Effects of prenatal exposure to diclofenac sodium and saline on the optic nerve of 4- and 20-week-old male rats: a stereological and histological study

Exploring the Nerve Regenerative Capacity of Compounds with Differing Affinity for PPARγ In Vitro and In Vivo

Damage to peripheral nerves can cause debilitating consequences for patients such as lifelong pain and disability. At present, no drug treatments are routinely given in the clinic following a peripheral nerve injury (PNI) to improve regeneration and remyelination of damaged nerves. Appropriately targeted therapeutic agents have the potential to be used at different stages following nerve damage, e.g., to maintain Schwann cell viability, induce and sustain a repair phenotype to support axonal growth, or promote remyelination. The development of therapies to promote nerve regeneration is currently of high interest to researchers, however, translation to the clinic of drug therapies for PNI is still lacking. Studying the effect of PPARγ agonists for treatment of peripheral nerve injures has demonstrated significant benefits. Ibuprofen, a non-steroidal anti-inflammatory drug (NSAID), has reproducibly demonstrated benefits in vitro and in vivo, suggested to be due to its agonist action on PPARγ. Other NSAIDs have demonstrated differing levels of PPARγ activation based upon their affinity. Therefore, it was of interest to determine whether affinity for PPARγ of selected drugs corresponded to an increase in regeneration. A 3D co-culture in vitro model identified some correlation between these two properties. However, when the drug treatments were screened in vivo, in a crush injury model in a rat sciatic nerve, the same correlation was not apparent. Further differences were observed between capacity to increase axon number and improvement in functional recovery. Despite there not being a clear correlation between affinity and size of effect on regeneration, all selected PPARγ agonists improved regeneration, providing a panel of compounds that could be explored for use in the treatment of PNI.

Hazardous impact of diclofenac on mammalian system: Mitigation strategy through green remediation approach

Diclofenac is an anti-inflammatory drug used as an analgesic. It is often detected in various environmental sources around the world and is considered as one of the emerging contaminants (ECs). This paper reviews the distribution of diclofenac at high concentrations in diverse environments and its adverse ecological impact. Recent studies observed strong evidence of the hazardous effect of diclofenac on mammals, including humans. Diclofenac could cause gastrointestinal complications, neurotoxicity, cardiotoxicity, hepatotoxicity, nephrotoxicity, hematotoxicity, genotoxicity, teratogenicity, bone fractures, and skin allergy in mammals even at a low concentration. Collectively, this comprehensive review relates the mode of toxicity, level of exposure, and route of administration as a unique approach for addressing the destructive consequence of diclofenac in mammalian systems. Finally, the mitigation strategy to eradicate the diclofenac toxicity through green remediation is critically discussed. This review will undoubtedly shed light on the toxic effects of pseudo-persistent diclofenac on mammals as well as frame stringent guidelines against its common usage.

The effect of maternal treatment with diclofenac sodium and thymoquinone on testicular parameters in rat offspring

INTRODUCTION AND OBJECTIVE

Diclofenac sodium (DS) can have toxic effects on various tissues and organs, as well as causing foetal and new-born malformations. Thymoquinone (TQ), the basic bioactive compound of black seed oil, is an antioxidant and antineoplastic substance. The aim of our study was to explore the effects of DS and TQ exposure during gestation on offspring rat testicular histology.

MATERIALS AND METHODS

Mother pregnant rats were divided into five groups: control, saline, DS, TQ and DS plus TQ (DS+TQ) four animals for each group. They were then treated as follows between day of 5 and 15 of gestation: the control group received no treatment. The saline group received physiological saline (1mg/kg/d) via the intraperitoneal (IP) route; the DS group received an intramuscular (IM) injection of DS (6.1mg/kg/d); the TQ group received TQ (5mg/kg/d) dissolved in drinking water; and the DS+TQ group received DS (6.1mg/kg/d) and TQ (5mg/kg/d) dissolved in water. After birth, the male rats were fed for four weeks, and at the end of this period offspring were sacrificed. Stereological methods, physical disector and Cavalieri principle were used for particle counting and volume estimation respectively.

RESULTS

The results revealed a significant decrease in the total number of Sertoli and Leydig cells in 4-week-old rats in the DS group (p<0.05), and TQ not have provide protection against this adverse effect of DS.

CONCLUSIONS

In this study, DS at a dose of 6.1mg/kg, equivalent to a dose of 1mg/kg in humans, decreased the number of Sertoli and Leydig cells, and TQ did not have a protective effect against the adverse effect of DS during the gestation period. These results show that new dose depend studies on TQ and DS interaction are requested to see protective effect of TQ.

Peripheral nerve and diclofenac sodium: Molecular and clinical approaches

Nonsteroidal anti-inflammatory drugs (NSAIDs) are the most frequently prescribed medications worldwide. Diclofenac sodium (DS), one of these NSAIDs, has a high specificity for arachidonic acid-degrading cyclooxygenase (COX)-2 enzymes. This drug can be used to relieve neuropathic pain. In this review, we examine the relevant researches, including in vivo, animal, and clinical human studies, with the aim of understanding the effect of DS on the peripheral nerves. In injured nerves, COX-2 is potently upregulated around the injury site. When a nerve is damaged, both COX-1 and COX-2 expression is increased in macrophages and Schwann cells. In addition, COX inhibitors can promote axonal outgrowth in cultured neurons. Neuropathic pain occurs after injury and leads to dysfunction of the peripheral nervous system. NSAIDs can modulate the nociceptive and inflammatory pain pathways and control neuropathic pain. DS may accelerate nerve regeneration and its effects on healing, as well as causing deleterious effects in the developing nerves. DS teratogenicity disrupts myelin sheath thickness and axon structure. Understanding the possible benefits and limitations of DS and specific conditions such as prenatal use will be of benefit in clinical practice.