Citicoline enhances frontal lobe bioenergetics as measured by phosphorus magnetic resonance spectroscopy.

Citicoline supplementation has been used to ameliorate memory disturbances in older people and those with Alzheimer's disease. This study used MRS to characterize the effects of citicoline on high-energy phosphate metabolites and constituents of membrane synthesis in the frontal lobe. Phosphorus ((31)P) metabolite data were acquired using a three-dimensional chemical-shift imaging protocol at 4 T from 16 healthy men and women (mean +/- SD age 47.3 +/- 5.4 years) who orally self-administered 500 mg or 2000 mg Cognizin Citicoline (Kyowa Hakko Kogyo Co., Ltd, Ibaraki, Japan) for 6 weeks. Individual (31)P metabolites were quantified in the frontal lobe (anterior cingulate cortex) and a comparison region (parieto-occipital cortex). Significant increases in phosphocreatine (+7%), beta-nucleoside triphosphates (largely ATP in brain, +14%) and the ratio of phosphocreatine to inorganic phosphate (+32%), as well as significant changes in membrane phospholipids, were observed in the anterior cingulate cortex after 6 weeks of citicoline treatment. These treatment-related alterations in phosphorus metabolites were not only regionally specific, but tended to be of greater magnitude in subjects who received the lower dose. These data show that citicoline improves frontal lobe bioenergetics and alters phospholipid membrane turnover. Citicoline supplementation may therefore help to mitigate cognitive declines associated with aging by increasing energy reserves and utilization, as well as increasing the amount of essential phospholipid membrane components needed to synthesize and maintain cell membranes.

Mitochondrial dysfunction in bipolar disorder: evidence from magnetic resonance spectroscopy research.

Magnetic resonance spectroscopy (MRS) affords a noninvasive window on in vivo brain chemistry and, as such, provides a unique opportunity to gain insight into the biochemical pathology of bipolar disorder. Studies utilizing proton ((1)H) MRS have identified changes in cerebral concentrations of N-acetyl aspartate, glutamate/glutamine, choline-containing compounds, myo-inositol, and lactate in bipolar subjects compared to normal controls, while studies using phosphorus ((31)P) MRS have examined additional alterations in levels of phosphocreatine, phosphomonoesters, and intracellular pH. We hypothesize that the majority of MRS findings in bipolar subjects can be fit into a more cohesive bioenergetic and neurochemical model of bipolar illness that is both novel and yet in concordance with findings from complementary methodological approaches. In this review, we propose a hypothesis of mitochondrial dysfunction in bipolar disorder that involves impaired oxidative phosphorylation, a resultant shift toward glycolytic energy production, a decrease in total energy production and/or substrate availability, and altered phospholipid metabolism.

Biexponential transverse relaxation (T(2)) of the proton MRS creatine resonance in human brain.

Differences in proton MRS T(2) values for phosphocreatine (PCr) and creatine (Cr) methyl groups (3.0 ppm) were investigated in studies of phantoms and human brain. Results from phantom studies revealed that T(2) of PCr in solution is significantly shorter than T(2) of Cr. Curve-fitting results indicated that the amplitude-TE curves of the total Cr resonance at 3.0 ppm in human brain (N = 26) fit a biexponential decay model significantly better than a monoexponential decay model (P < 0.006), yielding mean T(2) values of 117 +/- 21 ms and 309 +/- 21 ms. Using a localized, long-TE (272 ms) point-resolved spectroscopy (PRESS) proton MRS during 2 min of photic stimulation (PS), an increase of 12.1% +/- 3.5% in the mean intensity of the total Cr resonance in primary visual cortex (VI) was observed at the end of stimulation (P < 0.021). This increase is consistent with the conversion of 26% of PCr in VI to Cr, which is concordant with (31)P MRS findings reported by other investigators. These results suggest a significantly shorter T(2) for PCr than for Cr in vivo. This difference possibly could be exploited to quantify regional activation in functional spectroscopy studies, and could also lead to inaccuracies in some circumstances when the Cr resonance is used as an internal standard for (1)H MRS studies in vivo.

31P Nuclear magnetic resonance spectroscopy findings in bipolar illness: a meta-analysis.

Published literature comparing 31P MR brain spectra of bipolar patients to healthy controls was evaluated, focusing on phosphomonoester (PME)/phosphodiester (PDE) resonance areas because these metabolites are related to membrane phospholipids and membrane defects in bipolar disorder have been suggested. Studies comparing PME and/or PDE values of bipolar subjects to values observed in healthy controls were reviewed. Data from the studies meeting our inclusion criteria (8 reports involving 139 bipolar and 189 comparison subjects) were grouped according to the mood state of the subjects. Meta-analyses of data were performed to compare PME and PDE levels of euthymic bipolar patients to healthy controls, as well as comparing PME levels during euthymia in bipolar subjects to values observed during manic and depressed states. The PME values of euthymic bipolar patients were found to be significantly lower than PME values of healthy controls. Depressed bipolar patients had significantly higher PME values in comparison to euthymic bipolar patients. No significant difference could be detected between the PDE values of bipolars and controls. This meta-analysis found support for trait- and possibly state-dependent abnormalities of membrane phospholipid metabolism, which may reflect a dysregulation in brain-signal transduction systems of relevance in bipolar illness.

Increased orbitofrontal cortex levels of choline in depressed adolescents as detected by in vivo proton magnetic resonance spectroscopy.

BACKGROUND: The frontal lobe has been implicated in the pathology of depression in adults. Through the use of magnetic resonance spectroscopy, altered brain choline levels have also been linked to the pathophysiology of affective disorders. METHODS: To identify possible alterations in orbitofrontal cortex levels of cytosolic choline in adolescents with and without depression, 22 depressed and 43 control adolescents were recruited. Of those recruited, usable proton magnetic resonance spectra were acquired from a voxel in the left anterior medial frontal lobe of 17 depressed (mean age 15.8+/-1.6) and 28 healthy adolescents (mean age 14.5+/-1.7). RESULTS: Orbitofrontal cytosolic choline/creatine (Cho/Cr) ratios (p =.032) and cytosolic choline/N-acetyl aspartate (Cho/NAA) ratios (p =.043) were significantly higher in the depressed subjects than in the control subjects. There were no significant differences between depressed and control subjects in gray or white matter content within the voxel. CONCLUSIONS: These findings suggest that brain cytosolic choline may be increased in depressed adolescents in comparison with control subjects and independent of a corresponding structural change. These results are consistent with similar, previously reported findings in adults and suggest that depression in adolescents is associated with alterations in orbitofrontal metabolism.

Perinatal complications and abnormal proton metabolite concentrations in frontal cortex of adolescents seen on magnetic resonance spectroscopy.

OBJECTIVE: The relation of perinatal complications to metabolism of orbitofrontal cortex was studied in 12 normal adolescents aged 13 to 17 years. BACKGROUND: Perinatal complications are associated with both (a) behavioral signs of frontal lobe dysfunction and (b) increased risk for mood disorders and schizophrenia. Perinatal complications are not usually sufficient to produce these disorders, however, suggesting an etiologic model in which perinatal complications interact with a second, familial, liability factor. The present study tested a key prediction of this "two-factor" model, namely, that perinatal complications will be associated with physiologic signs of frontal dysfunction, even in persons who have no personal or family history of these psychiatric disorders. METHODS: Subjects were screened by structured interviews with the Kiddie Schedule for Affective Disorders and Schizophrenia and had no personal or family history of psychiatric disorder. Ratios of choline and N-acetyl aspartate to creatine in orbitofrontal cortex were measured using proton magnetic resonance spectroscopy. Perinatal complications were scored with the examiners blinded to magnetic resonance spectroscopy data, applying published scales to hospital records on subjects' gestations and births. RESULTS: Perinatal complications were significantly correlated with reduced concentrations of choline and N-acetyl aspartate. CONCLUSIONS: Our results complement earlier findings of significant relations between perinatal complications and signs of frontal lobe dysfunction, as well as elevated rates of these two types of variables in mood disorders and schizophrenia.

Cerebral phosphorus metabolite abnormalities in opiate-dependent polydrug abusers in methadone maintenance.

This study evaluated cerebral phosphorus metabolites in opiate-dependent polydrug abusers in methadone maintenance therapy (MMT) and determined whether metabolite profiles differed based on treatment duration. Phosphorus magnetic resonance spectroscopy (31P-MRS) data were acquired with the ISIS volume localization method from a 50-mm thick axial brain slice through the orbitofrontal and occipital cortices. Study subjects included 15 MMT subjects, seven having undergone treatment for an average of 39 +/- 23 weeks (mean +/- S.D.) and eight having undergone treatment for 137 +/- 53 weeks, as well as an age matched comparison group (n = 16). The methadone dose administered on the study day averaged 70.5 +/- 17.1 mg and was statistically equivalent in short- and long-term subgroups. MMT subjects (n = 15) differed from control subjects in percent phosphocreatine (%PCr) levels (-13%), and in both phosphomonoester (%PME, +13%) and phosphodiester (%PDE, +10%) levels, which likely reflect abnormalities in energy and phospholipid metabolism, respectively. There were no sex effects or group by sex interaction effects on these measures. In short-term MMT treatment subjects, abnormal %PCr (-18%), %PME (+20%) and %PDE (+17%) levels were found compared with control subjects. The only metabolite abnormality detected in long-term MMT subjects was decreased %PCr (-9%), in spite of continued illicit drug abuse. From these data, we conclude that polydrug abusers in MMT have 31P-MRS results consistent with abnormal brain metabolism and phospholipid balance. The nearly normal metabolite profile in long-term MMT subjects suggests that prolonged MMT may be associated with improved neurochemistry.

Effects of myo-inositol ingestion on human brain myo-inositol levels: a proton magnetic resonance spectroscopic imaging study.

BACKGROUND: Cerebrospinal fluid levels of myo-Inositol (m-Ino) are reported to be decreased in patients with affective disorder, and dietary supplements of m-Ino have been shown to reduce the symptoms of major depression. Myo-Inositol transport across the blood-brain barrier is mediated by a low capacity, saturable system. This study tests whether dietary m-Ino increases brain m-Ino or changes brain metabolism of m-Ino, possibly explaining the ability of this compound to alter mood. METHODS: Using proton magnetic resonance spectroscopic imaging, we measured m-Ino levels in occipital gray and parietal white matter of seventeen healthy subjects. Magnetic resonance spectroscopic imaging was performed twice at baseline as well as at day 4 and day 8 while subjects ingested 6 g of m-Ino twice a day. RESULTS: Following 4 days of m-Ino, m-Ino/Cr was 20% higher than baseline levels in occipital gray matter (p < 0.04) and 8% higher in parietal white matter (p = ns). By day 8, m-Ino/Cr ratios had returned to baseline values. CONCLUSIONS: Brain m-Ino levels initially increase during m-Ino administration and subsequently return to baseline levels. The time-limited increases observed for brain m-Ino may reflect homeostatic mechanisms, possibly associated with the role of m-Ino as a cerebral osmolyte, or with changes in brain phosphoinositide metabolism.

NAA-weighted imaging of the human brain using a conventional readout gradient.

An imaging sequence incorporating two complementary forms of water suppression was used in conjunction with conventional readout and phase-encoding gradients to acquire images of N-acetylaspartate (NAA) in human brain. The sequence consisted of CHESS water suppression pulses followed by dual echo sequence to select the imaging volume and frequency-selective refocusing pulses with asymmetric crushers to further reduce the water signal. Spectra and conventional spectroscopic images acquired with the sequence demonstrated robust suppression of water and other resonances down field from the 2.0-ppm NAA resonance with 98% of the brain signal resulting from the 3.0-ppm to 2.0-ppm region. The technique was found to provide NAA maps with a large (256 x 128) imaging matrix and to allow a flexible tradeoff between signal to noise ratio (SNR), matrix size, data acquisition window length, and imaging time. Since spectral information is not directly obtained, the length of the data acquisition window is not determined by the spectral resolution needed to resolve the components of the brain spectrum, allowing a significantly shorter readout period. The shorter acquisition window could potentially facilitate the acquisition of multi-echo or multi-slice brain NAA maps.

Brain proton magnetic resonance spectroscopy (1H-MRS) in Alzheimer's disease: changes after treatment with xanomeline, an M1 selective cholinergic agonist.

OBJECTIVE: Higher than normal cellular levels of the phospholipid catabolic intermediate glycerophosphocholine have been found in postmortem brain tissue of persons with Alzheimer's disease. Proton magnetic resonance spectroscopy (1H-MRS) can detect a choline resonance that is largely due to glycerophosphocholine. The authors tested the hypothesis that treatment with xanomeline, an M1 selective muscarinic cholinergic agonist, would be associated with a decrease in the 1H-MRS choline resonance. METHOD: Patients with mild to moderate Alzheimer's disease received placebo or xanomeline for 6 months. 1H-MRS spectra were collected at baseline and after treatment discontinuation for 12 patients, two taking placebo and 10 taking xanomeline at a dose of 25 mg t.i.d. (N = 4), 50 mg t.i.d. (N = 3), or 75 mg t.i.d. (N = 3). RESULTS: For the combined group of patients taking xanomeline, there was a significant decrease in the choline/creatine ratio from baseline to endpoint. CONCLUSIONS: Treatment of Alzheimer's disease with a cholinergic agonist is associated with a decrease in the MRS choline resonance. Xanomeline may reduce breakdown of cholinergic neuron membranes by reducing the cellular requirement for free choline for acetylcholine synthesis.

Lower levels of nucleoside triphosphate in the basal ganglia of depressed subjects: a phosphorous-31 magnetic resonance spectroscopy study.

OBJECTIVE: The purpose of this study was to evaluate whether the concentration of beta-nucleoside triphosphate is lower in the basal ganglia of depressed subjects. METHOD: In vivo 31P magnetic resonance spectra were acquired from a 45-cm3 region surrounding the basal ganglia of 35 unmedicated depressed subjects and 18 comparison subjects. RESULTS: beta-Nucleoside triphosphate, which arises primarily from beta-ATP, was 16% lower in the depressed subjects than in the comparison subjects. CONCLUSIONS: The low level of beta-nucleoside triphosphate is consistent with an abnormality of high-energy phosphate metabolism in the basal ganglia of subjects with major depression.

Metabolic and ionic changes in muscle during hemorrhagic shock.

We have employed concurrent noninvasive 31P and 23Na NMR spectroscopy in conjunction with the paramagnetic shift reagent dysprosium triethylenetetramine hexaacetic acid to observe the intracellular sodium and phosphorus signals in rat leg muscle. Male Wistar rats were bled to a mean arterial blood pressure of 40 mm Hg and were maintained at that pressure. Until decompensatory shock was reached, no increase in intracellular sodium (Nai) was found. Although the high energy storage metabolite phosphocreatine fell with time during shock, ATP did not decrease until decompensation. When the phosphorylation ratio, PR = [ATP]/[ADP][Pi], fell below log(PR) = 3.21 +/- .42, Nai increase commenced at a rate of 7.97 +/- 0.60 meq/l/hr. This corresponds to a two-fold increase in Na permeability compared to normal muscle. A calculation of the free energy available from hydrolysis of ATP at the above value of PR yields -11.7 kcal/mol which is essentially equal to the value of 11.8 kcal/mol which we calculate is needed to run the Na+-K+ antiport through one cycle under normal physiologic conditions.

Effects of thyroid hormones on skeletal muscle bioenergetics. In vivo phosphorus-31 magnetic resonance spectroscopy study of humans and rats.

The pathophysiology of the myopathy in dysthyroid states is poorly understood. We therefore tested the effects of thyroid hormones on muscle bioenergetics in humans and rats, using in vivo 31P NMR. Two hypothyroid patients had: low phosphocreatine to inorganic phosphate ratio (PCr/Pi) at rest, increased PCr depletion during exercise and delayed postexercise recovery of PCr/Pi. Eight thyroidectomized rats did not show abnormalities at rest, but muscle work induced by nerve stimulation resulted in a significantly (P less than 0.0001) lower PCr/Pi (35-45% of control) at each of the three stimulation frequencies tested (0.25, 0.5, and 1.0 Hz). Recovery rate was markedly slowed to one-third of normal values. Thyroxine therapy reversed these abnormalities in both human and rat muscle. Five patients and six rats with hyperthyroidism did not differ from normal controls during rest and exercise but had an unusually rapid recovery after exercise. The bioenergetic abnormalities in hypothyroid muscle suggest the existence of a hormone-dependent, reversible mitochondrial impairment in this disorder. The exercise intolerance and fatigue experienced in hypothyroid muscle may be due to such a bioenergetic impairment. The changes in energy metabolism in hyperthyroid muscle probably do not cause the muscular disease in this disorder.

Multinuclear MR imaging: a technique for combined anatomic and physiologic studies.

With the use of specially designed multiple-tuned probes for magnetic resonance (MR) imaging, data collection schemes can be developed for obtaining images of different nuclei simultaneously. Both phantom and in vivo MR images of two nuclei (either hydrogen-1, phosphorus-31, lithium-7, or fluorine-19) were obtained in the time span necessary to collect the image of the less sensitive nuclei. This technique offers a means by which physiologic and anatomic information can be gathered in a highly efficient fashion.