Genotoxic, biochemical and histopathological studies to assessment the topiramate hepatorenal toxicity in mice.

Liver and kidney role in detoxification and drug metabolism increases the risk of their poisonous injury. Topiramate (TMP) is an effective popular migraine prophylaxis that is accepted for utilize in adults and teenagers. Therefore, the target of this research is to estimate the potential toxic effects of TMP on liver and kidney in male mice. Thirty-two adult albino male mice were divided into four groups (n = 8 mice). Group I of animals was given saline solution and used as negative control. The other three groups were administrated TPM at doses (100, 200 and 400 mg/kg) for 28 days. Genotoxicity was evaluated by comet assay and DNA fragmentation by Diphenyleamine. Biochemical investigation was achieved by estimating liver enzymes (AST, ALT), alkaline phosphatase (ALP) creatinine and uric acid. In addition, measurement of the antioxidant enzymes, malondialdehyde and nitric oxide were performed in both two tissues of liver and kidney. Microscopic examination of hematoxyline and eosin (H&E), tumor necrosis factor (TNF-α) and caspase3 stained sections were done to explore the effect of topiramate on mice tissues of liver and kidney. The data revealed that TPM showed dose dependent toxicity that represented in: DNA damage in tested cells and increased level of liver enzymes, creatinine and uric acid as markers of toxicity. Topiramate significantly diminished antioxidant enzymes activities and elevated the level of malondialdehyde and nitric oxide. In addition, TPM caused histopathological alterations and dose dependent positive immune reaction for TNF--α and caspase 3 in kidney and liver tissues. The results showed that Topiramate has marked toxicity in liver and kidney of mice.

Topiramate treatment in Wistar rats during childhood induces sex-specific vascular dysfunction in adulthood.

The present study determined whether treatment during childhood with topiramate (TPM), a new generation antiepileptic drug, results in altered aortic reactivity in adult male and female rats. We also sought to understand the role of endothelium-derived contractile factors in TPM-induced vascular dysfunction. Male and female Wistar rats were treated with TPM (41 mg/kg/day) or water (TPM vehicle) by gavage during childhood (postnatal day, 16-28). In adulthood, thoracic aorta reactivity to phenylephrine (phenyl), as well as aortic thickness and expression of cyclooxygenases (COX-1 and COX-2), NOX2, and p47phox were evaluated. The aortic response to phenyl was increased in male and female rats from the TPM group when compared with the control group. In TPM male rats, the hyperreactivity to phenyl was abrogated by the inhibition of NADPH oxidase and COX-2, while in female rats, responses were restored only by inhibition of COX-2. In addition, TPM male rats presented aortic hypertrophy and increased expression of NOX-2 and p47phox, while TPM female rats showed increased COX-2 aortic expression. Taken together, for the first-time, the present study provides evidence that treatment with TPM during childhood causes vascular dysfunction in adulthood, and that the mechanism underlying the vascular effects of TPM is sex-specific.

Modulation of PTZ-induced convulsions in rats using topiramate alone or combined with low dose gamma irradiation: involving AKT/m-TOR pathway.

The current study evaluates the anticonvulsant effect low dose whole body gamma irradiation (LDR) alone or combined with topiramate against pentylenetetrazole (PTZ)-induced convulsions. Male Wister rats received either saline or PTZ (75 mg/kg i.p.). The other three groups were pretreated with single low dose radiation (0.5 Gy), topiramate (50 mg/kg, p.o., seven days) and TPM with LDR respectively before PTZ injection. Racine' score, latency, and duration of the convulsions were assessed. Glutamate and GABA were measured. AKT/m-TOR signaling pathway including AKT (protein kinase B), mammalian target of rapamycin (m-TOR), protein S6, and caspase 3 were also assessed. Measurements of markers of oxidative stress including malondialdehyde (MDA), glutathione (GSH), and nitric oxide (NO) were carried out. Histological examinations of hippocampi were done. PTZ produced behavioral changes (high Racine score, short latency, and long duration). It elevated MDA and NO contents, while reduced GSH content. TPM treatment alone or combined with LDR ameliorated the PTZ-induced convulsions and caused significant improvement in behavioral changes, brain mediators, m-TOR pathway, oxidative stress, and histological pictures in hippocampal regions. Histopathological examinations of the normal group showed normal structure with intact cells, while PTZ-treated rats exhibited necrosis, pyknosis, and atrophy of pyramidal cells. The histological findings corroborated with the amendment of biochemical parameters. The positive effects of LDR could offer a possible contributor in management of convulsions due to modulation of AkT/m-TOR signaling pathway, reduction of oxidative stress and modulation of brain amino acids. LDR improved the oxidative stress side effects of topiramate.

Effect of antiepileptic drug (Topiramate) and cold pressed ginger oil on testicular genes expression, sexual hormones and histopathological alterations in mice.

Sexual dysfunction in the epileptic patient is difficult to confirm whether it is ailment or therapy related. Antiepileptic drugs often use in reproductive age, through reproductive progress and maturation. On the other side, cold-pressed oils are rich in bioactive phytochemicals with health-promoting traits. The target of this work was to appraise the sexual dysfunction of antiepileptic Topiramate (TPM) and cold pressed ginger oil (CPGO) as antiepileptic alternative medicine in male mice. Fifty-four adult male albino mice were divided into nine groups (n = 6 mice). One group given saline and used as negative control; another one was given corn oil as vehicle. Six groups administered orally with TPM or CPGO at 100, 200 and 400 mg/kg. Moreover, group of animals co-administrated orally CPGO with TPM (400 mg/kg) to study their interaction. Fatty acid profile and tocols composition of CPGO were determined. in vitro assays were undertaken to evaluate radical scavenging traits of CPGO utilizing sable 1,1-diphenyl-2-picrylhydrazyl (DPPH·) and galvinoxyl radicals. The study investigated antioxidant and oxidative stress markers, sexual hormones levels, mRNA levels of vascular endothelial growth factor (Vegfa), synaptonemal complex protein (Sycp3), Wilms tumor gene (Wt1) as well as histopathological and immunohistochemical examination. Strong radical scavenging potential of CPGO against stable DPPH· and galvinoxyl radicals was recorded. The results revealed that TPM caused a dose-dependent reduction in the antioxidant activities and testosterone content, while, malonaldehyde (MDA) and nitric oxide (NO) as oxidative stress markers were elevated. Vegfa and Sycp3 mRNA expression down-regulated at all Topiramate tested doses, but Wt1 up-regulated at 400 mg/kg. TPM (400 mg/kg) revealed histological alterations associated with strong positive Bax immune reactive spermatogoneal and Leydig cells. Ginger oil elevated the CAT and SOD (antioxidant enzymes), serum testosterone and diminished the oxidative stress, up regulated the expression of Vegfa and Sycp3 and down-regulated the Wt1 expression. Meanwhile, CPGO revealed no histopathological alterations and no Bax immune-reactive cells. CPGO co-administration with TPM (400 mg/kg) attenuated the TPM toxicity. High doses of TPM may exhibit sexual dysfunction but CPGO is safe and has androgenic property. CPGO co-administration could protect the antiepileptic patient from the TPM sexual dysfunction.