Potentiation of Valproate-induced Anticonvulsant Response by Nigella sativa Seed Constituents: The Role of GABA Receptors.

This study investigated antiepileptic effects of the main constituents of Nigella sativa (NS) seed (i.e. aqueous extract (AE), fixed oil (FO), volatile oil (VO)) and the main components of its VO (i.e. thymoquinone, α-pinene and p-cymene) using pentylenetetrazole (PTZ) and maximal electroshock (MES)-induced convulsions. The potential of these constituents to induce minimal neurological deficit (MND) was also evaluated by using chimney test.Except for the FO, all of the NS seed constituents protected mice effectively against PTZ-induced convulsions. The activity of the VO in this model maybe attributed mainly to its content of thymoquinone and p-cymene and to a lesser extent, α-pinene. VO and its component p-cymene effectively suppressed convulsions induced by MES. The contents of p-cymene present in the effective dose of the VO maybe partially responsible for its anti-seizure effects.All of the NS seed constituents induced varying degrees of MND in the chimney test. MND induced by VO may pertain to its contents of thymoquinone (63%), p-cymene (23%) and α-pinene (<14%). Protective indices of p-cymene and thymoquinone were closer to one, but only in PTZ model.Exploration on the role of receptors suggests that picrotoxin and bicuculline-sensitive GABA receptors, most probably GABAA receptors, mediate an increase in GABAergic response. In the part dealing with the interaction of valproate with thymoquinone, it can be mentioned that thymoquinone increased the potency of valproate in both PTZ and MES models.

Modification by L-NAME of codeine induced analgesia: possible role of nitric oxide.

Objectives were to investigate the effect of nonselective nitric oxide synthase (NOS) inhibitor, L-NAME on codeine-induced analgesia and to see the role of NO in its antinociceptive effect. Also, to see if L-NAME can potentiate the antinociceptive response of sub-effective dose of codeine and to explore if opioid receptors have some role to play in L-NAME effects. Mice were injected with selected doses of codeine or other selected agents intraperitoneally and the latency to hot plate was recorded at zero, 15, 30, and 60 min of the treatments. The antinociceptive response of codeine (10 mg/kg, i.p.) was studied in comparison to those of the NOS inhibitor, L-NAME, and of nitric oxide donor, sodium nitroprusside (SNP). Assessment of nitrates and nitrites (NOx) in the sera of treated mice were also made. Codeine (20 mg/kg dose), induced analgesia significantly and dose dependently only after 15 min. L-NAME at 20, 40, and 80 mg/kg dose levels significantly changed the nonanalgesic effect of codeine (10 mg/kg) to highly significant analgesia. The effect of L-NAME 40 mg/kg was significantly higher than the other two doses and was almost equal to that of the higher dose of codeine. Naloxone itself did not show any intrinsic effect but almost abolished the L-NAME-codeine induced analgesia. Similarly, SNP (1 mg/kg) reversed the decrease in reaction time by L-NAME-codeine to its control values, significantly. Pretreatment with L-NAME rendered the nonanalgesic dose of codeine significantly analgesic almost in an equal potency to the high dose of codeine alone and indicate that the NO modulatory effect on the opioid analgesic codeine is probably, at least in part, through opioid receptors.