Ramy E. Abdelhamid scite author profile

The clinical benzothiophene SERM (BT-SERM), raloxifene, was compared with estrogens in protection of primary rat neurons against oxygen-glucose deprivation (OGD). Structure-activity relationships for neuroprotection were determined for a family of BT-SERMs displaying a spectrum of ERα and ERβ binding affinity and agonist/antagonist activity, leading to discovery of a neuroprotective pharmacophore, present in the clinically relevant SERMS, raloxifene and desmethylarzoxifene (DMA), for which submicromolar potency was observed for neuroprotection. BT-SERM neuroprotection did not correlate with binding to ER nor classical ER activity, however, both the neuroprotective SERMs and estrogens were shown, using pharmacological probes, to activate the same kinase signaling cascades. The antiestrogen ICI 182,780 inhibited the actions of estrogens, but not those of BT-SERMs, whereas antagonism of the G-protein coupled receptor, GPR30, was effective for both SERMs and estrogens. Since SERMs have antioxidant activity, ER-independent mechanisms were studied using the classical phenolic antioxidants, BHT and Trolox, and the Nrf2-dependent cytoprotective electrophile, sulforaphane. However, neuroprotection by these agents was not sensitive to GPR30 antagonism. Collectively, these data indicate that the activity of neuroprotective BT-SERMs is GPR30-dependent and ER-independent and not mediated by antioxidant effects. Comparison of novel BT-SERM derivatives and analogs identified a neuroprotective pharmacophore of potential use in design of novel neuroprotective agents with a spectrum of ER activity.

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Resident Macrophages in Muscle Contribute to Development of Hyperalgesia in a Mouse Model of Noninflammatory Muscle Pain

Gong

Abdelhamid

Carvalho

et al. 2016

The Journal of Pain

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Macrophages play a role in innate immunity within the body, are located in muscle tissue, and can release inflammatory cytokines that sensitize local nociceptors. Here we investigate the role of resident macrophages in the non-inflammatory muscle pain model induced by 2 pH 4.0 injections 5 days apart in the gastrocnemius muscle. We demonstrate that injecting 2 pH 4.0 injections into the gastrocnemius muscle increased the number of local muscle macrophages, and depleting muscle macrophages with clodronate liposomes prior to acid injections attenuated the hyperalgesia produced by this model. To further examine the contribution of local macrophages to this hyperalgesia, we injected mice intramuscularly with C34, a TLR4 receptor antagonist. When given before the first pH 4.0 injection, C34 attenuated the muscle and tactile hyperalgesia produced by the model. However, when given before the second injection C34 had no effect on the development of hyperalgesia. Then to test whether activation of local macrophages sensitizes nociceptors to normally non-nociceptive stimuli we replaced either the first or second acid injection with the immune cell activator lipopolysaccharide (LPS), or the inflammatory cytokine interleukin-6 (IL-6). Injecting LPS or IL-6 instead of the either the first or second pH 4.0 injection resulted in a dose-dependent increase in paw withdrawal responses and decrease in muscle withdrawal thresholds. The highest doses of LPS and IL-6 resulted in development of hyperalgesia bilaterally. The present study shows that resident macrophages in muscle are key to development of chronic muscle pain.

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Forced swim-induced musculoskeletal hyperalgesia is mediated by CRF2 receptors but not by TRPV1 receptors

et al. 2013

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The exacerbation of musculoskeletal pain by stress in humans is modeled by the musculoskeletal hyperalgesia in rodents following a forced swim. We hypothesized that stress-sensitive corticotropin releasing factor (CRF) receptors and transient receptor vanilloid 1 (TRPV1) receptors are responsible for the swim stress-induced musculoskeletal hyperalgesia. We confirmed that a cold swim (26°C) caused a transient, morphine-sensitive decrease in grip force responses reflecting musculoskeletal hyperalgesia in mice. Pretreatment with the CRF2 receptor antagonist astressin 2B, but not the CRF1 receptor antagonist NBI-35965, attenuated this hyperalgesia. Desensitizing the TRPV1 receptor centrally or peripherally using desensitizing doses of resiniferatoxin (RTX) failed to prevent the musculoskeletal hyperalgesia produced by cold swim. SB-366791, a TRPV1 antagonist, also failed to influence swim-induced hyperalgesia. Together these data indicate that swim stress-induced musculoskeletal hyperalgesia is mediated, in part, by CRF2 receptors but is independent of the TRPV1 receptor.

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ASICs Mediate Pain and Inflammation in Musculoskeletal Diseases

Abdelhamid

Sluka

2015

Physiology

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Chronic musculoskeletal pain is debilitating and affects ∼ 20% of adults. Tissue acidosis is present in painful musculoskeletal diseases like rheumatoid arthritis. ASICs are located on skeletal muscle and joint nociceptors as well as on nonneuronal cells in the muscles and joints, where they mediate nociception. This review discusses the properties of different types of ASICs, factors affecting their pH sensitivity, and their role in musculoskeletal hyperalgesia and inflammation.

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Depressive behavior in the forced swim test can be induced by TRPV1 receptor activity and is dependent on NMDA receptors

Abdelhamid

Kovács

Nunez

et al. 2014

Pharmacological Research

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Blocking, desensitizing, or knocking out transient receptor potential vanilloid type 1 (TRPV1) receptors decreases immobility in the forced swim test, a measure of depressive behavior. We questioned whether enhancing TRPV1 activity promotes immobility in a fashion that is prevented by antidepressants. To test this we activated heat-sensitive TRPV1 receptors in mice by water that is warmer than body temperature (41°C) or a low dose of resiniferatoxin (RTX). Water at 41°C elicited less immobility than cooler water (26°C), indicating that thermoregulatory sites do not contribute to immobility. Although a desensitizing regimen of RTX (3–5 injections of 0.1 mg/kg s.c.) decreased immobility during swims at 26°C, it did not during swims at 41°C. In contrast, low dose of RTX (0.02 mg/kg s.c.) enhanced immobility, but only during swims at 41°C. Thus, activation of TRPV1 receptors, endogenously or exogenously, enhances immobility and these sites are activated by cold rather than warmth. Two distinct types of antidepressants, amitriptyline (10 mg/kg i.p.) and ketamine (50 mg/kg i.p.), each inhibited the increase in immobility induced by the low dose of RTX, verifying its mediation by TRPV1 sites. When desensitization was limited to central populations using intrathecal injections of RTX (0.25 µg/kg i.t.), immobility was attenuated at both temperatures and the increase in immobility produced by the low dose of RTX was inhibited. This demonstrates a role for central TRPV1 receptors in depressive behavior, activated by conditions (cold stress) distinct from those that activate TRPV1 receptors along thermosensory afferents (heat).

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