Teru Matsuda scite author profile

Unaccustomed strenuous exercise that includes lengthening contraction (LC) often causes delayed-onset muscle soreness (DOMS), a kind of muscular mechanical hyperalgesia. The substances that induce this phenomenon are largely unknown. Peculiarly, DOMS is not perceived during and shortly after exercise, but rather is first perceived after ϳ1 d. Using B 2 bradykinin receptor antagonist HOE 140, we show here that bradykinin released during exercise plays a pivotal role in triggering the process that leads to muscular mechanical hyperalgesia. HOE 140 completely suppressed the development of muscular mechanical hyperalgesia when injected before LC, but when injected 2 d after LC failed to reverse mechanical hyperalgesia that had already developed. B 1 antagonist was ineffective, regardless of the timing of its injection. Upregulation of nerve growth factor (NGF) mRNA and protein occurred in exercised muscle over a comparable time course (12 h to 2 d after LC) for muscle mechanical hyperalgesia. Antibodies to NGF injected intramuscularly 2 d after exercise reversed muscle mechanical hyperalgesia. HOE 140 inhibited the upregulation of NGF. In contrast, shortening contraction or stretching induced neither mechanical hyperalgesia nor NGF upregulation. Bradykinin together with shortening contraction, but not bradykinin alone, reproduced lasting mechanical hyperalgesia. We also showed that rat NGF sensitized thin-fiber afferents to mechanical stimulation in the periphery after 10 -20 min. Thus, NGF upregulation through activation of B 2 bradykinin receptors is essential (though not satisfactory) to mechanical hyperalgesia after exercise. The present observations explain why DOMS occurs with a delay, and why lengthening contraction but not shortening contraction induces DOMS.

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Muscular mechanical hyperalgesia revealed by behavioural pain test and c‐Fos expression in the spinal dorsal horn after eccentric contraction in rats

Taguchi

Matsuda

Tamura

et al. 2005

The Journal of Physiology

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Delayed onset muscle soreness (DOMS) is quite common, but the mechanism for this phenomenon is still not understood; even the existence of muscle tenderness (mechanical hyperalgesia) has not been demonstrated in experimental models. We developed an animal model of DOMS by inducing eccentric contraction (lengthening contraction, ECC) to the extensor digitorum longus muscle (EDL), and investigated the existence of mechanical hyperalgesia in the EDL by means of behavioural pain tests (Randall-Selitto test and von Frey hair test, applied to/through the skin on the EDL muscle) and c-Fos expression in the spinal dorsal horn. We found that the mechanical withdrawal threshold measured with the Randall-Selitto apparatus decreased significantly between 1 and 3 days after ECC, while that measured by von Frey hairs did not. The group that underwent stretching of the muscle only (SHAM group) showed no change in mechanical pain threshold in either test. These results demonstrated that the pain threshold of deep tissues (possibly of the muscle) decreased after ECC. c-Fos immunoreactivity in the dorsal horn (examined 2 days after ECC/SHAM exercise) was not changed by either ECC or compression (1568 mN) to the EDL muscle by itself, but it was significantly increased by applying compression to the EDL muscle 2 days after ECC. This increase was observed in the superficial dorsal horn of the L4 segment of the ipsilateral side, and was clearly suppressed by morphine treatment (10 mg kg −1 , I.P.). These results demonstrated the existence of mechanical hyperalgesia in the muscle subjected to ECC. This model could be used for future study of the neural mechanism of muscle soreness.

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Cutaneous C-fiber nociceptor responses and nociceptive behaviors in aged Sprague–Dawley rats

Taguchi

Ota

Matsuda

et al. 2010

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The change with age in pain perception in humans and the nociceptive behaviors in animals elicited by noxious stimuli to the skin are not well understood, and little is known about the peripheral neural mechanisms of cutaneous nociception in the aged. We systematically examined cutaneous nociceptor responses and nociceptive behaviors in young (9-14 w) and in aged (127-138 w) Sprague-Dawley rats. C-fiber nociceptors in the skin were identified by mechanical and electrical stimulation, and extracellularly recorded from hind paw skin-saphenous nerve preparations in vitro. In the aged rats, the proportions of mechano-responsive and/or heat-responsive C-nociceptors were significantly lower. The proportion of mechano- and thermo-insensitive units, on the other hand, was significantly increased. In addition, the response threshold to mechanical stimulus tended to be higher and the magnitude of the response tended to be smaller. There were no differences between the two age groups in the response magnitudes of mechano-responsive C-nociceptors to bradykinin, cold or heat. Repetitive electrical stimulation of afferent fibers revealed exaggerated slowing of conduction velocity in mechano-responsive C-fibers in the aged. This showed for the first time that not only receptive properties of afferent terminals but also membrane properties of conducting axons are changed in aged rats. Nociceptive behaviors in response to noxious levels of cold (cold plate test) and heat (Hargreaves' radiant heat test) were facilitated in aged animals, while mechanical sensitivity measured by von Frey hairs remained unchanged. These discrepancies between the changes in peripheral afferents and the behavioral outcomes might be explained by facilitatory changes in the central nervous system.

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Change with age in muscular mechanical hyperalgesia after lengthening contraction in rats

Taguchi

Matsuda

Mizumura

2007

Neuroscience Research

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Teru Matsuda

Bradykinin and Nerve Growth Factor Play Pivotal Roles in Muscular Mechanical Hyperalgesia after Exercise (Delayed-Onset Muscle Soreness)

Muscular mechanical hyperalgesia revealed by behavioural pain test and c‐Fos expression in the spinal dorsal horn after eccentric contraction in rats

Cutaneous C-fiber nociceptor responses and nociceptive behaviors in aged Sprague–Dawley rats

Change with age in muscular mechanical hyperalgesia after lengthening contraction in rats

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