Chronic citicoline increases phosphodiesters in the brains of healthy older subjects: an in vivo phosphorus magnetic resonance spectroscopy study.

RATIONALE: Phosphatidylcholine (PtdCho) in brain cell membranes decreases with age. Evidence from both animal and in vitro studies indicates that CDP-choline (citicoline) administration may increase phosphatidylcholine (PtdCho) synthesis and might reverse PtdCho loss. OBJECTIVES: We investigated whether oral citicoline can increase PtdCho synthesis in the brains of older subjects by measuring levels of phosphorus-containing metabolites using proton-decoupled phosphorus magnetic resonance spectroscopy ((31)P-MRS) before and after citicoline treatment. METHODS: All subjects took 500 mg citicoline once orally each day for 6 weeks, then took either citicoline or placebo once orally per day for a second 6-week period. Subjects underwent a (31)P-MRS scan at baseline and following 6 and 12 weeks of treatment. RESULTS: Treatment with citicoline for 6 weeks was associated with a 7.3% increase from baseline levels in brain phosphodiesters ( P=0.008), including an 11.6% increase in glycerophosphoethanolamine ( P=0.002) and a 5.1% increase in glycerophosphocholine ( P=0.137). Subjects who continued to take citicoline for the second 6-week period did not show significant additional increases in the levels of these metabolites. No changes were seen in other phosphorus-containing metabolites. There was a correlation between improvement on the California Verbal Learning Test and increase in phosphodiesters. CONCLUSIONS: The increases in phosphodiesters seen in this study indicate that phospholipid synthesis and turnover were stimulated by 6 weeks of oral citicoline. These results in humans support previous in vitro and animal studies and suggest that the administration of oral citicoline may be of use in reversing age-related changes in the brain.

Choline, myo-inositol and mood in bipolar disorder: a proton magnetic resonance spectroscopic imaging study of the anterior cingulate cortex.

OBJECTIVES: Alterations in choline and myo-inositol metabolism have been noted in bipolar disorder, and the therapeutic efficacy of lithium in mania may be related to these effects. We wished to determine the relationship between anterior cingulate cortex choline and myo-inositol levels, assessed using proton magnetic resonance spectroscopic imaging (MRSI), and mood state in subjects with bipolar disorder. METHODS: Serial assessments of anterior cingulate cortex choline and myo-inositol metabolism were performed in nine subjects with bipolar disorder, taking either lithium or valproate, and 14 controls. Each bipolar subject was examined between one and four times (3.1 +/- 1.3). On the occasion of each examination, standardized ratings of both depression and mania were recorded. RESULTS: In the left cingulate cortex, the bipolar subjects' depression ratings correlated positively with MRSI measures of Cho/Cr-PCr. In the right cingulate cortex, the Cho/Cr-PCr ratio was significantly higher in subjects with bipolar disorder compared with control subjects. In addition, bipolar subjects not taking antidepressants had a significantly higher right cingulate cortex Cho/Cr-PCr ratio compared with patients taking antidepressants or controls. No clinical or drug-related changes were observed for the Ino/Cr-PCr ratio. CONCLUSIONS: The results of this study suggest that bipolar disorder is associated with alterations in the metabolism of cytosolic, choline-containing compounds in the anterior cingulate cortex. As this resonance arises primarily from phosphocholine and glycerophosphocholine, both of which are metabolites of phosphatidylcholine, these results are consistent with impaired intraneuronal signaling mechanisms.

Measurement of human brain dexfenfluramine concentration by 19F magnetic resonance spectroscopy.

OBJECTIVE: The goals of this study were to quantitate the brain concentration of the anorectic drug dexfenfluramine (DF) in human subjects receiving clinical doses of DF and to determine whether human brain DF concentrations approach those reported to cause irreversible neurochemical changes in animals. Each subject's brain DF concentration was measured several times over an extended period of DF treatment to determine whether drug accumulation in the brain would plateau or continue to increase throughout the treatment period. DESIGN: Fluorine magnetic resonance spectroscopy (19F-MRS) was used to directly detect and quantitate brain levels of the fluorinated drug dexfenfluramine and its active metabolite dex-norfenfluramine (dNF). Patients received 15 mg dexfenfluramine BID for 90 days. 19F-MRS measurements were performed at baseline and at three times during the treatment period. PARTICIPANTS: Twelve women (age 38-54 years) who were obese, with body mass indices of 28. 4-37.4, but otherwise healthy. RESULTS: The combined concentration of DF and nDF reached steady-state in the human brain after approximately 10 days of treatment. The steady-state brain concentration averaged approximately 4 microM and did not tend to increase significantly during the 90 day treatment period. CONCLUSIONS: These results demonstrate that fluorinated drugs can be quantified using 19F MRS at concentrations below 10 microM in the human brain. The time-course data suggest that brain DF concentrations parallel DF plasma pharmacokinetics in humans. Measured brain dexfenfluramine/nor-dexfenfluramine concentrations were well below levels previously found to cause irreversible brain alterations in animals.

Quantitation of dexfenfluramine/d-norfenfluramine concentration in primate brain using 19F NMR spectroscopy.

Fluorine (19F) magnetic resonance spectroscopy (MRS) was used to quantify the combined concentration of the anorectic drug dexfenfluramine (DF) and its active metabolite d-norfenfluramine (dNF) in rhesus monkey brain. The accuracy of the MRS technique was assessed by comparison with gas chromatography. Brain 19F MRS signals were converted to brain DF + dNF concentrations after correction for signal relaxation losses and drug distribution in nonbrain tissue. Gas chromatography (GC) was used to assay brain DF and dNF concentrations following MRS evaluation. DF + dNF concentrations measured by 19F MRS averaged 104 +/- 36 microM (mean +/- SD) and GC measurements averaged 71 +/- 12 microM. Correction for the distribution of DF and its metabolites in nonbrain tissue yielded a DF + metabolite brain concentration that was within one standard deviation of the GC-derived value. The concentration of DF plus dNF measured by 19F MRS was similar to or greater than the value obtained by GC, which indicates that DF and its active metabolite dNF are fully detected by 19F MRS in primate brain in vivo. The application of these techniques to human subjects should enable the measurement of low micromolar-range brain concentrations of DF and other fluorinated drugs.

Basal ganglia choline levels in depression and response to fluoxetine treatment: an in vivo proton magnetic resonance spectroscopy study.

We have investigated proton magnetic resonance spectra of the basal ganglia in 41 medication-free outpatients with major depression, prior to starting an 8-week standardized trial of open-label fluoxetine, and 22 matched comparison subjects. Upon completing the trial, depressed subjects were classified as treatment responders (n = 18) or nonresponders (n = 23), based on changes in the Hamilton Depression Rating Scale. Depressed subjects had a lower area ratio of the choline resonance to the creatine resonance (Cho/Cr) than comparison subjects. This statistically significant difference between the depressed subjects and comparison subjects was more pronounced in the treatment responders than in the nonresponders. There were no differences in the relative volumes of gray matter or white matter in the voxel used for proton spectroscopy in depressed subjects relative to comparison subjects. These results are consistent with an alteration in the metabolism of cytosolic choline compounds in the basal ganglia of depressed subjects and, in particular, those who are responsive to fluoxetine.

Differential effect of CDP-choline on brain cytosolic choline levels in younger and older subjects as measured by proton magnetic resonance spectroscopy.

Phosphatidylcholine (PtdCho), which is essential for membrane integrity and repair, is reduced in brain cell membranes with age. Evidence from both animal and in vitro studies indicates that cytidine 5' diphosphate choline (CDP-choline) can increase the synthesis of PtdCho; however, the effect of CDP-choline on brain choline metabolism has not previously been studied in human subjects. In this study, in vivo proton magnetic resonance spectroscopy (1H-MRS) was used to measure brain levels of cytosolic, choline-containing compounds before and after single oral doses of CDP-choline. Three hours after dosing, plasma choline increased similarly in younger (mean age 25 years) and older subjects (mean age 59 years). However, while the choline resonance in brain increased by 18% on average in younger subjects, it decreased by almost 6% in older subjects (P = 0.028). These results may be explained by a previously observed decrease in brain choline uptake, but not cytidine uptake, in older subjects. Additional intracellular cytidine following the administration of CDP-choline should lead to the increased incorporation of choline already present in brain into membrane PtdCho, which is not MRS-visible, consequently lowering the brain choline resonance below that of pre-treatment values. These results suggest that the cytidine moiety of CDP-choline stimulates phosphatidylcholine synthesis in human brain cell membranes in older subjects.

Decreased brain choline uptake in older adults. An in vivo proton magnetic resonance spectroscopy study.

OBJECTIVE: To test the hypothesis that uptake of circulating choline into the brain decreases with age, because alterations in metabolism of choline may be a factor contributing to age-related degenerative changes in the brain. DESIGN: Cohort comparison in younger and older adults. PARTICIPANTS: Subjects were chosen consecutively from lists of healthy volunteers screened by medical and psychiatric interviews and laboratory tests. Younger adults (n = 12) were between the ages of 20 and 40 years (mean age, 32 years), and older adults (n = 16) were between the ages of 60 and 85 years (mean age, 73 years). INTERVENTIONS: After fasting overnight, subjects received choline, as the bitartrate, to yield free choline equal to 50 mg/kg of body weight. Blood was drawn for determination of plasma choline concentration by high-performance liquid chromatography, and proton magnetic resonance spectroscopy (1H-MRS) was performed to determine the relative concentration of cytosolic choline-containing compounds in the brain at baseline and after ingestion of choline. MAIN OUTCOME MEASURES: Plasma choline and cytosolic choline-containing compounds in the brain, estimated as the ratio of the choline resonance to the creatine resonance on 1H-MRS scans of the basal ganglia, were compared following blinded analyses of data from subject cohorts studied at baseline and 3 hours after choline ingestion. RESULTS: Levels of plasma choline and cytosolic choline-containing compounds in brain were similar at baseline in younger and older subjects. Following ingestion of choline, plasma choline concentration increased by similar proportions (76% and 80%) in both younger and older subjects. Brain cytosolic choline--containing compounds increased substantially in younger subjects (mean increase, 60%; P < .001 vs baseline). Older subjects showed a much smaller increase in brain choline-containing compounds (mean, 16%; P < .001 vs the increase in younger subjects). CONCLUSION: Uptake of circulating choline into the brain decreases with age. Given the key role of choline in neuronal structure and function, this change may be a contributing factor in onset in late life of neurodegenerative, particularly dementing, illnesses in which cholinergic neurons show particular susceptibility to loss.

Persistent reduction of immediate early gene mRNA in rat forebrain following single or multiple doses of cocaine.

Stimulus-induced expression of immediate early genes (IEGs) is believed to be involved in the transduction of extracellular stimuli into prolonged modifications of cellular function. Previous studies have demonstrated that the IEGs NGFI-A (zif268) and c-fos are each rapidly induced in the caudate putamen (CP) by treatment with the indirect dopamine agonist cocaine. The short-term course of this induction has been well studied. However, the consequences of cocaine use are not limited to immediate pharmacological effects. Withdrawal, especially from prolonged or repeated use, can produce extended physiological and behavioral changes. At the cellular level, these longer-term effects may be mediated by or reflected in changes in the expression of IEGs. For this reason, we have investigated long-term perturbations in IEG expression during withdrawal from intravenously (IV) or intraperitoneally (IP) administered cocaine. Levels of NGFI-A and c-fos were measured in the CP of rats by Northern blot analysis, which confirmed that cocaine-induced increases of NGFI-A and c-fos mRNA lasts for several hours after drug administration. Immediately following this induction, however, there is a prolonged period during which a marked reduction in the relative amount of mRNA for both NGFI-A and c-fos is observed in cocaine-treated animals when compared to matched, vehicle-treated controls. This repression persisted for several hours after a single injection and as long as several days following multiple injections, strongly suggesting a cumulative effect for repeated exposures.(ABSTRACT TRUNCATED AT 250 WORDS)

Drug distribution between blood and brain as a determinant of antipsychotic drug effects.

Concentrations of the neuroleptics haloperidol, bromperidol, fluphenazine, chlorpromazine and its metabolites nor-1- and nor-2-chlorpromazine, thioridazine and its metabolites mesoridazine, sulforidazine, and northioridazine, and promazine were estimated in serum and brain of rats by high performance liquid chromatography (HPLC) with electrochemical detection following 5 days of chronic administration of drug at typical doses (haloperidol, bromperidol, and fluphenazine 1 mg/kg/day; chlorpromazine, promazine, and thioridazine 25 mg/kg/day). The observed ratio of brain-to-serum concentration of drug varied widely (0.18-62.5) among neuroleptics studied. High potency agents had more favorable brain-to-blood distribution than low potency agents, and a strong correlation (r = 0.734, p < 0.05) was observed between the brain-to-serum ratios of the neuroleptics and standard clinical doses of drug. This finding suggests that drug distribution is a significant determinant of clinical potency. For most neuroleptics, including drugs with high (fluphenazine, haloperidol) and low potency (thioridazine) such as dopamine D2 antagonists, concentration of drug in the brain was similar. If the results are applicable to patients, they suggest that the degree of dopamine D2 blockade achieved during treatment may vary by drug. Chlorpromazine and promazine were notable for producing high concentrations of drug in the brain at typical doses, suggesting that optimal doses might be lower than those in common use. These results may be important in designing and interpreting studies of the effects of neuroleptic drugs in animals and patients.

Differences between antipsychotic drugs in persistence of brain levels and behavioral effects.

After a single dose of the butyrophenone neuroleptic haloperidol, behavioral effects and detectable drug levels in rat brain can last for several weeks. To determine if such persistence is a general property of neuroleptics, we compared drug levels and effects after IP administration of two butyrophenones (haloperidol and bromperidol), a high potency (fluphenazine) and a low potency (chlorpromazine) phenothiazine. Drug levels in brain tissue were measured by high pressure liquid chromatography and behavioral effects monitored as inhibition of apomorphine-induced stereotypy. Estimated near terminal elimination half-lives (t 1/2) from brain for acutely administered chlorpromazine (20 mg/kg) and fluphenazine (1 mg/kg) were 0.41 and 0.62 days, respectively, and neither drug was detectable after 4 days. Fluphenazine given daily for 5 days showed an only slightly slower elimination (t 1/2 = 1.1 days). In contrast, near-terminal elimination half-lives from brain for haloperidol and bromperidol (both at 1 mg/kg, IP) were much longer (6.6 and 5.8 days, respectively), and each was detectable for 21 days after dosing. Inhibition of apomorphine-induced stereotypy correlated highly (r = 0.95) with brain levels of haloperidol. For fluphenazine, given once or repeatedly, early inhibition was replaced within 1 week by supersensitivity to apomorphine which persisted for up to 3 weeks. These findings, indicating marked differences in clearance and recovery times after dosing with butyrophenones and phenothiazines, have clear implications for studies of the effects of neuroleptic drugs in rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of the novel antidepressant S-adenosyl-methionine on alpha 1- and beta-adrenoceptors in rat brain.

alpha 1- and beta-adrenoceptors were studied ex vivo in the brains of rats receiving repeated daily treatment with the standard antidepressant imipramine or the atypical antidepressant S-adenosyl-L-methionine (SAM), which has minimal effects on monoamine reuptake or turnover. Consistent with past studies, a decrease in the density of beta receptors at three weeks and an increase in the affinity of alpha 1 receptors for the agonist phenylephrine at one week of treatment was observed with imipramine. By comparison, an increase in the density of beta receptors and a decrease in the affinity of alpha 1 receptors for phenylephrine was observed at one week of treatment with SAM. These changes were no longer apparent at three weeks of treatment. The results suggest that treatment with SAM does lead to changes in adrenergic neurotransmission, but that down regulation of beta receptors or increased agonist affinity of alpha 1 receptors may not be necessary for the production of antidepressant effects.

Abnormal platelet membrane composition in Alzheimer's-type dementia.

An abnormality of membranes, possibly representing an increase in internal membranes, has been reported in fluorescence spectroscopic and electron microscopic studies of platelets of patients with Alzheimer's-type dementia (AD). To further define this abnormality, the cholesterol and phospholipid content of platelet and erythrocyte membranes was determined and compared for patients with AD and matched control subjects. No significant differences in either cholesterol or phospholipid, per se, were observed in comparing platelets from subjects in the two study groups. However, the ratio of cholesterol to phospholipid was significantly lower (p less than 0.01) in the platelets of patients with AD (9.37 +/- 1.11) than in the platelets of control subjects (10.20 +/- 1.04). Furthermore, the cholesterol to phospholipid ratio correlated significantly (rs = 0.53, p less than 0.01) with a separately determined measure of platelet membrane characteristics, the steady-state anisotropy of DPH (diphenylhexatriene). No differences were observed between the study groups for any of the same parameters measured in erythrocytes, which lack internal membranes. The findings suggest that there is no general abnormality of membrane lipids in Alzheimer's-type dementia. Rather, because normal internal membranes are reported to be low in their cholesterol to phospholipid ratio and in anisotropy of DPH, the results of these studies, together with the results of studies employing electron microscopy, suggest that platelets of patients with AD have an increase in internal membranes. Such membranes, while present in excess, may be normal in composition.