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Editorial Views  |   September 2002
Is Gabapentin a “Broad-spectrum” Analgesic?
Author Notes
  • Director, Clinical Pain Research, and Assistant Professor, Departments of Anesthesiology and Pharmacology and Toxicity, Queen's University, Kingston, Ontario, Canada.
Article Information
Editorial Views
Editorial Views   |   September 2002
Is Gabapentin a “Broad-spectrum” Analgesic?
Anesthesiology 9 2002, Vol.97, 537-539. doi:
Anesthesiology 9 2002, Vol.97, 537-539. doi:
GABAPENTIN  is an alkylated γ-aminobutyric acid analog that was synthesized in 1977 1 and first developed clinically as an anticonvulsant in the late 1980s. 2 Recent experience suggests that it may also be useful in treating other neurologic and psychiatric conditions such as spasticity, anxiety, and pain. 1 Following early case reports of use in “reflex sympathetic dystrophy,”3 multicenter controlled trials have demonstrated analgesic efficacy and safety of gabapentin in chronic neuropathic pain. 4 Other anticonvulsants such as carbamazepine, phenytoin, and topiramate have also shown efficacy in neuropathic pain but are generally not thought to be useful in other conditions such as inflammatory or postoperative pain. 5 However, accumulating laboratory and clinical evidence, including a postoperative analgesic trial appearing in this issue of Anesthesiology, 6 suggest that gabapentin and related analogs such as pregabalin (S  -(+)-3-isobutylgaba) 7 are analgesic across a wider spectrum of pain states. The role of certain neural changes, common both to neuropathic and post-tissue injury pain, 8 may explain these recent observations.
Gabapentin and Injury-induced Neuroplasticity
Similar to nerve injury, surgical tissue injury has been shown to result in spinal sensitization—i.e.  , metabolic activation and hyperexcitability of spinal nociceptive neurons, expansion of sensory receptive fields, and alterations in the processing of innocuous stimuli. 8 These postoperative neuroplastic changes underlie the development of “pathologic” pain, which is characterized by (1) hyperalgesia (an increased response to a stimulus that is normally painful), which may be primary (at the site of injury) or secondary (distant to the site of injury); and (2) allodynia (pain due to a stimulus that does not normally provoke pain). 9 Pharmacologic effects of gabapentin that may be important in pain modulation include binding to α2δ calcium channel subunits, 10 suppression of glutamate, 11 and substance P 12 neurotransmission, as well as modulation of γ-aminobutyric acid receptors. 13 However, the relative importance of these and other mechanisms of gabapentin remains uncertain, and intensive investigation continues. The most important site of action of gabapentin also remains unclear, although evidence supports effects at peripheral, 14 primary afferent neuron, 15 spinal neuron, 11 and supraspinal sites 16 (fig. 1). In any case, several animal 17–19 and human 6,20,21 studies support antihyperalgesic and antiallodynic effects of gabapentin in the setting of peripheral tissue injury (table 1).
Fig. 1. Putative sites of action of gabapentin. References in parentheses provide examples of evidence to support antinociceptive effects of gabapentin at respective sites within the nervous system.
Fig. 1. Putative sites of action of gabapentin. References in parentheses provide examples of evidence to support antinociceptive effects of gabapentin at respective sites within the nervous system.
Fig. 1. Putative sites of action of gabapentin. References in parentheses provide examples of evidence to support antinociceptive effects of gabapentin at respective sites within the nervous system.
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Table 1. Examples of Antihyperalgesic and Antiallodynic Effects of Gabapentin after Peripheral Tissue Injury
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Table 1. Examples of Antihyperalgesic and Antiallodynic Effects of Gabapentin after Peripheral Tissue Injury
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Of particular relevance to injury-induced neuroplasticity, evidence suggests that gabapentin selectively reduces pain transmission in a “sensitized” nervous system but not in a normal nervous system. For example, a recent in vitro  study has demonstrated that gabapentin affects N  -methyl-d-aspartate-mediated currents in spinal neurons from rats with experimental arthritis but not from normal rats. 22 In vivo  , gabapentin has no effect on pain behaviors during phase 1 of the rat formalin test (which is thought to reflect brief physiologic pain) but does appear to be analgesic during phase 2 of this test, at which time formalin-induced spinal sensitization is, in part, thought to be driving pain behavior. 23 Similarly, two studies of human volunteers showed that gabapentin had no effect on pain transmission in normal skin but significantly reduced hyperalgesia following an experimental thermal injury 20 or heat-capsaicin sensitization. 21 This pattern of activity is of considerable value in that gabapentin may serve to reduce “pathologic” pain while leaving other protective nociceptive mechanisms intact.
In this issue's study by Dirks et al.  , 6 a single dose of gabapentin prior to mastectomy reduced postoperative morphine use and pain during movement. Trends for analgesia at rest failed to reach statistical significance. Although additional work in this area should include larger trials extending further into the postoperative period, these early findings suggest the possibility that gabapentin selectively reduces movement-evoked pain over spontaneous pain. If so, this would parallel similar findings with the 2-amino-3-hydroxy-5-methyl-4-isoxazole-proprionic acid (AMPA)/kainate antagonist LY293558, another antihyperalgesic agent that has been shown to reduce move-ment-evoked, but not spontaneous, postoperative pain. 24 Whether or not gabapentin proves to have any effect on pain at rest, this observed reduction of movement-evoked pain is of particular clinical interest. Recent evidence suggests that movement-evoked pain may contribute to postoperative physiologic impairment, 25 and numerous postoperative studies demonstrate that opioids, while effective for spontaneous pain, perform poorly for movement-evoked pain. 26 Data from Dirks et al.  6 support a favorable therapeutic profile in postoperative patients, suggesting that gabapentin may be a welcome addition to the anesthesiologist's pharmacopoeia of “coanalgesics” such as nonsteroidal antiinflammatory drugs and local anesthetics. However, before considering the routine use of gabapentin in postoperative pain, future studies are needed to (1) replicate the findings of Dirks et al.  6, (2) evaluate the safety and efficacy of postoperative multidose gabapentin administration, and (3) determine the optimal duration of use and dose of gabapentin in postoperative pain.
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Fig. 1. Putative sites of action of gabapentin. References in parentheses provide examples of evidence to support antinociceptive effects of gabapentin at respective sites within the nervous system.
Fig. 1. Putative sites of action of gabapentin. References in parentheses provide examples of evidence to support antinociceptive effects of gabapentin at respective sites within the nervous system.
Fig. 1. Putative sites of action of gabapentin. References in parentheses provide examples of evidence to support antinociceptive effects of gabapentin at respective sites within the nervous system.
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Table 1. Examples of Antihyperalgesic and Antiallodynic Effects of Gabapentin after Peripheral Tissue Injury
Image not available
Table 1. Examples of Antihyperalgesic and Antiallodynic Effects of Gabapentin after Peripheral Tissue Injury
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