Effects of nicotine withdrawal on the local cerebral glucose utilization in conscious rats

Imaging localised dynamic changes in the nucleus accumbens following nicotine withdrawal in rats

This study utilises pharmacological functional magnetic resonance imaging (fMRI) to examine the neurobiological mechanisms through which nicotine produces dependence. Using an established regime to induce physical dependence to nicotine in rats (osmotic minipumps delivering 3.16 mg/kg/day nicotine for 7 days SC), animals were subsequently anaesthetised under urethane and positioned in a stereotaxic frame to allow collection of gradient echo whole brain images with a 4.7-T MRI spectrometer. Rats were initially scanned for 34 min (40 baseline image volumes, 1 volume per 51 s) then challenged with mecamylamine (1.0 mg/kg SC) or saline (1 ml/kg) and scanned for a further 68 min (80 image volumes). Mecamylamine precipitated highly significant positive changes in fMRI blood oxygen level dependent (BOLD) contrast that were predominantly localised to the NAc of nicotine-dependent rats. Saline-treated rats challenged with the same dose of mecamylamine exhibited similar but smaller increases in BOLD contrast although such changes were less defined around the NAc. Precipitated withdrawal also elicited statistically significant negative BOLD contrast changes in widespread cortical regions. These findings are consistent with previous neurochemical reports on decreases in dopamine in the NAc during nicotine withdrawal. This fMRI study further highlights the potential and power to image the neurobiological events during nicotine dependence.

Effects of nicotine and chlorisondamine on cerebral glucose utilization in immobilized and freely-moving rats

Chlorisondamine blocks central nicotinic receptors for many weeks via an unknown mechanism. Intracerebroventricular administration of [(3)H]-chlorisondamine in rats results in an anatomically restricted and persistent intracellular accumulation of radioactivity. The initial aim of the present study was to test whether nicotinic receptor antagonism by chlorisondamine is also anatomically restricted. Male adult rats were pretreated several times with nicotine to avoid the disruptive effects of the drug seen in drug-naïve animals. They then received chlorisondamine (10 microg i. c.v.) or saline, and local cerebral glucose utilization (LCGU) was measured 4 weeks later after acute nicotine (0.4 mg kg(-1) s.c.) or saline administration. During testing, rats were partially immobilized. Nicotine significantly increased LCGU in the anteroventral thalamus and in superior colliculus. Chlorisondamine completely blocked the first of these effects. Chlorisondamine significantly reduced LCGU in the lateral habenula, substantia nigra pars compacta, ventral tegmental area, and cerebellar granular layer. The second experiment was of similar design, but the rats were not pre-exposed to nicotine, and were tested whilst freely-moving. Acute nicotine significantly increased LCGU in anteroventral thalamus, superior colliculus, medial habenula and dorsal lateral geniculate. Overall, however, nicotine significantly decreased LCGU. Most or all of the central effects of nicotine on LCGU were reversed by chlorisondamine given 4 weeks beforehand. These findings suggest that chlorisondamine blocks nicotinic effects widely within the brain. They also indicate that in freely-moving rats, nicotine can reduce or stimulate cerebral glucose utilization, depending on the brain area. British Journal of Pharmacology (2000) 129, 147 - 155

Comparison of cholinergic drug effects on regional brain glucose consumption in rats and humans by means of autoradiography and position emission tomography

Cholinergic mechanisms have been extensively studied in animals and have been implicated in the pathogenesis of human disorders such as Alzheimer's disease. However, few investigations have directly evaluated the validity of extrapolating the results of animal studies to humans. As a component of a continuing examination of the contribution of cholinergic deficits to the alterations in brain metabolism that occur in Alzheimer's disease, we have compared the effects of scopolamine and physostigmine on regional brain energy metabolism in both rats and humans, using a common region of interest atlas. In Alzheimer's patients and in rodents, physostigmine increased glucose metabolism in several regions (e.g. thalamus) and decreased it in others. Overall, there was a significant positive correlation for the effects of physostigmine in the nineteen brain regions studied in both species (r = 0.51, P < 0.05). In normal humans, scopolamine induced a metabolic increase in most brain regions except in the thalamus. Outside this structure, the regional effects of scopolamine were significantly and negatively correlated (r = 0.58, P < 0.01) between rat and human. These results suggest that: (1) cholinergic mechanisms have a similar anatomic distribution in both species, (2) muscarinic receptor-mediated cholinergic effects could predominate outside the thalamus, (3) muscarinic mechanisms are inhibitory in humans but are more complex and possibly excitatory in rats, (4) nicotinic stimulatory effects are found in the thalamus of both species, and (5) physostigmine, but not scopolamine, alters glucose consumption similarly in both species.