Intrinsic Mechanisms of Pain Inhibition: Activation by Stress

Terman, GW; Shavit, Yehuda; Jw, Lewis; Cannon, J. Timothy; Liebeskind, John C.

doi:10.1126/science.6505691

Cited by 519 publications

(316 citation statements)

References 92 publications

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“…While the significant improvement in WB at the equivalent high-dose pregabalin indicated that it provided a successful analgesic effect, the potential sedative side effects observed at this dose in the OF and burrowing assays suggest that this result was confounded and may represent a false positive resulting from the sedative effects of the drug. In contrast to the WB assay, the burrowing assay may not result in potential false positives/negatives induced by restraining the animal (Terman et al, 1984;Imbe et al, 2006;Mogil, 2009). The burrowing assay could, therefore, be used to discriminate between analgesic doses that impair movement, which according to previous reports, the WB assay cannot (Andrews et al, 2012).…”

Section: Discussionmentioning

confidence: 99%

“…As the animal is restrained, data from the WB assay do not distinguish between doses of sedatives that might impair movement and motor function. It has also been suggested that assays that restrain animals could elicit a stress response (Mogil, 2009), leading to increased pain tolerance due to stress-induced analgesia (Terman et al, 1984) or increased sensitivity to pain due to stress-induced hyperalgesia (Imbe et al, 2006). Stress-induced analgesia/hyperalgesia could, therefore, lead to false positives/negatives.…”

Section: Discussionmentioning

confidence: 99%

“…Rodents were presented with a gravel-filled hollow tube; the weight of gravel displaced from the tube after a fixed time period was measured and this weight was relative to the burrowing response (Deacon, 2006(Deacon, , 2009. The burrowing assay is considered to have advantages compared with evoked response or weight-bearing (WB) assays, which can potentially produce false positives/ negatives due to potential stress-induced responses, investigator bias and sedative side effects (Terman et al, 1984;Imbe et al, 2006;Mogil, 2009). To date, no comparison of the burrowing assay with established methods has been performed.…”

Section: Introductionmentioning

confidence: 99%

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Burrowing as a non‐reflex behavioural readout for analgesic action in a rat model of sub‐chronic knee joint inflammation

Rutten¹,

Schiene²,

Robens³

et al. 2013

European Journal of Pain

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Background: Innate responses against spontaneous pain are proposed to improve the predictive validity of preclinical analgesia models. Therefore, development and validation of novel readouts is necessary. To investigate whether innate rodent burrowing is a useful alternative behavioural readout for assessment of analgesic efficacy, a complete Freund's adjuvant (CFA)-induced model of sub-chronic inflammation was used to compare the effects of naproxen, ibuprofen and pregabalin in weight-bearing (WB), open-field (OF) and burrowing assays. Methods: Male Sprague Dawley rats were injected with 150 μL of CFA (2 mg/mL) into the knee (hind leg) 3 days before testing. Naproxen, ibuprofen and pregabalin were administered at different doses 30, 90 and 60 min, respectively, before testing. WB was determined using a rat incapacitance tester; horizontal distance moved and vertical rearings were recorded in an OF; and burrowing was measured by the weight of gravel remaining in a hollow tube after 60 min. Results: CFA-induced arthritis reduced WB, OF activity and burrowing. Naproxen, pregabalin and ibuprofen treatment normalized WB; however, horizontal OF activity was not improved by any treatment; rearing behaviour was moderately reinstated by ibuprofen (100 mg/kg). In burrowing, naproxen (100 mg/kg), ibuprofen (31.6 and 100 mg/kg) and pregabalin (10 mg/kg) reversed CFA-induced deficits. Conclusions: Burrowing performance is an alternative non-reflex readout relying on innate rodent behaviour that is affected by nociceptive behaviour and can be pharmacologically manipulated. The burrowing assay appears to be more sensitive than OF assays and is as sensitive as WB assays at distinguishing between analgesic doses and doses that impair locomotion.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Burrowing as a non‐reflex behavioural readout for analgesic action in a rat model of sub‐chronic knee joint inflammation

Rutten¹,

Schiene²,

Robens³

et al. 2013

European Journal of Pain

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“…They, and others, have reported that descending inhibitory systems are suppressed by barbiturates (Frank and Ohta 1971;Collins et al 1990). Since these reports, others showed that pentobarbital blocks shock-induced analgesia (Terman et al 1984;Grau 1987) and other forms of anesthesia were shown to diminish the inhibition of dorsal horn neuron firing seen after noxious stimulation (Tomlinson et al 1983). The exact mechanism through which this occurs remains unknown, although the inhibitory neurotransmitter GABA appears to play a major role (Asana and Ogasawara 1981;Olsen and Snowman 1982;Sivam et al 1982).…”

Section: Discussionmentioning

confidence: 99%

“…The inhibitory signal, is believed to originate in the periaqueductal gray, travel to the rostroventral medulla, including the nucleus raphe magnus (NRM), and then to the spinal cord through serotonergic fibers that descend through the DLF to suppress firing of neurons within the dorsal horns (Mayer et al 1971;Oliveras et al 1974;Fields 1979, 1984). This antinociceptive system can be engaged by aversive environmental stimuli, such as shock and restraint (Madden et al 1977;Terman et al 1984;Tricklebank and Curzon 1984). In the case of shock and other localized noxious stimuli, the antinociception is correlated with the inhibition of nociceptive neurons within the spinal cord and occurs in areas distant from the stimulation site (Morgan and Whitney 1996).…”

Section: Introductionmentioning

confidence: 99%

Exposure to intermittent nociceptive stimulation under pentobarbital anesthesia disrupts spinal cord function in rats

et al. 2007

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Rationale-Spinal cord plasticity can be assessed in spinal rats using an instrumental learning paradigm in which subjects learn an instrumental response, hindlimb flexion, to minimize shock exposure. Prior exposure to uncontrollable intermittent stimulation blocks learning in spinal rats but has no effect if given before spinal transection, suggesting that supraspinal systems modulate nociceptive input to the spinal cord, rendering it less susceptible to the detrimental consequences of uncontrollable stimulation.Objective-The present study examines whether disrupting brain function with pentobarbital blocks descending inhibitory systems that normally modulate nociceptive input, making the spinal cord more sensitive to the adverse effect of uncontrollable intermittent stimulation. Materials and methods-MaleSprague-Dawley rats received uncontrollable intermittent stimulation during pentobarbital anesthesia after (experiment 1) or before (experiment 2) spinal cord transection. They were then tested for instrumental learning at a later time point. Experiment 3 examined whether these manipulations affected nociceptive (thermal) thresholds.Results-Experiment 1 showed that pentobarbital had no effect on the induction of the learning deficit after spinal cord transection. Experiment 2 showed that intact rats anesthetized during uncontrollable intermittent stimulation failed to learn when later transected and tested for instrumental learning. Experiment 3 found that uncontrollable intermittent stimulation induced an antinociception in intact subjects that was blocked by pentobarbital. Conclusions-The results suggest a surgical dose of pentobarbital (50 mg/kg) suppresses supraspinal (experiment 2) but not spinal (experiment 1) systems that modulate nociceptive input to the spinal cord by blocking the antinociception that is induced by this input (experiment 3).

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Neurotransmitter, neurohormonal, and neuropeptidal function in stress and PTSD

Bremner

Pearce

2016

Posttraumatic Stress Disorder

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Intrinsic Mechanisms of Pain Inhibition: Activation by Stress

Cited by 519 publications

References 92 publications

Burrowing as a non‐reflex behavioural readout for analgesic action in a rat model of sub‐chronic knee joint inflammation

Burrowing as a non‐reflex behavioural readout for analgesic action in a rat model of sub‐chronic knee joint inflammation

Exposure to intermittent nociceptive stimulation under pentobarbital anesthesia disrupts spinal cord function in rats

Neurotransmitter, neurohormonal, and neuropeptidal function in stress and PTSD

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