Intraperitoneal administration and other modifications of the 2-deoxy-D-glucose technique

Striatal Rgs4 regulates feeding and susceptibility to diet-induced obesity

Consumption of high fat, high sugar (western) diets is a major contributor to the current high levels of obesity. Here, we used a multidisciplinary approach to gain insight into the molecular mechanisms underlying susceptibility to diet-induced obesity (DIO). Using positron emission tomography (PET), we identified the dorsal striatum as the brain area most altered in DIO-susceptible rats and molecular studies within this region highlighted regulator of G-protein signaling 4 (Rgs4) within laser-capture micro-dissected striatonigral (SN) and striatopallidal (SP) medium spiny neurons (MSNs) as playing a key role. Rgs4 is a GTPase accelerating enzyme implicated in plasticity mechanisms of SP MSNs, which are known to regulate feeding and disturbances of which are associated with obesity. Compared to DIO-resistant rats, DIO-susceptible rats exhibited increased striatal Rgs4 with mRNA expression levels enriched in SP MSNs. siRNA-mediated knockdown of striatal Rgs4 in DIO-susceptible rats decreased food intake to levels comparable to DIO-resistant animals. Finally, we demonstrated that the human Rgs4 gene locus is associated with increased body weight and obesity susceptibility phenotypes, and that overweight humans exhibit increased striatal Rgs4 protein. Our findings highlight a novel role for involvement of Rgs4 in SP MSNs in feeding and DIO-susceptibility.

Limbic activation to novel versus familiar food cues predicts food preference and alcohol intake

Expectation of salient rewards and novelty seeking are processes implicated in substance use disorders but the neurobiological substrates underlying these associations are not well understood. To better understand the regional circuitry of novelty and reward preference, rats were conditioned to pair unique cues with bacon, an initially novel food, or chow, a familiar food. In the same animals, after training, cue-induced brain activity was measured, and the relationships between activity and preference for three rewards, the conditioned foods and ethanol (EtOH), were separately determined. Activity in response to the food paired cues was measured using brain glucose metabolism (BGluM). Rats favoring bacon-paired (BAP) cues had increased BGluM in mesocorticolimbic brain regions after exposure to these cues, while rats favoring chow-paired (CHP) cues showed relative deactivation in these regions. Rats exhibiting BAP cue-induced activation in prefrontal cortex (PFC) also consumed more EtOH while rats with cortical activation in response to CHP cues showed lower EtOH consumption. Additionally, long-term stable expression levels of PFC Grin2a, a subunit of the NMDA receptor, correlated with individual differences in EtOH preference insomuch that rats with high EtOH preference had enduringly low PFC Grin2a mRNA expression. No other glutamatergic, dopaminergic or endocannabinoid genes studied showed this relationship. Overall, these results suggest that natural variation in mesocorticolimbic sensitivity to reward-paired cues underlies behavioral preferences for and vulnerability to alcohol abuse, and support the notion of common neuronal circuits involved in food- and drug-seeking behavior. The findings also provide evidence that PFC NMDA-mediated glutamate signaling may modulate these associations.

Intraperitoneal catheter placement for pharmacological imaging studies in conscious mice

Imaging studies that use rodents sometimes involve intraperitoneal administration of pharmacological compounds. To facilitate such studies, the authors developed a simple and easily mastered technique for placing an intraperitoneal catheter in a conscious mouse. This technique eliminates the need to remove the animal from the scanner to administer a drug through the intraperitoneal route.

Reproducibility of intraperitoneal 2-deoxy-2-[18F]-fluoro-D-glucose cerebral uptake in rodents through time

INTRODUCTION

One strength of small animal imaging is the ability to obtain longitudinal measurements within the same animal, effectively reducing the number of animals needed and increasing statistical power. However, the variability of within-rodent brain glucose uptake after an intraperitoneal injection across an extended time has not been measured.

METHODS

Small animal imaging with 2-deoxy-2-[(18)F]-fluoro-D-glucose ((18)FDG) was used to determine the variability of a 50-min brain (18)FDG uptake following an intraperitoneal injection over time in awake male and female Sprague-Dawley rodents.

RESULTS

After determining the variability of an intraperitoneal injection in the awake rat, we found that normalization of brain (18)FDG uptake for (1) injected dose and body weight or (2) body weight, plasma glucose concentration and injected dose resulted in a coefficient of variation (CV) of 15%. However, if we normalized regional uptake to whole brain to compare relative regional changes, the CV was less than 5%. Normalized cerebral (18)FDG uptake values were reproducible for a 2-week period in young adult animals. After 1 year, both male and female animals had reduced whole-brain uptake, as well as reduced regional hippocampal and striatal (18)FDG uptake.

CONCLUSION

Overall, our results were similar to findings in previous rodent and human clinical populations; thus, using a high throughput study with intraperitoneal (18)FDG is a promising preclinical model for clinical populations. This is particularly relevant for measuring changes in brain function after experimental manipulation, such as long-term pharmacological administration.

Functional consequences of neuropeptide FF receptors stimulation in mouse: a cerebral glucose uptake study

The brain substrates involved in the pharmacological effects of neuropeptide FF (NPFF, Phe-Leu-Phe-Gln-Pro-Gln-Arg-Phe-NH2) including interactions with opioid systems, were investigated with the [14C]-2-deoxyglucose ([14C]-2-DG) autoradiography technique in mouse. The changes in cerebral activity were mapped after i.p. administration of 1DMe ([D-Tyr1,(NMe)Phe3]NPFF; 70 mg/kg), a neuropeptide FF analogue partially resistant to peptidases, alone or in combination with morphine (15 mg/kg). 1DMe induced a rapid decrease in the cerebral activity in the thalamus, the pontine reticular nuclei and the cerebellar cortex, brain regions involved in the control of motor activity and/or the processing of sensory data. This decrease, observed when 1DMe was administered 5 min before [14C]-2-DG, was reversed by morphine, which was devoid of significant effect at this time. When administered 30 min before the radioisotope, 1DMe was without effect, whereas morphine induced a significant increase in cerebral glucose utilization in the caudate putamen, the primary somatosensory cortex, the thalamus, the superior colliculus, the pontine reticular nuclei and the spinal cord. The association of morphine and 1DMe significantly increased cerebral glucose utilization in the same regions as morphine alone and also in three additional regions: the auditory cortex, the inferior colliculus and the dorsomedial periaqueductal gray. Following systemic administration, 1DMe and morphine modulated cerebral activity in brain regions involved in pain transmission and motor control, but their effects were temporally shifted, as were their effects on horizontal locomotor activity. However, neuropeptide FF-induced changes in brain activity were modulated in part by opioid receptors activation.

Comparative analysis of acute and chronic administration of haloperidol and clozapine using [3H] 2-deoxyglucose metabolic mapping

In an effort to compare and contrast the mechanisms of action of typical and atypical antipsychotic drugs, [3H] 2-deoxyglucose metabolic mapping was employed following acute and chronic administration of haloperidol (1 mg/kg i.p. acute and 0.5 mg/kg i.p. chronic) and clozapine (20 mg/kg i.p., both acute and chronic). Optical density ratios (ODR) were measured in 62 brain structures. An overall decrease in ODR was observed in many of the regions analyzed. Acute haloperidol elicited significant decreases, particularly in the thalamus and hippocampus. Acute clozapine decreased glucose uptake in the caudate putamen, hippocampus, central gray, locus coreleus, and the thalamus. In both chronically treated haloperidol and clozapine animals, significant decreases in ODR were seen in the thalamus and hippocampal areas most dramatically, with other changes in the superior colliculus, retrospenial cortex, and the cerebellum. Clozapine caused significant effects in 32 nuclei acutely and only 19 nuclei chronically. Haloperidol caused significant effects in 23 nuclei acutely and 15 nuclei chronically. The pattern of change induced by haloperidol and clozapine were remarkably similar when considering their pharmacology is somewhat different. Both antipsychotics elicited fewer significant changes upon chronic administration.

Jugular vein catheterization for repeated blood sampling in the unrestrained conscious rat

The ability to obtain repeated, low-stress blood samples from adult rats enables the design of complex experiments in which time course information or evaluation of repeated treatments is necessary. Furthermore, it reduces the number of animals necessary to acquire such information and, thus, facilitates compliance with the animal use 3Rs (reduction, refinement and replacement). To this end, a microsurgical technique to collect blood samples from the right atrium through a catheter (cannula) implanted into the right external jugular vein of adult rats is described. Rats tolerate this simple and efficient vascular access technique as evidenced by the absence of overt morbidity or abnormal behaviors. Blood is easily sampled while the rats reside in their home cages. Because the sample volume is replaced, repeated sampling is possible without compromising blood volume. Successful adoption of this procedure by other investigators will be aided by the photographic illustrations accompanying this detailed description of the procedure. Application of this technique to monitor temporal changes in plasma stress hormones during stressor paradigms as well as after behavioral and pharmacological challenges is discussed.

Cerebral glucose utilization in transgenic mice overexpressing heat shock protein 70 is altered by dizocilpine

Heat shock protein (HSP70), a member of the 70 kDa HSP superfamily, has been widely implicated in the cellular stress response to numerous insults. HSP70 may be a significant factor in cell survival following stresses such as cerebral ischaemia. The precise mechanisms by which HSP70 facilitates cell survival remain unclear. The aim of this study was to ascertain whether any differences in local cerebral glucose utilization (LCGU) existed between transgenic mice overexpressing HSP70 (HSP70 Tg) and wild- type littermate (WT) mice. LCGU was assessed using (14)C-2-deoxyglucose in HSP70 Tg and WT mice under basal conditions (intraperitoneal injection of saline) and during metabolic activation produced by NMDA receptor blockade (intraperitoneal injection of dizocilpine, 1 mg/kg). No significant alterations in LCGU were observed between saline injected HSP70 Tg and WT mice in any of the 35 brain regions analyzed. Dizocilpine injection produced significant heterogeneous alterations in LCGU in HSP70 Tg mice (24 of 35 brain regions) and in WT mice (22 of 35 brain regions) compared with saline injected mice. The distribution of altered LCGU produced by dizocilpine was similar in HSP70 Tg and WT mice. However in five brain regions, dizocilpine injected HSP70 Tg mice displayed significantly altered LCGU compared to dizocilpine injected WT mice (anterior thalamic nucleus +27%, dorsal CA1 stratum lacunosum molecularae +22%, dorsal CA1 stratum oriens + 14%, superior olivary body -26%, and the nucleus of the lateral lemniscus -16%). These data highlight that while overexpression of HSP70 transgene does not significantly alter LCGU in the basal state, mice overexpressing the HSP70 transgene respond differently to metabolic stress produced by NMDA receptor blockade in some important brain regions.

Alterations in cerebral blood flow and glucose utilization in mice overexpressing the amyloid precursor protein

We have used quantitative autoradiographic techniques to study the relationship between cerebral blood flow (CBF) and glucose utilization (CGU) in two lines of transgenic mice overexpressing Swedish mutant amyloid precursor protein (APP) and APP-derived Abeta peptides. Mice were studied at an age when there are no amyloid plaques. In the 2123 line, CBF was reduced only in telencephalic regions with no corresponding decrease in CGU. In 2576 transgenics, a line with higher levels of Abeta peptide, both CBF and CGU were reduced throughout the brain. The data indicate that Abeta induces alterations in resting CBF that are either associated with or independent of alterations in CGU and that occur in the absence of amyloid deposition in neuropil of blood vessels. These observations support the hypothesis that cerebrovascular and metabolic abnormalities are early events in the pathogenesis of Alzheimer's disease.

Brain mediation of Anolis social dominance displays. I. Differential basal ganglia activation

Ritualistic displays of aggressive intent are important social signals, often obviating physically dangerous engagement. To date, however, brain regions mediating such behaviors are not established. Here we used male Anolis carolinensis together with an in vivo 14C-2-deoxyglucose method to determine patterns of brain activation during elicitation of this animal's dominance displays vs. other behaviors. By patching one eye regional brain activation in the hemisphere receiving display-evocative visual stimuli ('seeing' side) was compared to activity in the contralateral brain that did not see specific stimuli ('patched' side); this was quantitated as the ratio of seeing/patched activity for brain regions of interest. Lone males displaying dominantly to mirrors activated dorsolateral basal ganglia (BG) in the seeing, compared to the patched hemisphere; this was not seen in various non-displaying controls. Degree of dorsolateral BG activation also correlated with a measure of dominant display activity, but not with locomotion. In socially stable pairs, displaying dominants showed similar activation of dorsolateral BG, but deactivated ventromedial BG; non-dominant cagemates displaying submissively had the opposite pattern. When cohabiting peacefully without displaying, paired dominants' and subordinates' brain activity patterns were similar to each other. Thus, different BG subsystems seem involved in dominant vs. submissive display behaviors. Given similarities in both social displays and BG organization, homologous brain systems might have similar functions in members of other amniote classes, including primates.

Mapping cerebral glucose metabolism during spatial learning: interactions of development and traumatic brain injury

Previous studies have demonstrated that, compared to adults, postnatal day 17 (P17) and P28 rats show remarkable cognitive recovery in the Morris water maze (MWM) following fluid percussion injury (FPI). This observed age-at-trauma effect could result from either younger animals solving the MWM task using noninjured neural circuitry or an inability of adult and P28 brains to activate appropriate neural networks due to trauma-induced neurological dysfunction. To address these possibilities, we compared "activated" brain regions during normal MWM acquisition and following FP injury. To generate "activated" images of the brain while animals were performing the MWM task, qualitative [14C]2-deoxy-D-glucose was conducted on days 2, 5, and 14 during training in sham and injured adult, P28, and P17 rats. When maturational changes in cerebral glucose metabolism are taken into account, the results suggests similar activity changes in the cerebral cortex and lacunosum moleculare of CA1 during acquisition in all age groups, suggesting that the developmental rates of MWM learning do not correspond to different patterns of activated cerebral metabolism. Injured P17s, showing no latency deficits, revealed activated cerebral metabolic patterns similar to noninjured P17 animals. In P28 and adult cases, animals exhibited cognitive deficits and their metabolic studies indicated that the cortical-hippocampal pattern of activation was disrupted by marked injury-induced metabolic depression, which primarily affected the ipsilateral hemisphere and lasted for as long as 14 days in adult animals.

Exogenous A beta1-40 reproduces cerebrovascular alterations resulting from amyloid precursor protein overexpression in mice

Transgenic mice overexpressing the amyloid precursor protein (APP) have a profound impairment in endothelium-dependent cerebrovascular responses that is counteracted by the superoxide scavenger superoxide dismutase (SOD). The authors investigated whether the amyloid-beta peptide (A beta) is responsible for the cerebrovascular effects of APP overexpression. Cerebral blood flow (CBF) was monitored by a laser-Doppler flowmeter in anesthetized-ventilated mice equipped with a cranial window. Superfusion of A beta1-40 on the neocortex reduced resting CBF in a dose-dependent fashion (-29% +/- 7% at 5 micromol/L) and attenuated the increase in CBF produced by the endothelium-dependent vasodilators acetylcholine (-41% +/- 8%), bradykinin (-39% +/- 9%), and the calcium ionophore A23187 (-37% +/- 5%). A beta1-40 did not influence the CBF increases produced by the endothelium-independent vasodilators S-nitroso-N-acetylpenicillamine and hypercapnia. In contrast, A beta1-42 did not attenuate resting CBF or the CBF increases produced by endothelium-dependent vasodilators. Cerebrovascular effects of A beta1-40 were reversed by the superoxide scavengers SOD or MnTBAP. Furthermore, substitution of methionine 35 with norleucine, a mutation that blocks the ability of A beta to generate reactive oxygen species, abolished A beta1-40 vasoactivity. The authors conclude that A beta1-40, but not A beta1-42, reproduces the cerebrovascular alterations observed in APP transgenics. Thus, A beta1-40 could play a role in the cerebrovascular alterations observed in Alzheimer's dementia.

Abeta 1-40-related reduction in functional hyperemia in mouse neocortex during somatosensory activation

Peptides derived from proteolytic processing of the beta-amyloid precursor protein (APP), including the amyloid-beta peptide (Abeta), play a critical role in the pathogenesis of Alzheimer's dementia. We report that transgenic mice overexpressing APP and Abeta have a profound attenuation in the increase in neocortical blood flow elicited by somatosensory activation. The impairment is highly correlated with brain Abeta concentration and is reproduced in normal mice by topical neocortical application of exogenous Abeta1-40 but not Abeta1-42. Overexpression of M146L mutant presenilin-1 in APP mice enhances the production of Abeta1-42 severalfold, but it does not produce a commensurate attenuation of the hyperemic response. APP and Abeta overexpression do not diminish the intensity of neural activation, as reflected by the increase in somatosensory cortex glucose usage. Thus, Abeta-induced alterations in functional hyperemia produce a potentially deleterious mismatch between substrate delivery and energy demands imposed by neural activity.

MR volumetric analysis of the human basal ganglia: normative data

RATIONALE AND OBJECTIVES

The authors undertook this study to identify a precise, semiautomated, reproducible magnetic resonance (MR) imaging technique for measuring the basal ganglia, to establish normative volumetric data, and to verify the presence of previously reported asymmetries.

MATERIALS AND METHODS

Twenty-eight healthy adults underwent cranial MR examination. The volumes of the various components of the basal ganglia were measured by means of a combination of thresholding and manual tracing techniques performed with specialized software. The validity of these measurements was assessed by fashioning, imaging, and measuring a practical basal ganglia phantom. Measurement accuracy was also established by means of inter- and intrarater reliability indexes. Normalized volumes were statistically analyzed with analysis of variance and paired t tests.

RESULTS

The absolute values of the various components of the basal ganglia varied widely even though the volumes were normalized to differences in intracranial volume. The right caudate nucleus volume was significantly (P < .000001) larger than the left in both men and women and in both right-handed and non-right-handed subjects. This asymmetry led to an increase in the overall volume of the basal ganglia on the right.

CONCLUSION

The authors have defined a precise, reproducible technique for measuring various components of the basal ganglia and have established normative data. The basal ganglia, similar to other brain structures, exhibit hemispheric lateralization.

Cyclooxygenase-2 contributes to functional hyperemia in whisker-barrel cortex

The prostanoid-synthesizing enzyme cyclooxygenase-2 (COX-2) is expressed in selected cerebral cortical neurons and is involved in synaptic signaling. We sought to determine whether COX-2 participates in the increase in cerebral blood flow produced by synaptic activity in the somatosensory cortex. In anesthetized mice, the vibrissae were stimulated mechanically, and cerebral blood flow was recorded in the contralateral somatosensory cortex by a laser-Doppler probe. We found that the COX-2 inhibitor NS-398 attenuates the increase in somatosensory cortex blood flow produced by vibrissal stimulation. Furthermore, the flow response was impaired in mice lacking the COX-2 gene, whereas the associated increase in whisker-barrel cortex glucose use was not affected. The increases in cerebral blood flow produced by hypercapnia, acetylcholine, or bradykinin were not attenuated by NS-398, nor did they differ between wild-type and COX-2 null mice. The findings provide evidence for a previously unrecognized role of COX-2 in the mechanisms coupling synaptic activity to neocortical blood flow and provide an insight into one of the functions of constitutive COX-2 in the CNS.

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

[3H]-2-deoxyglucose uptake study in mutant dystonic hamsters: abnormalities in discrete brain regions of the motor system

The genetically dystonic (dtSZ) hamster, an animal model of idiopathic paroxysmal dystonia, displays attacks of generalized twisting movements and abnormal postures of limbs and trunk either spontaneously or in response to mild stress. This experimental model may be helpful to give insights into the pathophysiology of idiopathic dystonia in man. In the present study, the regional uptake of [3H]-2-deoxyglucose (2-DG) was examined in brains (75 brain regions) of dtSZ hamsters during the expression of severe dystonia. 2-DG autoradiography revealed significant changes of 2-DG uptake in discrete brain regions of dtSZ hamsters compared with age-matched, nondystonic control hamsters. In dystonic hamsters, a dramatic increase of 2-DG uptake was observed in the red nucleus (159% over control). Furthermore, enhanced 2-DG uptake was found in the ventromedial, ventrolateral, and anteroventral nuclei of the thalamus (19-42%) and in the medial vestibular nucleus (23%). A significant decrease in 2-DG uptake in deep cerebellar nuclei (-30%) may be the result of decreased synaptic activity of GABAergic neurons within these structures resulting in enhanced excitatory output to red nucleus, thalamic, and vestibular nuclei. In dtSZ hamsters, the 2-DG uptake was not significantly altered overall within the basal ganglia. Significant increases of 14% were, however, found in discrete parts of the caudate putamen in which recent studies revealed changes of dopamine receptors. Altered neural activity within the basal ganglia may therefore contribute to increased 2-DG uptake in the ventral thalamic nuclei as well as to decreased 2-DG uptake (-13%) found in the reticular thalamic nucleus. Although the present data are in line with the concept that abnormal thalamocortical activity seems to be critically involved in the dystonic syndrome, altered activities in other motor areas than output structures of the basal ganglia, such as in the red nucleus, may contribute to clinical manifestation of dystonia in mutant hamsters.

Antinociceptive action of vaginocervical stimulation in rat spinal cord: 2-DG analysis

Using [14C] 2-deoxyglucose (2-DG) autoradiography with computerized densitometric analysis, unilateral foot pinch was found to significantly increase the relative optical density in laminae I and II of the ipsilateral, compared to the contralateral, spinal cord at lumbar 5 (L5). However, during vaginocervical mechanostimulation applied concurrently with the unilateral foot pinch, no comparable difference was observed. No response to foot pinch was observed in other laminae of the spinal cord at L5, and no effects comparable to the above were observed at L3. These findings indicate that vaginocervical mechanostimulation suppresses neural responses to noxious foot pinch stimulation selectively at the laminae I and II level of the spinal cord at L5, but not at L3.

Effects of stress and hypophysectomy on the uptake of [3H]2-deoxy-D-glucose in the mouse adrenal medulla: an autoradiographic study

Effects of immobilization stress and hypophysectomy on the uptake of [3H] 2-deoxy-D-glucose (2DG) in the adrenal medulla of the mouse was examined by autoradiography. Radioactivity due to [3H]2DG in both adrenaline-storing and noradrenaline-storing cells was markedly increased by acute immobilization stress. Under immobilization stress, adrenaline-storing cells incorporated more 2DG than noradrenaline-storing cells. Adrenal denervation did not change the uptake of 2DG either in control or in stressed adrenal medulla. The uptake of [3H]2DG was also increased by hypophysectomy. Since withdrawal of cortical steroid hormones enhanced the uptake of 2DG and the adrenal denervation did not change the uptake, it is suggested that certain substances, such as bradykinin or histamine, which are released on immobilization stress from certain tissues other than sympathetic nerve endings in the medulla, enhanced the uptake of [3H]2DG. This phenomenon occurs mainly in adrenaline-storing cells.

Phlorizin enhancement of memory in rats and mice

Glucose administration near the time of training or testing elevates blood glucose levels and enhances memory in rodents and humans. The magnitude of increases in circulating glucose levels predicts later retention performance in these and several other situations. Thus, circulating glucose levels appear to contribute to the regulation of memory storage processes. Phlorizin is an inhibitor of glucose transport, which, in view of the effects of glucose on memory, should impair memory. However, rats and mice injected with phlorizin before training in an inhibitory (passive) avoidance task demonstrated significantly enhanced memory performance compared to that of control animals. The effective dose of phlorizin did not significantly change regional brain-relative 3H-2-deoxyglucose uptake or plasma glucose levels. To summarize, phlorizin is a potent memory-enhancing drug. While the mechanism of this enhancement is unknown, it does not appear to include changes in blood glucose levels or brain glucose uptake.

Autoradiography of hypothalamic regions after acute hyperosmolarity in mice

Many regions around the third ventricle of the brain are thought to participate in the regulation of water intake. In this study we have visualized in acutely hyperosmolar mice the hypothalamic regions by using autoradiography and [14C]deoxyglucose as marker. By applying a recently published, inexpensive, calibrated photographic method for the analysis of the autoradiographs, we can show that the medial parts of the hypothalamus near the third ventricle increased their uptake of deoxyglucose in comparison with the lateral parts. Densitometric measurements confirmed the results. The results also indicate that parts of the medial hypothalamus, even those that are more caudal than the paraventricular nuclei, react to hyperosmolarity.

Role of dialysable solutes in the mediation of uremic encephalopathy in the rat

This study addresses mechanisms of the clinical, encephalopathic uremic illness and its suppression by dialysis. Renoprival rats were treated with peritoneal dialysis (8 exchanges per day, 30 min dwell), or untreated (attrition group), and their EEG's were automatically sampled overnight and subjected to power spectrum analysis as an index of encephalopathy. As in man the background rhythm of the quantified EEG (Q.EEG) in the attrition group slowed with time as extracellular fluid composition became increasingly abnormal; these changes were normalized by therapeutic dialysis (TD) using standard, commercial dialysate. However, Q.EEG slowing was only partially normalized by solute-specific dialysis using "mock uremic dialysate" (M-UD), prepared from laboratory chemicals to equal plasma concentrations in preterminal uremic rats of urea, creatinine, potassium, phosphorus, calcium, magnesium, bicarbonate, sodium, and chloride. When only phosphate was added to TD, the Q.EEG slowed to the same level achieved after M-UD. We conclude that uremic encephalopathy in this model is produced by an unknown neurotoxin and augmented by one or more of the M-UD solutes, phosphate being a likely candidate. To localize the encephalopathic effect, regional brain glucose uptake was estimated in 20 discrete brain areas. Significance of reduced uptake in three areas is discussed.

Effect of injections of contrast media on regional uptake of (14C)-2-deoxyglucose by the rat brain

Mechanisms contributing to the rare but consistent neurotoxicity of contrast media currently in clinical use for the radiological examination of the subarachnoid space remain to be isolated. We assessed, by means of the (14C)-2-deoxy-D-glucose (2-DG) autoradiographic method, the effect of three non-ionic, low-osmolar contrast media, namely metrizamide, iopamidol and iohexol, on the local cerebral glucose utilization in the rat brain after intracisternal application. A significant (-30%) global reduction of the brain's metabolic activity occurred following intracisternal metrizamide injection. When compared with the mock-CSF control group the greater relative changes were observed in the supratentorial grey matter structures. In contrast, no significant changes were observed in metabolic brain activity in rats treated intracisternally with iopamidol and iohexol. These findings were consistent with the hypothesis that metrizamide is a competitive inhibitor of human brain hexokinase. The apparent lack of interference on neural tissue metabolism makes the second generation contrast media less neurotoxic and more suitable for neuroradiological subarachnoid investigations in clinical settings. The present experimental work establishes the 2-DG method as a viable laboratory approach to investigate aspects of neuronal dysfunction induced by contrast media.

Restriction of enhanced [2-14C]deoxyglucose utilization to rhinencephalic structures in immature amygdala-kindled rats

Sixteen-day-old albino rat pups were kindled to varying degrees of seizure severity with amygdala stimulations spaced 15 to 20 min apart. Subsequently, each rat pup was injected (ip) with 10 microCi of [2-14C]-deoxyglucose, and received several additional kindled seizures at regular intervals throughout the following 80 min, at which time it was killed and processed for deoxyglucose autoradiography. Increased seizure severity was associated with correspondingly increased deoxyglucose utilization in many rhinencephalic limbic structures. However, unlike adults, rat pups did not show discernibly increased neocortical, thalamic, or substantia nigra utilization. We postulate that the apparent confinement of seizure activity to limbic structures in pups is related to their relative lack of postictal seizure refractoriness, as well as to other indices of increased seizure susceptibility in immature animals.

The uptake of [14C]deoxyglucose into brain of young rats with inherited hydrocephalus

The effect of hydrocephalus on cerebral glucose utilization as reflected by deoxyglucose uptake has been examined in rats with inherited hydrocephalus at 10, 20, and 28 days after birth using a semiquantitative method. Injection of [14C]deoxyglucose intraperitoneally was followed by freezing the brain, sectioning, and quantitative autoradiography of 10 brain regions. Brain [14C] concentration, cortical thickness, and plasma glucose concentrations were measured. Maximal thinning of the cerebral cortex had already occurred by 10 days after birth, although obvious symptoms such as gait disturbance developed after 20 days. In control rats, the cerebral isotope concentration was lower and more homogeneous at 10 days than at 20 or 28 days, which may be a reflection of the use of metabolic substrates other than glucose in younger animals. In order to make comparisons between control and hydrocephalic groups, tissue isotope concentrations were normalized to cerebellar cortex which was not affected by the hydrocephalus at any age. In hydrocephalic rats at 10 and 20 days, the concentration of [14C] was lower in all areas except the inferior colliculi and pons but the reduction was only significant in the sensory-motor cortex at 10 days and in the caudate nuclei at 20 days. By 28 days after birth, all areas except the cerebellum (six cortical regions, inferior colliculi, pons, and caudate) had significantly lower isotope concentrations in the hydrocephalic group. It is concluded that cerebral glucose metabolism is significantly reduced by 28 days after birth in H-Tx rats with congenital hydrocephalus and that less marked reductions occur prior to 28 days.

Comparison of the effects of central and peripheral aluminum administration on regional 2-deoxy-D-glucose incorporation in the rat brain

Intracerebroventricular (ICV) Injection of aluminum tartrate (ALT 205.7 mcg) in the rat induces a progressive encephalopathy characterized by neurobehavioral derangements, by the slowing of the background rhythm of the quantitative electroencephalogram and by learning and memory deficits. The condition, lethal within about 35 days, is associated with a reduced ability of cerebral synaptosomes to incorporate radiolabeled 2-Deoxy-D-glucose (2DG) in vitro. The present study surveyed and compared the in vivo regional cerebral glucose uptake (rCGlu) capacity of rats injected with ALT 7 or 14 days previously either by the ICV or intraperitoneal (120 mg/Kg) routes. ICV injection produces transient rCGlu depression in caudate-putamen, geniculate bodies and periaquaeductal gray, resolving by day 14. Thalamic nuclei exhibit depressed rCGlu by the 7th day undergoing further depression by day 14. The rCGlu of occipitoparietal cortices, normal at day 7, was increased by day 14. In contrast, peripheral aluminum administration produced transient rCGlu depression in olfactory bulbs, frontal and occipitoparietal cortices, nucleus accumbens and cerebellum, and transiently increased rCGlu in the geniculate nuclei. These effects, present by day 7, had resolved by day 14 when rCGlu had increased in the previously normal pontine nuclei and decreased in the previously normal hippocampus. Neither treatment changed rCGlu in the septal nuclei, globus pallidus, amygdala, olfactory cortex, substantia nigra, superior or inferior colliculi or the medullary nuclei. The pattern of anomalies in cerebral 2DG incorporation most probably indexes the deranged glucoregulatory and metabolic demands of these brain areas in the aluminum intoxicated state.

Distribution of [3H]deoxyglucose and [3H]dopamine in the adrenal medulla and nerve endings of the mouse

Distribution of [3H]deoxyglucose- and [3H]dopamine-derived radioactivity in the mouse adrenal medulla and nerve endings in the capsule was examined by autoradiography. Nerve endings and medullary chromaffin cells exhibited an accumulation of [3H]dopamine but not [3H]deoxyglucose, indicating that their amine uptake system does not require high glucose consumption rate as is required to generate action potential. The study also indicated that uneven capacity in handling dopamine within a single type of chromaffin cell; peripheral cells incorporate more dopamine than those in the center, was not due to different rate of glucose utilization.

Cerebral glucose uptake in lindane-treated rats

The pesticide and ectoparasiticide lindane, gamma-isomer of hexachlorocyclohexane, is a powerful CNS-stimulant inducing convulsions and other signs of hyperexcitability in mammals. The present work was carried out to investigate the effect of lindane on brain regional glucose uptake at convulsant and non-convulsant doses. Local glucose uptake was measured in male Wistar rats using a modification of the 2-deoxyglucose (2-DG) method. Animals received i.p. [3H]2-DG and the amount of label in different brain structures of control and lindane-treated animals was assayed by a liquid scintillation counting of 18 dissected regions. Lindane at single convulsant dose (150 mg/kg, p.o.) increased 2-DG uptake in olfactory tubercules, hypothalamus, hippocampus, parafloculi and hypophysis. The uptake was decreased in parietal cortex, thalamus and pons-medulla. The pattern of 2-DG uptake after a single non-convulsant dose of 30 mg/kg p.o. was not so modified. After 1 week of treatment with 10 mg/kg per day p.o., increased 2-DG uptake was observed in superior colliculi while it was decreased in parietal cortex. The increase of 2-DG uptake in limbic regions observed at the convulsive dose agrees with the experimental association between poisoning signs induced by lindane and damage in the limbic system.

Specificity of spatial patterns of glomerular activation in the mouse olfactory bulb: computer-assisted image analysis of 2-deoxyglucose autoradiograms

We have developed a computer-assisted method for analyzing the 2-deoxyglucose (2-DG) autoradiograms of mice olfactory bulbs. The purpose of the study was to numerize the maps of glomerular activation in order to achieve a statistical comparison of the glomerular patterns evoked by different stimuli. The spatial distribution of glomerular activation was displayed on unfolded representations of the glomerular layer which were built up using glomerular optical densities (OD) measured systematically within 13 sections per bulb. Each bulbar sample was converted into an 'OD profile'. A matrix composed of 18 OD profiles was submitted to a principal component analysis. The first factor which accounted for 28% of the variance separated unambiguously two clusters corresponding to the bulbs issued from animals stimulated with amylacetate and isovaleric acid, respectively. The second and third factors which accounted for 14% and 12% of the variance segregated the control group (animals exposed to pure air) from the odor-stimulated ones. It was demonstrated that the cluster separation was actually due to the specific spatial distribution of the most-labelled glomeruli. A particular attention was paid to the well-delineated glomerular activation evoked by isovaleric acid. The results demonstrate the specificity and reliability of the glomerular 2-DG patterns. The method should be useful for further comparisons of patterns elicited by larger sets of odorant compounds.

Effects of sex and reproductive state on acoustic responsiveness in hamsters

Semi-quantitative [14C]2-deoxyglucose (2DG) autoradiography was used to describe the responses of hamsters to 35 kHz mimics of the "ultrasounds" used for communication during mating. The first study examined the processing of ultrasounds and ambient noise by estrous females, some of which were deafened or hemideafened with plastic ear plugs. These data failed to reveal responses specific to the ultrasounds. However, lateralized responses to the ambient noise were apparent, especially in the hemideafened subjects. For the ventral cochlear nucleus (VCN), 2DG uptake was elevated contralateral to the plug and ipsilateral to the effective stimulus. In contrast, uptake by more rostral structures (dorsal n. of the lateral lemniscus = DNLL; ventral n. of the lateral lemniscus = VNLL; central n. of the inferior colliculus = CIC; medial geniculate n.) was elevated contralateral to the stimulus. A second experiment examined the responses of intact or castrated male and female hamsters to unilaterally presented ultrasounds and ambient noise. As before, relative levels of 2DG uptake differed across hemispheres for structures including the VCN, trapezoid body, VNLL, DNLL, and CIC. More surprisingly, intact females showed more 2DG uptake than males in the DNLL, auditory nerve, and lateral lemniscus. Females also tended to show elevated anterior hypothalamic uptake, but just in the hemisphere contralateral to the stimulus. These results suggest that male and female hamsters differ in acoustic responsiveness, and that this difference is mediated by hormonal effects at several brainstem components of the central auditory system.

Effect of Piracetam on electrocorticogram and local cerebral glucose utilization in the rat

The effect of Piracetam on hypoxia-induced alterations of cerebral cortex electrogenesis is studied. The results showed protection. As this anti-hypoxidotic property could be linked to Piracetam influence on energy-metabolic processes in the brain, we studied the effect of this nootropic drug on local cerebral glucose utilization (LCGU) by means of a variant of the Sokoloff's technique. Our results showed that Piracetam enhances LCGU. We suggest that both effects, the functional and the metabolic one, are related.

Single vibrissal cortical column in the mouse labeled with 2-deoxyglucose

Columnar labeling was found in the primary somatosensory cortex of mice after stimulation of a single mystacial vibrissa following 2-deoxyglucose injection. The cortical vibrissal column had a cylindrical shape, passing through all layers of the cortex and was centered upon the appropriate vibrisal barrel. Columnar labeling extended beyond this barrel onto parts of neighbouring barrels, particularly within the same row. The densest labeling was found in layer IV in the barrel hollow. Removal of the non-stimulated vibrissae resulted in a subsequent lowering of 2DG uptake in the barrelfield surrounding the activated column, but did not affect the dimension of the activated column.

Resting and high-frequency evoked 2-deoxyglucose uptake in the rat inferior colliculus: developmental changes and effects of short-term conduction blockade

Development of resting and high-frequency-evoked metabolic patterns in the central nucleus of the inferior colliculus (ICC) in rat was investigated using the 2-deoxyglucose (2-DG) method. The effects of early short-term acoustic deprivation were studied by unilateral blockade of the external auditory meatus on postnatal day 12. Quantitative and qualitative analyses were performed on 2-DG uptake in 5 regional sectors of ICC. Adult resting ICC uptake is robust and exhibits regional differentiation with the ventromedial region preferentially labelled. At 17 days of age, resting uptake is substantially lower and regionally more uniform than in the adult. This age-dependent change is likely a function of the immature stage of neuronal and cochlear development at 17 days. Unilateral 50 kHz stimulation in the adult results in bilaterally enhanced 2-DG incorporation in ventromedial ICC, with a discrete band of elevated uptake along the contralateral ventromedial border. 50 kHz stimulation evokes ventromedial banding in the contralateral, but not ipsilateral, ICC of undeprived 17-day-olds, though at a much reduced level relative to the adult. Following monaural conduction blockade from 12 to 17 days of age, stimulation through the reopened deprived ear elicits a band of uptake along the lateral ICC border, oblique to the normal tonotopic gradient. Cochlear mechanisms may account for modified patterning of high-frequency-evoked 2-DG uptake in ICC subsequent to conductive hearing loss during a period of elevated susceptibility to experiential factors.

Effects of rapid eye movement sleep deprivation on regional brain metabolism as measured by 2-[14C]deoxyglucose autoradiography

Regional brain metabolic activity of six male Sprague-Dawley rats was investigated with 2-[14C]deoxyglucose autoradiography. Regional brain metabolic activity was determined bilaterally for 60 brain structures, using laser densitometry. After 5 days of uninterrupted rapid eye movement sleep deprivation, increased metabolic activity was found in the lateral habenula, the caudal and middle parts of the limbic system, and in the corpus callosum.

A cheap, calibrated photographic method for the screening of X-ray film autoradiographs

This report describes the use of a calibrated photographic method for the screening of X-ray film autoradiographs. In the method the autoradiographic film is contact printed onto photographic film of high contrast, and the latter is contact printed onto photographic paper of suitable contrast. Special features of e.g. deoxyglucose-autoradiographs are thus visualized. The method is inexpensive, and it can be used as a complement to densitometric point measurements of X-ray film autoradiographs.

Uptake of [3H]2-deoxy-D-glucose and [3H]dopamine in adrenal chromaffin cells of the mouse

Deoxyglucose method was applied to adrenal chromaffin cells. It was shown that dichromate-fixation could fix [3H]deoxyglucose in tissue sections. Dichromate-fixation has two advantages as compared with glutaraldehyde-fixation: (1) two types of adrenal chromaffin cells, adrenaline-storing (A) cell and noradrenaline-storing (NA) cells, are distinguishable, (2) more [3H]deoxyglucose is retained in sections than in those fixed with glutaraldehyde. No difference was demonstrated in the uptake of deoxyglucose between A and NA cells while A cells incorporated more [3H]dopamine than NA cells. This indicates that such difference was not due to the different rate of glucose utilization.

Maturation of kainic acid seizure-brain damage syndrome in the rat. I. Clinical, electrographic and metabolic observations

The maturation of the seizure/brain damage syndrome produced by parenteral administration of kainate was studied in the rat. The motor, electrographic and metabolic alterations are described in the present report, the maturation of the pathological abnormalities and of the specific kainate binding sites are described in the two following companion papers. Parenteral kainate produces tonico-clonic seizures until the end of the third week of age when limbic motor signs (wet-dog shakes, facial myoclonia, paw tremor etc.) were first produced. Using the 2-deoxyglucose autoradiographic method, we found that in animals of 3 days of age and until the third week of age, kainate produced a rise in metabolism restricted to the hippocampus and lateral septum. This was paralleled by paroxysmal discharges which were recorded in the hippocampus. Starting from the end of the third week of age approximately--i.e. when the toxin produced limbic motor seizures--there was a rise of labelling in other structures which are part of or closely associated to the limbic system i.e. the amygdaloid complex, the mediodorsal and adjacent thalamic nuclei, piriform, entorhinal and rostral limbic cortices and areas of projection of the fornix. These metabolic maps are thus similar to those seen in adults. Two main conclusions can be drawn from these experiments: kainate activates the hippocampus from a very early age probably by means of specific receptors present in this structure and the limbic syndrome will only be produced by the toxin once the limbic circuitry--including in particular the amygdaloid complex--is activated by the procedure i.e. after the third week of age.

Phagocytic and metabolic reactions to chronically implanted metal brain electrodes

In order to study the biocompatibility of metal electrodes and insulations in the rat brain, eight different metal electrode types and two different insulations were implanted for 11, 35, 36, 37, or 63 days. Stainless steel and Nichrome were nontoxic metals, silver was toxic, and copper extremely toxic with phagocytosis active to 37 days of implantation. Active phagocytosis was easily detected by high glucose demand using 2-deoxy[14C]glucose (2-DG) autoradiography contrasted with normal 2-DG autoradiographs where phagocytes were present but not ingesting. Epoxylite, an epoxy-polyester varnish, was slightly more reactive in brain than polyimide but not statistically significant. In general, larger electrodes created more tissue reaction per se for as long as 37 days. These results suggested that a thin stainless-steel bipolar electrode will provide safe recording electrodes in either animal or human brain. The importance of these findings is that certain metals (silver, copper) cannot be used in the brain without producing necrosis and phagocytosis, whereas other metals (stainless steel, Nichrome) with varnish insulators (Epoxylite, polyimide) can be implanted without producing any detectable damage beyond that of the initial trauma and brief phagocytosis limited to the edge of the electrode track. Finally, the glucose metabolism autoradiographs differentiated active phagocytosis (copper) from inactive phagocytes (silver) when using long implants (37 days) of toxic metals.

Presynaptic dopaminergic agonists modify brain glucose metabolism in a way similar to the neuroleptics

The effects of the (+) and (-) enantiometers of 3-(3-hydroxyphenyl)-N-n-propylpiperidine (3-PPP), 9,10-didehydro-6-methyl-8 beta-(2-pyridylthiomethyl)ergoline (CF 25-397) and 6,7-dihydroxy-2-dimethyl-aminotetralin (TL 99), three agonists of the postulated presynaptic dopamine receptor, on the pattern of brain glucose metabolism were studied using the autoradiographic technique of Sokoloff et al. [19]. It was found that these drugs modify brain glucose metabolism in a way similar to the neuroleptics but different from postsynaptic agonists. These results support the suggestion that these drugs could represent a new type of neuroleptic.

Calcium antagonist binding sites in the rat brain: quantitative autoradiographic mapping using the 1,4-dihydropyridines [3H]PN 200-110 and [3H]PY 108-068

An in vitro autoradiographic technique has been used for the quantitative mapping of calcium antagonist binding sites (CABS) in the rat brain, using the 1,4-dihydropyridines [3H]PN 200-110 and [3H]PY 108-068 as ligands. CABS were distributed throughout the brain in a highly heterogeneous fashion. The highest densities of CABS were observed in the olfactory bulb, hippocampus and parts of the amygdala. The neocortex was also rich in CABS. The basal ganglia, thalamus and hypothalamus presented intermediate levels of CABS while low densities of sites were seen in areas such as the cerebellum, pons and white matter tracts. The distributions of CABS in brain does not correlate with indexes of brain blood flow, regional glucose utilization or the distributions of receptor binding sites for drugs and neurotransmitters analyzed until now. No correlation exists between CABS distribution and that of any neurotransmitter or brain enzyme described so far. The heterogeneous distributions of CABS is suggestive of a neuronal localization, an idea supported by lesion experiments.

Metabolic rate in different rat brain areas during seizures induced by a specific delta opiate receptor agonist

The glucose utilization during specific delta opiate agonist-induced epileptiform phenomena, determined by the [14C]2-deoxyglucose technique (2-DG), was examined in various rat brain areas at different time intervals. The peak in EEG spiking response and the most intensive 2-DG uptake occurred 5 min after intraventricular (i.v.t.) administration of the delta opiate receptor agonist. The most pronounced 2-DG uptake at this time interval can be observed in the subiculum, including the CA1 hippocampal area, frontal cortex and central amygdala. A general decrease of glucose consumption, compared to control values, is observed after 10 min, in all regions, with exception of the subiculum. Since functional activity and 2-DG uptake are correlated, we suggest that the subiculum and/or CA1 area, are probably the brain regions most involved in the enkephalin-induced epileptic phenomena.

Kainic acid seizure syndrome and binding sites in developing rats

In rats up to 16 days after birth, parenteral kainic acid (KA) produced tonico-clonic convulsions, metabolic activation limited to the hippocampus, and no brain damage. Starting with the 19th day after birth, KA produced limbic seizures associated with metabolic activation and subsequent damage in the hippocampus, the amygdala, and other limbic structures. Membranes prepared from hippocampi 10 days after birth bound [3H]KA with a high affinity component, which was localized in the mossy fiber region by slice autoradiography. In contrast, on amygdaloid membranes this component appeared only 17-19 days after birth. Our results further stress the crucial role of the amygdala in the KA seizure syndrome.

Acute administration of 1-N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), a compound producing parkinsonism in humans, stimulates [2-14C]deoxyglucose uptake in the regions of the catecholaminergic cell bodies in the rat and guinea pig brains

A modification of the [2-14C]deoxyglucose (2-DG) autoradiographic technique of Sokoloff et al. was used to study the effects of acute administration of 1-N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) (10 mg/kg, s.c.) in the rat and guinea pig brains. MPTP administration resulted in both species in a dramatic increase in the 2-DG uptake in the substantia nigra pars compacta, ventral tegmental area and locus ceruleus, brain areas containing the cell bodies of dopaminergic and noradrenergic neurons. Many other brain areas were not affected. In the rat the effects were time dependent, being maximal between 1 and 2 h after drug administration. The effects of MPTP on 2-DG uptake differ from those of other dopaminergic or catecholaminergic drugs and suggest a specificity of the action of this drug on catecholaminergic neurons.

The development of the vibrissal cortical column: a 2-deoxyglucose study in the rat

A column of SI cortex responding to stimulation of a single vibrissa can be visualized with [14C]2-deoxyglucose (2-DG) autoradiography. The development of C3 vibrissal column was investigated in rat pups aged 2, 4, 6, 8, 12 and 21 days. A patch of label corresponding to higher glucose utilization appeared at postnatal day (p.d.) 4 to 6 in the cortical plate. Between p.d. 6 and 12 it developed into a spindle-shaped column. The infragranular layers showed metabolic activation later than the upper laminae. The suitability of the 2-DG technique for studies of infant mammalian brain is discussed.

Harmaline induced tremor. III. A combined simple units, horseradish peroxidase, and 2-deoxyglucose study of the olivocerebellar system in the rat

Purkinje cells were recorded extracellularly and mapped in the cerebellar cortex of the rat under tremogenic doses of harmaline. Four different types of responses were encountered, of which two were considered as being responsible for the harmaline tremor. The latter had a regular firing pattern of complex spikes at 5 to 10 Hz and were mostly found in the vermis. Their number decreased in the more lateral region of the cerebellar cortex until they eventually disappeared. Horseradish peroxidase was injected into all the areas of the cerebellar cortex containing Purkinje cells with harmaline-induced activity. Labeled neurons were in all cases traced to the medial accessory olive. The metabolic activity of the inferior olive under harmaline was measured with 2-deoxyglucose. Increased labeling was only found in the medial accessory olive. Such an increase was demonstrated as being due to a direct effect of the drug on the inferior olivary neurons, indicating that the medial accessory olive is responsible for the harmaline tremor in the rat. Our results point out that, in the rat, there is an inverse relationship between serotoninergic innervation of a region in the inferior olivary nucleus and that with harmaline sensitivity, therefore a serotoninergic mechanism hypothesis for the harmaline tremor needs further investigation.