GABA concentrations and turnover in neonatal rat brain during asphyxia and recovery

The hypoxic respiratory response of the pre-Bötzinger complex

Since the discovery of the pre-Bötzinger Complex (preBötC) as a crucial region for generating the main respiratory rhythm, our understanding of its cellular and molecular aspects has rapidly increased within the last few decades. It is now apparent that preBötC is a highly flexible neuronal network that reconfigures state-dependently to produce the most appropriate respiratory output in response to various metabolic challenges, such as hypoxia. However, the responses of the preBötC to hypoxic conditions can be varied based on the intensity, pattern, and duration of the hypoxic challenge. This review discusses the preBötC response to hypoxic challenges at the cellular and network level. Particularly, the involvement of preBötC in the classical biphasic response of the respiratory network to acute hypoxia is illuminated. Furthermore, the article discusses the functional and structural changes of preBötC neurons following intermittent and sustained hypoxic challenges. Accumulating evidence shows that the preBötC neural circuits undergo substantial changes following hypoxia and contribute to several types of the respiratory system's hypoxic ventilatory responses.

Rate dependent influence of arterial desaturation on self-selected exercise intensity during cycling

The purpose of this study was to clarify if Ratings of Perceived Exertion (RPE) and self-selected exercise intensity are sensitive not only to alterations in the absolute level of arterial saturation (SPO2) but also the rate of change in SPO2. Twelve healthy participants (31.6 ± 3.9 y, 175.5 ± 7.7 cm, 73.3 ± 10.3 kg, 51 ± 7 mL·kg-1·min-1 [Formula: see text]) exercised four times on a cycle ergometer, freely adjusting power output (PO) to maintain RPE at 5 on Borg's 10-point scale with no external feedback to indicate their exercise intensity. The fraction of inspired oxygen (FIO2) was reduced during three of those trials such that SPO2 decreased during exercise from starting values (>98%) to 70%. These trials were differentiated by the time over which the desaturation occurred: 3.9 ± 1.4 min, -8.7 ± 4.2%•min-1 (FAST), 11.0 ± 3.7 min, -2.8 ± 1.3%•min-1 (MED), and 19.5 ± 5.8 min, -1.5 ± 0.8%•min-1 (SLOW) (P < 0.001). Compared to stable PO throughout the control condition (no SPO2 manipulation), PO significantly decreased across the experimental conditions (FAST = 2.8 ± 2.1 W•% SPO2-1; MED = 2.5 ± 1.8 W•% SPO2-1; SLOW = 1.8 ± 1.6 W•% SPO2-1; P < 0.001). The rates of decline in PO during FAST and MED were similar, with both greater than SLOW. Our results confirm that decreases in absolute SPO2 impair exercise performance and that a faster rate of oxygen desaturation magnifies that impairment.

Sex and steroid hormones in early brain injury

Brain injury during development can have severe, long-term consequences. Using an array of animal models, we have an understanding of the etiology of perinatal brain injury. However, we have only recently begun to address the consequences of endogenous factors such as genetic sex and developmental steroid hormone milieu. Our limited understanding has sometimes led researchers to make over-generalizing and potentially dangerous statements regarding treatment for brain injury. Therefore this review acts as a cautionary tale, speaking to our need to understand the effects of sex and steroid hormone environment on the response to brain trauma in the neonate.

Possible GABAergic Modulation in the Protective Effect of Zolpidem in Acute Hypoxic Stress-induced Behavior Alterations and Oxidative Damage

Hypoxia is an environmental stressor that is known to elicit alterations in both the autonomic nervous system and endocrine functions. The free radical or oxidative stress theory holds that oxidative reactions are mainly underlying neurodegenerative disorders. In fact among complex metabolic reactions occurring during hypoxia, many could be related to the formation of oxygen derived free radicals, causing a wide spectrum of cell damage. In present study, we investigated possible involvement of GABAergic mechanism in the protective effect of zolpidem against acute hypoxia-induced behavioral modification and biochemical alterations in mice. Mice were subjected to acute hypoxic stress for a period of 2 h. Acute hypoxic stress for 2 h caused significant impairment in locomotor activity, anxiety-like behavior, and antinocioceptive effect in mice. Biochemical analysis revealed a significant increased malondialdehyde, nitrite concentrations and depleted reduced glutathione and catalase levels. Pretreatment with zolpidem (5 and 10 mg/kg, i.p.) significantly improved locomotor activity, anti-anxiety effect, reduced tail flick latency and attenuated oxidative damage (reduced malondialdehyde, nitrite concentration, and restoration of reduced glutathione and catalase levels) as compared to stressed control (hypoxia) (P < 0.05). Besides, protective effect of zolpidem (5 mg/kg) was blocked significantly by picrotoxin (1.0 mg/kg) or flumazenil (2 mg/kg) and potentiated by muscimol (0.05 mg/kg) in hypoxic animals (P < 0.05). These effects were significant as compared to zolpidem (5 mg/kg) per se (P < 0.05). Present study suggest that the possible involvement of GABAergic modulation in the protective effect of zolpidem against hypoxic stress.

Increased allopregnanolone levels in the fetal sheep brain following umbilical cord occlusion

Allopregnanolone (AP) is a potent modulator of the GABAA receptor. Brain AP concentrations increase in response to stress, which is thought to provide neuroprotection by reducing excitation in the adult brain. Umbilical cord occlusion (UCO) causes hypoxia and asphyxia in the fetus, which are major risk factors associated with poor neurological outcome for the neonate, and may lead to adverse sequelae such as cerebral palsy. The aims of this study were as follows: (i) to determine the effect of 10 min UCO on AP concentrations in the extracellular fluid of the fetal brain using microdialysis, and (ii) to compare the content of the steroidogenic enzymes P450scc and 5alpha-reductase type II (5alphaRII) with brain and CSF neurosteroid concentrations. UCO caused fetal asphyxia, hypertension, bradycardia and respiratory acidosis, which returned to normal levels after 1-2 h. AP concentrations in dialysate samples from probes implanted in grey and white matter of the parietal cortex were significantly increased 1 h after UCO from control levels of 10.4 +/- 0.4 and 12.4 +/- 0.3 to 26.0 +/- 5.1 and 27.6 +/- 6.4 nmol l(-1), respectively (P < 0.05), before returning to pre-occlusion levels by 3-4 h after UCO. When fetal brains were collected 1 h after a 10 min UCO, the relative increases of AP and pregnenolone content in the parietal cortex were similar to the increase observed in the extracellular (dialysate) fluid. AP, but not pregnenolone, was increased in CSF at this time. P450scc and 5alphaRII enzyme expression was significantly increased in the cerebral cortex in the UCO fetuses compared to control fetuses. These results suggest that the fetal brain is capable of transiently increasing neurosteroid production in response to asphyxia. The action of the increased neurosteroid content at GABAA receptors may serve to diminish the increased excitation due to excitotoxic amino acid release, and provide short-term protection to brain cells during such stress.

The Role of Gamma-Aminobutyric Acid and Glutamate for Hypoxic Ventilatory Response in Anesthetized Rabbits

Acute hypoxia produces an increase in ventilation. When the hypoxia is sustained, the initial increase in ventilation is followed by a decrease in ventilation. Hypoxia causes changes in brain neurotransmitters depending on its severity and durations. The purpose of this study was to investigate the role of gamma-aminobutyric acid (GABA) and glutamate for hypoxic ventilatory response in rabbits. The experiments were performed in peripheral chemoreceptors intact and denervated rabbits anesthetized with Na-pentobarbitate. For intracerebroventricular (ICV) injections of reagents in each animal, cannula was placed in left lateral cerebral ventricle by stereotaxic method. After ICV injection of GABA (0.48 mg/kg), air breathing in both groups caused a depression of respiratory activity. On the other hand, after ICV injection of GABA, breathing of hypoxic gas mixture (8% O(2)-92% N(2)) in both groups produced the hypoxic hyperventilation. After ICV injection of GABA, blockade of GABA(A) receptors with bicuculline (0.2 mg/kg) did not prevent the hypoxic hyperventilation. In contrast, after ICV GABA injection, blockade of glutamate NMDA receptors with MK-801 (0.09 mg/kg) completely abolished the hypoxic hyperventilation observed while the animals were breathing hypoxic gas mixture. Our findings suggest that ICV injection of GABA causes respiratory depression in normoxic conditions, and that it increases ventilation in hypoxic conditions with or without peripheral chemoreceptor impulses by increasing glutamate.

Cell death in the rat hippocampus in a model of prenatal brain injury: time course and expression of death-related proteins

Survival rates have increased dramatically for very premature (gestational week 24-28) infants. However, many of these infants grow up to have profound cognitive, motor and behavioral impairments due to brain damage. We have developed a novel model of prenatal infant gray matter injury. During the neonatal period, GABA is an excitatory neurotransmitter. GABA(A) receptor activation results in chloride efflux and membrane depolarization sufficient to open L-type voltage sensitive calcium channels. Our model involves excessive GABA(A) receptor activation in the newborn rat, with damage due to the resultant excessive calcium influx, not GABA(A) receptor activation itself. A common feature among numerous insult pathologies in the neonatal brain is an elevation in the intracellular levels of calcium. The goals of the present study were: 1) to document the time course and amount of cell death (both apoptotic and necrotic), and 2) to investigate the effect of GABA(A) receptor activation on the time course and expression of three cell death-related proteins (caspase-9, bax and bcl-2) in our model of prenatal brain injury. The magnitude of cell death, using TdT-mediated dUTP nick end labeling and Cresyl Violet to quantify the incidence of apoptotic and necrotic cells, was region dependent (CA1>CA2/3>dentate gyrus) and persisted for at least 5 days following insult. There was a relative increase in the amount of bax to bcl-2 protein, and increased protein levels of caspase-9, indicative of cell death. These findings are consistent with mechanisms of cell death seen in other types of early brain insult, and highlight a conserved cascade of events leading to cell death in the developing brain.

Hypoxic ventilatory depression in a patient with mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes

We describe a case of a 21-year-old man with mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS) who presented with hypoxic ventilatory depression. He had chronic hypoventilation, which was not explained by weakness of respiratory muscles. His hypercapnic ventilatory response was not impaired. In contrast, hypoxic ventilatory depression was observed in the isocapnic progressive hypoxic response test. After exposure to hypoxic conditions, his respiratory frequency decreased and tidal volume was unchanged. The hypoxic ventilatory depression was partially blocked by pretreatment with aminophylline. In conclusion, we need to be careful with patients with MELAS who are hypoxaemic because a vicious circle of hypoxia and hypoventilation can occur.

Inhibitory mechanisms in hypoxic respiratory depression studied in an in vitro preparation

A medullary-spinal cord preparation without the pons isolated from the neonatal rat was used to investigate the role of inhibitory neurotransmitters in the respiratory depression induced by hypoxia (hypoxic respiratory depression; HRD). The burst frequency (C(4)-f) and peak amplitudes of the integrated activity of the C(4) roots (integral C(4)) and of the hypoglossal nerve (integral XII) were recorded. A marked decrease in C(4)-f (to 36+/-6% of control, P<0. 05) with no change in the peak amplitudes of integral C(4) or integral XII was observed 17-21 min after superfusion with hypoxic CSF bubbled with 5% CO(2) in N(2). Antagonists of GABA(A) (bicuculline; 10 microM), GABA(B) (phaclofen; 0.2-0.5 mM), glycine (strychnine; 10 mM), adenosine (aminophylline; 100 mM) or opioid (naloxone; 1 mM) receptors were added to the bathing solution to block inhibitory synaptic transmission. Among these antagonists, only strychnine and naloxone alleviated HRD reducing the decline in C(4)-f to 57+/-11 and 53+/-6%, respectively (P<0.05). Posthypoxic neural arrest (PHNA) following resumption of oxygenation was shortened by the application of aminophylline, strychnine or naloxone (by 91+/-17, 96+/-25 and 40+/-6 s, respectively, P<0.05). These findings indicate that the reduction in the frequency component of HRD depends on glycinergic and opioid-mediated neuronal inhibition in an in vitro medullary spinal cord preparation. It was also observed that the duration of PHNA was positively correlated with the severity of the fall in C(4)-f (r=0.60, P<0.01).

Recurrent hypoxic exposure and reflex responses during development in the piglet

The effects of recurrent hypoxia on cardiorespiratory reflexes were characterized in anesthetized piglets at 2-10 d (n=15), 2-3 weeks (n=11) and 8-10 weeks (n=8). Responses of phrenic and hypoglossal electroneurograms (ENG(phr) and ENG (hyp)) to hypoxia (8% 0(2), bal N(2), 5 min), hypercapnia (7% CO(2) bal O(2), 5 min) and intravenous capsaicin were tested before and after recurrent exposure to 11 episodes of hypoxia (8% O(2) bal N(2), 5 min). In piglets 2-10 d, ENG(phr) response to hypoxia declined in proportion to the number of hypoxic exposures; however, ENG (hyp) response to hypoxia was unchanged. In piglets at 2-10 d, intracisternal injection of bicuculline (GABA(A) receptor antagonist) reversed effects of recurrent hypoxia on ENG(phr) hypoxic response, eliminated apnea during hypoxia, as well as the delay in appearance of ENG(phr) after hypoxia. The ENG(phr) response to 7% CO(2) inhalation also decreased after recurrent hypoxia; however, the ENG(phr) response to C-fiber stimulation by capsaicin was unaltered. Piglets at 2-3 and 8-10 weeks were resistant to the depressive effects of recurrent hypoxia on respiratory reflex responses. We conclude that the response of the anesthetized newborn piglet to recurrent hypoxia is dominated by increasing inhibition of phrenic neuroelectrical output during successive hypoxic exposures. Central GABAergic inhibition may contribute significantly to the cumulative effects of repeated hypoxia in the newborn piglet experimental model.

Excitation of phrenic and sympathetic output during acute hypoxia: contribution of medullary oxygen detectors

Severe brain hypoxia results in respiratory excitation and an increase in sympathetic nerve activity. Respiratory excitation takes the form of gasping which is characterized by an abrupt onset, high amplitude, short duration burst of inspiratory activity. Recent evidence suggests that centrally-mediated hypoxic respiratory and sympathetic excitation may result from direct hypoxic stimulation of discrete hypoxia chemosensitive sites in the medulla. Thus, medullary regions involved in the generation and modulation of respiratory and sympathetic vasomotor output may contain neurons which function as central oxygen detectors, acting as medullary analogs to the peripheral (arterial) chemoreceptors. This review focuses on the medullary sites and mechanisms proposed to mediate hypoxic respiratory and sympathetic excitation in anesthetized, chemodeafferented animals, and provides the evidence suggesting a role for central oxygen detectors in the control of breathing and sympathetic vasomotor output.

Neuronal mechanisms mediating the integration of respiratory responses to hypoxia

The activation of peripheral chemoreceptors by hypoxia or electrical stimulation of the carotid sinus nerve elicited a hypoxic respiratory response consisting of both stimulatory and subsequent or simultaneous inhibitory components (hypoxic respiratory stimulation and depression). Both components have different time domains of responses (time-dependent response), providing an integrated respiratory response to hypoxia. This review has focused on the neuroanatomical and neurophysiological correlations responsible for these responses and their neuropharmacological mechanisms. Hypoxic respiratory depression is characterized by the initial activation of respiration followed by a progressive and gradual decline in ventilation during prolonged and/or severe hypoxic exposure (biphasic response). The responsible mechanisms for the depression are located within the central nervous system and may be dependent upon activity from peripheral chemoreceptor. Two underlying mechanisms contributing to the depression have been advocated. (1) Change in synaptic transmission: Within the neuronal network controlling the hypoxic respiratory response, hypoxia might induce the enhancement of inhibitory neurotransmission (modulation), disfacilitation of excitatory neruotransmission or both. (2) Change in the membrane property of respiratory neurons: Hypoxia might suppress the membrane excitability of respiratory neurons composing the hypoxic respiratory response via modulating ion channels, leading to hyperpolarization or depolarization blocking of the neurons. However, the quantitative aspects of Pao(2) (degree and duration of hypoxic exposure) to induce these changes and the susceptibility of both mechanisms to the Pao(2) level have not yet been clearly elucidated.

Cardiorespiratory response to bicuculline during resistive loaded breathing in anesthetized rabbits

We hypothesized that hypoventilation induced by resistive loaded breathing may result in part from an increase in gamma-aminobutyric acid (GABA) concentration in the central nervous system. Accordingly, ventilatory depression should be minimized by GABA receptor blockade. The effects of subseizure doses of the GABAA receptor antagonist bicuculline on the cardiorespiratory variables and cortical activities were evaluated in two groups of urethane anesthetized rabbits, breathing either through an inspiratory resistive load (IRL) or not. Bicuculline induced cardiorespiratory changes which consisted mainly of an augmented respiratory rate, through shortening of expiratory duration, and of bradycardia. Bicuculline effects did not significantly differ between both groups and were accompanied by high amplitude delta rhythmic cortical activities. These data show that GABAA receptors may exert a tonic depressive effect on the respiratory circuit and suggest that endogenous GABA release is not augmented by an acute increase in the work of breathing.

Adenosinergic modulation of respiratory neurones and hypoxic responses in the anaesthetized cat

1. The modulatory effects of intracellularly injected adenosine on membrane potential, input resistance and spontaneous or evoked synaptic activity were determined in respiratory neurones of the ventral respiratory group. 2. The membrane potential hyperpolarized and sometimes reached values which were beyond the equilibrium potential of Cl(-)-dependent IPSPs. At the same time, neuronal input resistance decreased. 3. Spontaneous and stimulus-evoked postsynaptic activities were decreased, as were mean respiratory drive potentials. 4. Systemic injection of the A1 adenosine receptor antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX; 0.01-0.05 mg kg-1) resulted in an increase in mean peak phrenic nerve activity when arterial chemoreceptors were denervated. In contrast, phrenic nerve activity decreased when arterial chemoreceptors were left intact. 5. The depressant effect of adenosine on synaptic activity was abolished after systemic DPCPX administration. DPCPX caused an increase in respiratory drive potentials, increased the amplitude of stimulus-evoked IPSPs, and hyperpolarized membrane potential. 6. Administration of DPCPX blocked the early hypoxic depression of stimulus-evoked IPSPs, doubled the delay of onset of hypoxic apnoea and shortened the time necessary for recovery of the respiratory rhythm. 7. The data indicate that adenosine acts on pre- and postsynaptic A1 receptors resulting in postsynaptic membrane hyperpolarization and depression of synaptic transmission. Blockade of A1 receptors increases respiratory activity, indicating that adenosine A1 receptors are tonically activated under control conditions. Further activation contributes to the hypoxic depression of synaptic transmission in the respiratory network.

Regional changes in amino acid levels of the neonate rat brain during anoxia and recovery

The aim of this study was to compare the changes in amino acids (alanine, aspartate, GABA, glutamate, glutamine, glycine, serine taurine) that are produced in different regions of the neonate brain (telencephalon, diencephalon cerebellum, brain stem) following a survivable period of anoxia and after the re-establishment of air respiration. Anoxia provoked different responses in the different regions. The changes during the anoxic period were as follows. In the brain stem there was a decrease in aspartate, in the telencephalon there was a significant increase in GABA and alanine and a decrease in aspartate, in the diencephalon, glutamate and GABA increased, and in the cerebellum, glycine and alanine levels were enhanced. The changes during recovery were even more dissimilar. Here the greatest shifts were seen in the brain stem with increases in glutamine, GABA, aspartate, glycine, serine, alanine, and taurine. In the telemcephalon glutamate fell and alanine increased, in the diencephalon GABA increased, and in the cerebellum, glutamate fell while glycine and alanine increased. In none of the major brain regions did the pattern of changes in neurotransmitters correspond to that seen in anoxic tolerant species.

Evidence for involvement of amino acid neurotransmitters in anesthesia and naloxone induced reversal of respiratory paralysis

General anesthetics render a person unconscious and may produce respiratory paralysis at therapeutic doses. No pharmacological agent is available to restore respiration and the mechanism/s of anesthesia or apnea is not clearly understood. In this report, we present evidence to show that naloxone reversed respiratory failure induced by thiopental, ketamine, halothane but not that induced by phenobarbital. Furthermore, 25 mg/kg, i.v. thiopental, 140 mg/kg, i.v. ketamine, and 3% halothane produced anesthesia without significantly altering respiratory rate, increased GABA and decreased glutamate (except ketamine and phenobarbital) levels in rat brain stem and cortex, but not in caudate and cerebellum. Aspartate, glycine and alanine levels were not affected in four brain regions studied. Pretreatment with TSC for 30 minutes did not change GABA or glutamate contents, but abolished the anesthetic as well as the respiratory depressant actions of the anesthetics. Increasing the doses of anesthetics produced respiratory failure with further rise in GABA and fall in glutamate in brain stem and cortex. Naloxone reversed respiratory paralysis and restored GABA close to control values in rat brain stem and cortex with no changes in caudate or cerebellum. Data presented here suggest that GABA may be necessary to produce loss of consciousness and naloxone reverses anesthetic induced respiratory failure.

Hypoxia, sleep and respiration in relation to opioids in developing swine

To test the role of mu and delta opioid systems in neonates during hypoxia, a total of sixteen, 4-11 (n = 7) and 26-33-day-old piglets (n = 9) were instrumented aseptically for assessment of sleep/wake states (S/W), electromyographic activities of the diaphragm and posterior cricoarytenoid muscles (EMGdi, EMG-pca, respectively), heart rate, and arterial pressures, pH and gas tensions. During daily sessions for 5 consecutive days, the piglets inhaled 10% O2/90% N2 for 10 min twice per session, first before any drug, then after either naltrexone (2 mg.kg-1 i.v.), a predominantly mu opioid antagonist, or naltrindole (4 mg.kg-1 i.v.), a specific delta opioid antagonist. During hypoxia, young, in contrast to older piglets, spent more time asleep, and increased sleep during the second half of the hypoxic exposure before, but not after each antagonist. They also exhibited, overall, higher breathing frequency, and lower slope, amplitude, area and initial area of EMGdi and EMGpca activity than older piglets. Naltrindole stimulated EMGpca activity in both age groups, and naltrexone increased the breathing frequency and slope of EMGdi in the older group. We conclude that hypoxia enhances the activation of central mu and delta opioid systems which influence S/W and respiration.

Response of the medullary respiratory network of the cat to hypoxia

1. The effect of systemic hypoxia was tested in anaesthetized, immobilized, thoracotomized and artificially ventilated cats with peripheral chemoreceptor afferents either intact or cut. Extracellular recordings from different types of medullary respiratory neurones and intracellular recordings from stage 2 expiratory neurones were made to determine the hypoxia-induced changes in neuronal discharge patterns and postsynaptic activity as an index for the disturbances of synaptic interaction within the network. 2. The general effect of systemic hypoxia was an initial augmentation of respiratory activity followed by a secondary depression. In chemoreceptor-denervated animals, secondary depression led to central apnoea. 3. The effects of systemic hypoxia were comparable with those of cerebral ischaemia following occlusion of carotid and vertebral arteries. 4. In chemoreceptor-denervated animals, all types of medullary respiratory neurones ceased spontaneous action potential discharge during hypoxia. 5. Reversal of inhibitory postsynaptic potentials (IPSPs) and/or blockade of IPSPs was seen after 2-3 min of hypoxia. 6. During hypoxia, the membrane potential of stage 2 expiratory neurones showed a slight depolarization to -45 to -55 mV and then remained stable. 7. The neurone input resistance increased initially and then decreased significantly during central apnoea. 8. Rhythmogenesis of respiration was greatly disturbed. This was due to blockade of IPSPs and, in some animals, to more complex disturbances of phase switching from inspiration to expiration. 9. Central apnoea occurred while respiratory neurones were still excitable as shown by stimulus-evoked orthodromic and antidromic action potentials. 10. The results indicate that the medullary respiratory network is directly affected by energy depletion. There is indication for a neurohumoral mechanism which blocks synaptic interaction between respiratory neurones in chemoreceptor-intact animals.

Central GABA mechanisms during postnatal development in the rat: neurochemical characteristics

Various biochemical characteristics of the developing GABA system was studied in rats from 1 to 60 days of age. Endogenous GABA concentrations were high in the limbic system, midbrain, brain stem and spinal cord at birth. Until 7 days of postnatal age, GABA concentrations generally decreased, thereafter an increase was seen and at 60 days of age the GABA concentrations exceeded those found in the neonate except for the spinal cord regions. After GABA-T inhibition with AOAA, GABA concentrations increased in all brain regions, however considerably more marked in the 28 days old rats compared to the 4 days old animals. Turnover rate of GABA was estimated by investigating the rate of disappearance of GABA after GAD inhibition with 3-MPA. Calculated turnover time of whole brain GABA was 34.1 min in the 4 days old rats and 19.9 min in the 28 days old animals. The results from this investigation clearly indicate a caudal to rostral maturational gradient in the development of endogenous GABA concentrations as well as synthesis capacity. Furthermore, turnover rate of total whole brain GABA but probably not of GABA in the neuronal pool is retarded in the 4 days old rats compared to the adolescent animals.