The increasing use of transgenic mice for the study of pain mechanisms necessitates comprehensive understanding of the murine somatosensory system. Using an in vivo mouse preparation, we studied response properties of tibial nerve afferent fibers innervating glabrous skin. Recordings were obtained from 225 fibers identified by mechanical stimulation of the skin. Of these, 106 were classed as A beta mechanoreceptors, 51 as A delta fibers, and 68 as C fibers. A beta mechanoreceptors had a mean conduction velocity of 22.2 +/- 0.7 (SE) m/s (13.8--40.0 m/s) and a median mechanical threshold of 2.1 mN (0.4--56.6 mN) and were subclassed as rapidly adapting (RA, n = 75) or slowly adapting (SA, n = 31) based on responses to constant force mechanical stimuli. Conduction velocities ranged from 1.4 to 13.6 m/s (mean 7.1 +/- 0.6 m/s) for A delta fibers and 0.21 to 1.3 m/s (0.7 +/- 0.1 m/s) for C fibers. Median mechanical thresholds were 10.4 and 24.4 mN for A delta and C fibers, respectively. Responses of A delta and C fibers evoked by heat (35--51 degrees C) and by cold (28 to -12 degrees C) stimuli were determined. Mean response thresholds of A delta fibers were 42.0 +/- 3.1 degrees C for heat and 7.6 +/- 3.8 degrees C for cold, whereas mean response thresholds of C fibers were 40.3 +/- 0.4 degrees C for heat and 10.1 +/- 1.9 degrees C for cold. Responses evoked by heat and cold stimuli increased monotonically with stimulus intensity. Although only 12% of tested A delta fibers were heat sensitive, 50% responded to cold. Only one A delta nociceptor responded to both heat and cold stimuli. In addition, 40% of A delta fibers were only mechanosensitive since they responded neither to heat nor to cold stimuli. Thermal stimuli evoked responses from the majority of C fibers: 82% were heat sensitive, while 77% of C fibers were excited by cold, and 68% were excited by both heat and cold stimuli. Only 11% of C fibers were insensitive to heat and/or cold. This in vivo study provides an analysis of mouse primary afferent fibers innervating glabrous skin including new information on encoding of noxious thermal stimuli within the peripheral somatosensory system of the mouse. These results will be useful for future comparative studies with transgenic mice.
Clinical management of severe pain associated with sickle cell disease (SCD) remains challenging. Development of optimal therapy would be facilitated by use of murine model(s) with varying degrees of sickling and pain tests that are most sensitive to vasoocclusion. We found that young (≤3 month old) NY1DD and S+SAntilles mice (having modest and moderate sickle phenotype, respectively) exhibit evidence of deep tissue/musculoskeletal pain. Deep tissue pain and cold sensitivity in S+SAntilles mice increased significantly with both age and incitement of hypoxia/reoxygenation (H/R). C57/BL6 mice (genetic background strain of NY1DD and S+SAntilles) were hypersensitive to mechanical and heat stimuli, even without the sickle transgene. H/R treatment of HbSS-BERK mice with severe sickle phenotype resulted in significantly decreased withdrawal thresholds and enhanced mechanical, thermal and deep tissue hyperalgesia. Deep hyperalgesia incited by H/R in HbSS-BERK was ameliorated by CP 55940, a cannabinoid receptor agonist. Thus, assessment of deep tissue pain appears to be the most sensitive measure for studying pain mechanisms across mouse models of SCD, and HbSS-BERK mice may best model vaso-occlusive and chronic pain of SCD.
We used a murine model to investigate functional interactions between tumors and peripheral nerves that may contribute to pain associated with cancer. Implantation of fibrosarcoma cells in and around the calcaneus bone produced mechanical hyperalgesia of the ipsilateral paw. Electrophysiological recordings from primary afferent fibers in control and hyperalgesic mice with tumor revealed the development of spontaneous activity (0.2-3.4 Hz) in 34% of cutaneous C-fibers adjacent to the tumor (9-17 d after implantation). C-fibers in tumor-bearing mice exhibited a mean decrease in heat threshold of 3.5 +/- 0.10 degrees C. We also examined innervation of the skin overlying the tumor. Epidermal nerve fibers (ENFs) were immunostained for protein gene product 9.5, imaged using confocal microscopy, and analyzed in terms of number of fibers per millimeter of epidermal length and branching (number of nodes per fiber). Divergent morphological changes were linked to tumor progression. Although branching of ENFs increased significantly relative to control values, in later stages (16-24 d after implantation) of tumor growth a sharp decrease in the number of ENFs was observed. This decay of epidermal innervation of skin over the tumor coincided temporally with gradual loss of electrophysiological activity in tumor-bearing mice. The development of spontaneous activity and sensitization to heat in C-fibers and increased innervation of cutaneous structures within the first 2 weeks of tumor growth suggest activation and sensitization of a proportion of C-fibers. The decrease in the number of ENFs observed in later stages of tumor development implicates neuropathic involvement in this model of cancer pain.
Since its introduction in 1992, the spinal nerve ligation (SNL) model of neuropathic pain has been widely used for various investigative works on neuropathic pain mechanisms as well as in screening tests for the development of new analgesic drugs. This model was developed by tightly ligating one (L5) or two (L5 and L6) segmental spinal nerves in the rat. The operation results in long-lasting behavioral signs of mechanical allodynia, heat hyperalgesia, cold allodynia, and ongoing pain. In the process of widespread usage, however, many different variations of the SNL model have been produced, either intentionally or unintentionally, by different investigators. Although the factors that cause these variations themselves are interesting and important topics to be studied, the pain mechanisms involved in these variations are likely different from the original model. Therefore, this chapter describes, in detail, the method for producing the spinal nerve ligation model that will minimally induce potential factors that may contribute to these variations. It is hoped that this description will help many investigators to produce a consistent animal model with uniform pathophysiological mechanisms.
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