Microwave facilitation of domperidone antagonism of apomorphine-induced stereotypic climbing in mice

The dopaminergic agonist apomorphine produced dose-dependent stereotypic climbing behavior in mice housed in cages with vertical bars. This drug effect was competitively inhibited by systemic pretreatment with the centrally acting dopaminergic antagonist haloperidol but not by microwave irradiation (2.45 GHz, 20 mW/cm2, CW, 10 min) nor by systemic pretreatment with domperidone, a dopaminergic antagonist that only poorly penetrates the blood-brain barrier (BBB). Yet when mice were systemically pretreated with domperidone and then subjected to microwave irradiation (as above), the apomorphine effect was significantly reduced. Microwave irradiation also facilitated antagonism of the apomorphine effect by low and otherwise ineffective systemic pretreatment doses of haloperidol. Apomorphine-induced stereotypic climbing behavior was also reduced by domperidone administered intracerebrally, which bypassed the BBB. Exposure of intracerebral domperidone-pretreated animals to microwave irradiation failed to increase the degree of antagonism. These findings indicate that microwave irradiation can facilitate central effects of domperidone, a drug which acts mainly in the periphery. One possible explanation for these findings is that microwave irradiation alters the permeability of the BBB and increases the entry of domperidone to central sites of action.     

Replacement of receptor cells in the hamster vomeronasal epithelium after nerve transection

Chemoreceptor cells in the vomeronasal and olfactory epithelium are replaced following experimentally induced degeneration. This study analyzes quantitatively the time course and degree of vomeronasal receptor cell replacement. Unilateral transection of the vomeronasal nerves in adult hamster was used to induce a retrograde degeneration of receptor cells in the vomeronasal organ. Histological measurement of both number of receptor cells and epithelial thickness were made for recovery times from 0 to 60 days. After nerve transection, there was a gradual degeneration of receptor cells, the number decreasing to 50% of control by day 2 and 16% by day 6. During days 7-15 maximum receptor cell replacement was observed. Cell number increased rapidly and reached a peak on day 15. At recovery times of 40-60 days, cell number returned to the control level. Epithelial thickness, however, decreased to 60-70% during the degeneration period (days 4-6) and did not return to control levels. After 40-60 days epithelial thickness remained at 70% of control. These results demonstrate that vomeronasal receptor cells are replaced following degeneration, but epithelial thickness does not return to control levels. These findings suggest that the number of replacement cells is not limited by the reduced thickness of the epithelium, and that recovery mechanisms may function to restore an optimum number of receptor cells.      

Enhanced apomorphine-induced hypothermia in alloxan-treated rats

Previous studies have indicated that drug-induced experimental diabetes is associated with increased receptor binding in the rat brain. The purpose of this study was to determine whether the dopamine receptor agonist apomorphine (APO) might produce an accentuated hypothermic response in rats rendered diabetic by alloxan (ALX) treatment. In a previous study, however, the only controls used were ALX-treated rats that failed to develop glycosuria. Therefore, in this study, APO (0.5 mg/kg IP) was administered to ALX-diabetic and non-diabetic as well as saline-treated control rats to ascertain whether the APO responsiveness of ALX-non-diabetic rats was comparable to that of saline control animals. ALX-diabetic rats experienced significantly greater hypothermic response to APO than did the saline control animals. Although ALX-non-diabetic rats were similar to the saline control animals in body weight and blood glucose levels, they too were hyperresponsive to APO. These findings indicate that pancreatic injury from ALX, while not always sufficiently severe to produce overt diabetes, does appear to induce an hyperresponsiveness to APO-induced hypothermia in a manner similar to that observed in severely diabetic animals.     

Microwave facilitation of methylatropine antagonism of central cholinomimetic drug effects

Pilocarpine-induced hypothermia and oxotremorine-induced tremors in mice are central cholinomimetic drug effects that are readily blocked by the muscarinic antagonist atropine. However, the quaternary ammonium derivative of atropine, methylatropine, is unable to block these cholinomimetic drug effects by virture of its inability to penetrate the blood-brain barrier (BBB) and blood-cerebral spinal fluid barrier (B-CSFB). Dose-response curves for pilocarpine and oxotremorine effects are not appreciably affected either by pretreatment with methylatropine (1.0 mg/kg) or by exposure to moderate-level microwave irradiation (2.45 GHz, 23.7 W/kg, CW, 10-min exposure). However, in mice receiving both the methylatropine pretreatment and microwave irradiation, the dose-response curves for both pilocarpine and oxotremorine effects were significantly shifted to the right, signifying a central anticholinergic action by methylatropine. These data indicate that a single acute exposure to a thermogenic level of microwave irradiation facilitates methylatropine antagonism of centrally mediated cholinomimetic drug effects. One possible explanation for this observation is that microwave radiation may enhance passage of quaternary ammonium compounds like methylatropine across the BBB and B-CSFB.     

Enhancement of apomorphine-induced climbing in mice by reversible and irreversible narcotic antagonist drugs

Apomorphine produced a characteristic climbing syndrome in mice. Pretreatment of mice with increasing doses of the reversible narcotic antagonist naloxone resulted in a dose-related enhancement of this activity. Central microinjection of mice with the irreversible narcotic antagonist drug chlornaltrexamine also resulted in significant potentiation of apomorphine-induced climbing for up to fourteen days following pretreatment. These data indicate that narcotic antagonist drugs of both reversible and irreversible types are capable of enhancing this dopaminergic drug effect in mice.