device. However, our data support the view that sensitization of both WDR and HT neurons may contribute to cold and heat hyperalgesia produced by freeze injury.

The mechanisms by which responses of dorsal horn neurons to heat and cold stimuli are increased after freeze injury are unclear. We believe that the enhanced responses are the result of injury and are not solely due to cold temperature because sensitization was not observed when the skin was cooled to -15°C but freezing did not occur. However, we do not know whether peripheral or central mechanisms, or both, contributed to the increased responses of dorsal horn neurons to heat and cold stimuli after the freeze injury. One possibility is that freeze causes sensitization of cutaneous nociceptors to heat and cold stimuli. It is known that sensitization of nociceptors contribute to heat hyperalgesia following heat injury to the skin (Campbell and LaMotte 1983; LaMotte et al. 1983; Meyer and Campbell 1981; Torebjörk et al. 1984). Whether nociceptors can become sensitized to cold stimuli following freeze injury and thereby contribute to cold hyperalgesia needs to be determined.

A second possibility is that the increased responses to heat and cold stimuli after freeze injury are due to central sensitization. It is well-known that tissue injury and inflammation increase excitability of nociceptive dorsal horn neurons whereby RFs become enlarged and responses evoked by mechanical and thermal innocuous and noxious inputs are enhanced (Simone 1992; Treede et al. 1992; Woolf 1992). High-frequency discharge in nociceptors, particularly C-fiber nociceptors, may lead to a state of central sensitization in which responses of dorsal horn neurons produced by activation of low-threshold afferent fibers, including cooling-specific fibers, as well as by nociceptors are increased. If central sensitization occurs following a mild freeze injury, it will be important to determine whether similar cellular events, such as activation of N-methyl-D-aspartate (NMDA) receptors, contribute to hyperexcitability as has been demonstrated with other models of injury and inflammation.

A particularly interesting finding was that five heat-sensitive neurons that did not appear to be responsive to cold stimuli before injury developed responses to cold after injury. This phenomenon might also be related to nociceptor sensitization or to central sensitization. In any event, we cannot preclude the possibility that these neurons received input from Adelta nociceptors with cold thresholds below -12°C, as described earlier (Simone and Kajander 1996, 1997), and sensitivity to cold would have been observed before injury if colder stimulus temperatures were used.

Conclusions

We have shown that the majority of WDR and HT neurons in the spinal cord are excited by and encode the intensity of noxious heat as well as noxious cold stimuli, and that both types of neurons develop increased responses to heat and cold stimuli following a mild cold damage to the skin. The decrease in response threshold and the increase in evoked response to cold stimuli following freeze injury were greater than those observed for heat stimuli. It is concluded that sensitization of both WDR and HT neurons located in the superficial as well as the deep dorsal horn contributes to thermal hyperalgesia following mild freeze injury to the skin. Sensitization of these neurons may also underlie hyperalgesia following more severe frostbite injuries.


    ACKNOWLEDGMENTS

We thank Dr. Glenn J. Giesler, Jr. for reading an earlier version of the manuscript.

This work was supported by National Institutes of Health Grants NS-33908 and DA-11986.


    FOOTNOTES

Address for reprint requests: D. A. Simone, Dept. of Oral Science, University of Minnesota, 515 Delaware St. SE, 17-252 Moos, Minneapolis, MN 55455 (E-mail: simon003{at}umn.edu).

Received 23 February 2001; accepted in final form 20 April 2001.


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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
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0022-3077/01 $5.00 Copyright © 2001 The American Physiological Society