Taizo Hitoshi

Pipecolic acid: a new type of α-amino acid possessing bicuculline-sensiti action in the mammalian brain

Using unit recording and electrophoretic techniques, pharmacological properties of pipecolic acid (PA) were studied in the brain neurons of rats. PA response was blocked by bicuculline more effectively than GABA response but not blocked by strychnine. Stereochemical findings obtained using the HGS-model demonstrated that PA structure is almost the same as a part of bicuculline structure. The present results suggest that PA might be a new type of substance possessing bicuculline-sensitive action. The site of the action of PA was also discussed.

Simultaneous analysis of pipecolic acid with proline in the brain by selected ion-monitoring technique

Abstract A method for the simultaneous analysis of pipecolic acid and proline in the brain is developed. The qualification and quantification of pipecolic acid and proline are accomplished with gas chromatography/mass spectrometry including a selected ion-monitoring technique by using deuterium-labeled proline as an internal standard, after the amino and carboxylic groups of these cyclic amino acids are derivatized with boron trifluoride methanol complex and heptafluorobutyric anhydride. The lower limit of quantification for the method is picomole levels and the concentration of pipecolic acid and proline in rat whole brain is determined to be 1.05 and 71.50 nmol/g of tissue, respectively.

Pipecolic acid enhancement of GABA response in single neurons of rat brain

Using unit recording and microelectrophoresis, influence of pipecolic acid (PA), a major metabolite of lysine in the brain, on GABA and glycine responses was studied in the cerebral cortical and hippocampal pyramidal neurons of rats. With small currents, PA had no effect on the single neuron activities but enhanced GABA response without affecting glycine response. The finding provides a new evidence that PA may have a connection with central GABA system.

Potentiation of phenobarbital-induced anticonvulsant activity by pipecolic acid

Pipecolic acid (PA) is an intermediate of lysine metabolism in the mammalian brain. Recent findings suggest a functional connection of PA as neuromodulator in GABAergic transmission. Since many drugs are postulated to produce their effects by interaction with the central GABA system, the influence of PA on the anticonvulsant activity of phenobarbital was examined. Pretreatment of mice with 50 mg . kg-1 of PA potentiated the suppressing effects of the barbiturate on electrically and chemically induced convulsions. However, there was no potentiation of the behavioral effects and hypothermia induced by phenobarbital. PA itself had no or only little effect on the convulsions, motor function and rectal temperature when given in i.p. doses up to 500 mg . kg-1. Intraventricular administration of 500 microgram of PA also did not suppress either type of convulsion, although it produced ptosis, hypotonia, sedation and hypothermia. The results are discussed in relation to GABA system.

Changes in brain piperidine levels under anesthesia: mass fragmentographic analysis.

Piperidine is a biogenic alicyclic amine possessing potent pharmacological activity. Interest has recently been focussed on its possible role as an endogenous hypnogenic substance. Using a mass fragmentographic technique with deuterium-labelled piperidine as an internal standard, the time relations of the change in brain levels of piperidine and the anesthetic activity of urethane were determined in mice. The brain piperidine level increased prior to the loss of the righting reflex and the elevated level declined prior to the reappearance of the reflex. The change in brain piperidine level correlated with neither that in spontaneous motility nor that in body temperature. The findings favor the idea that piperidine might at least partly regulate the level of consciousness.

Effects of anesthetics on piperidine levels in mouse brain

Piperidine is one of the biogenic amines possessing potent pharmacological activity. Recent interest has focused on its possible role as an endogenous hypnogenic substance. Using a mass fragmentographic technique with deuterium-labelled piperidine as an internal standard, piperidine concentrations in brains of waking and deeply anesthetized mice were analyzed to compare piperidine levels in the brain under distinctly different states of consciousness. A rapid and significant increase in piperidine concentrations was found in the brain but not in blood of mice anesthetized with any one of pentobarbital, urethane, ether and halothane. The results, showing that CNS depression is accompanied by accumulation of piperidine in the brain, are consistent with the idea that piperidine may have a close connection with the mechanisms controlling the level of consciousness.

Application of selected ion monitoring technique for quantitative determination of picomole levels of pyrrolidine in the brain

A specific and sensitive method for analysis of brain pyrrolidine, a volatile amine with potent synaptotropic actions on the peripheral and central nervous systems, was devised. The method involves the isolation of volatile amines by steam distillation and the qualification and quantification of pyrrolidine by gas chromatography/mass spectrometry (gcms) including a selected ion monitoring technique with deuterium-labeled pyrrolidine as an internal standard. The lower limit of quantification for the method was 2 pmol, and the mean concentration of pyrrolidine in the rat whole brain was determined to be 95 pmol/g of tissue.

Analysis of endogenous pyrrolidine levels by mass fragmentography

Pyrrolidine, one of biogenic volatile amines, possesses nicotine-like synaptotropic actions on the nervous systems. In the present study, pyrrolidine levels in the tissues were examined by using mass fragmentographic technique. High concentrations of pyrrolidine were found in the seminal vesicle and lung of rabbits. Only trace amounts of pyrrolidine existed in the brain of mice and rats, although higher concentrations were detected in the brain of rabbits. In the rat brain, however, high levels of pyrrolidine were found in the pineal gland, pituitary gland and corpus striatum.