Selected maturational changes observed in the postnatal rat brain

Postnatal growth and morphological development of the brain: a species comparison

The objective of this report is to summarize the available literature regarding the postnatal growth and morphological development of the brain and compare the timelines for these events between humans and experimental species. While not the primary focus of this report, in acknowledgement of the evident role of maturation of neurotransmitter systems in development, a brief description of the comparative development of the NMDA receptor is included. To illustrate the challenges faced in estimating developmental toxicity potential in humans, the importance of postnatal experience in CNS development is also briefly reviewed. This review is part of the initial phase of a project undertaken by the Developmental and Reproductive Toxicology Technical Committee of the ILSI Health and Environmental Sciences Institute (HESI) to bring together information on a selected number of organ systems and compare their postnatal development across several species (Hurtt and Sandler: Birth Defects Res Part B 68:307-308, 2003).

Postnatal maturation of cytochrome oxidase and lactate dehydrogenase activity and age-dependent consequences of lithium-pilocarpine status epilepticus in the rat: a regional histoenzymology study

The lithium-pilocarpine (Li-Pilo) model of epilepsy reproduces some pathophysiological, temporal, and developmental features of human temporal lobe epilepsy. In this model, rates of cerebral glucose utilization measured by the [(14)C]2-deoxyglucose technique increased during the initial status epilepticus (SE) and decreased during the latent or chronic periods. To correlate these metabolic changes with the activities of the enzymes of the glycolytic and tricarboxylic acid cycle pathways, we measured by histoenzymology the regional activity of two key enzymes of glucose metabolism, lactate dehydrogenase (LDH) for the anaerobic pathway and cytochrome oxidase (CO) for the aerobic pathway coupled to oxidative phosphorylation, at various times after SE induced by Li-Pilo in 10- (P10), 21-d-old (P21) and adult rats for CO and in adult rats only for LDH. CO activity was slightly affected in P10 and P21 rats only at 4 and 24 h and normalized by 14 d after SE. In adult rats, CO activity decreased at 4 and 24 h in damaged areas, like entorhinal cortex, hippocampal CA3 area, amygdala, and thalamus. At 14 d after SE, CO activity was decreased only in entorhinal cortex and increased in brainstem regions involved in the remote control of seizures. In adult rats, LDH activity decreased at 24 h and 14 d after SE in sensorimotor and entorhinal cortex. These data show that the enzymatic equipment underlying the metabolism of glucose is not severely affected by Li-Pilo SE and confirm our previous observations concerning the relative metabolic hyperactivity of brain regions involved in the seizure circuit despite marked neuronal loss.

Fluid percussion brain injury in the developing and adult rat: a comparative study of mortality, morphology, intracranial pressure and mean arterial blood pressure

Changes in intracranial pressure (ICP) and mean arterial blood pressure (MABP) were measured for 30 min following an experimental fluid percussion traumatic brain injury in postnatal day 17 (P17), P28 and adult rats. Under enflurane anesthesia the left femoral artery was cannulated for MABP measurements and a 20 gauge needle was stereotaxically positioned into the right lateral ventricle for ICP measurements. Three different injury severities (mild: 1.35-1.45 atm, moderate: 2.65-2.75 atm, severe: 3.65-3.75 atm) were delivered over the left parietal cortex to each of the age groups. The biomechanical/physiological results indicated that fluid percussion generated reproducible traumatic brain injuries in the developing rat. Furthermore, with increasing injury severity the physiological responses (in terms of ICP and MABP) became more pronounced, resulting in a corresponding increase in mortality (mild, moderate, severe, respectively, P17: 27%, 36%, 100%; P28: 33%, 30%, 75%; adult: 0%, 20%, 55%). Compared to adult animals, developing rats exhibited pronounced hypotension in response to closed head injury, which most likely explains the greater percent mortality among the younger animals. The utilization of this model will allow for future studies addressing the consequences of traumatic brain injury when it is sustained early in development.

A quantitative method for measuring regional in vivo fatty-acid incorporation into and turnover within brain phospholipids: review and critical analysis

An experimental method and its associated mathematical model are described to quantitate in vivo incorporation rates into and turnovers of fatty acids (FAs) within stable brain metabolic compartments, particularly phospholipids. A radiolabeled FA is injected i.v. in a rat, and arterial plasma unacylated FA radioactivities and unlabeled concentrations are sampled until the animal is killed after 15 min, when the brain is analyzed biochemically or with quantitative autoradiography. Unbound unacylated label in blood easily crosses the blood-brain barrier; rapidly equilibrates in the unacylated FA, acyl-CoA and phosphatidate-diacylglycerol brain pools; then is incorporated into phospholipids and other stable metabolic compartments. Uptake and incorporation of labeled FAs are independent of cerebral blood flow at constant brain blood volume. Different labeled FAs enter specific sn positions of different brain phospholipids, suggesting that a combination of probes can be used to investigate metabolism of these phospholipids. Thus, [9,10-3-H]palmitate preferentially labels the sn1 position of phosphatidylcholine; [1-14C]arachidonate the sn2 positions of phosphatidylinositol and phosphatidylcholine; and [1-14C]docosahexaenoate the sn2 positions of phosphatidylethanolamine and phosphatidylcholine. The FA model provides an operational equation for rates of incorporation of FAs into brain phospholipids, taking into account intracerebral recycling and de novo synthesis of the FA, as well as entry into brain of FA from acylated blood sources. The equation is essentially independent of specific details of the proposed model, and can be used to calculate turnovers and half-lives of FAs within different phospholipid classes. For the model to be most applicable, experiments should satisfy conditions for pulse-labeling of the phospholipids, with brain sampling times short enough to minimize exchange of label between stable metabolic compartments. A 15-20 min sampling time satisfies these criteria. The FA method has been used to elucidate the dynamics of brain phospholipids metabolism in relation to brain development, brain tumor, chronically reduced auditory input, transient ischemic insult, axotomy with and without nerve regeneration, and cholinergic stimulation in animals with or without a chronic unilateral lesion of the nucleus basalis magnocellularis.

Lifelong ethanol consumption enhances the age-related changes in rat sympathetic neurons

The effects of aging and chronic ethanol administration on the histochemical and morphometric features of rat superior cervical ganglion were studied in a rat strain selected for voluntary alcohol consumption. Ethanol was administered to the experimental group ad libitum (10% v/v in drinking water) from 3 months to 28 months of age, the average ethanol intake being 6.4-5.4 g/kg per day. The sympathetic neurons of the ethanol consuming rats showed several signs of enhanced degeneration, e.g. decreased neuronal packing density, increased amount of age-pigment and decreased intensity of catecholamine histofluorescence and tyrosine hydroxylase immunoreactivity. The results may indicate a selective vulnerability of peripheral sympathetic neurons rather than a universal accelerated aging due to chronic ethanol exposure.

Interaction of aging and lifelong ethanol ingestion on ethanol-related behaviors and longevity

The interactions of aging and long-term voluntary ethanol consumption were studied in the alcohol-preferring AA (Alko Alcohol) rats. The mean daily ethanol intake was 6.45 +/- 0.31 g/kg/day (mean +/- SE) at the beginning of the exposure at 3 months of age. The control animals were given only food and water ad libitum. There was no difference in survival or weight gain between the control and ethanol groups. When tested for voluntary ethanol intake at the age of 24 months, the rats in the ethanol group consumed significantly more ethanol than the controls. The two groups did not differ in ethanol-induced motor impairment, sleep-time, or hypothermia, nor in the rate of ethanol elimination. The 24-month-old animals, however, showed higher sensitivity to ethanol than the 3-4-month-old rats in the sleep-time test. It is concluded that the feeding regimen used in this study did not produce any detectable interactions between ethanol and the aging processes in the AA rats.

Endoneurial blood flow in rat sciatic nerve during development

1. Endoneurial blood flow (EBF) in the sciatic nerve of rats aged 2-12 weeks was studied using microelectrode H2 polarography. 2. EBF is highest in 2-week-old rats and progressively declines during development. Mean arterial pressure (MAP) is low at 2 weeks of age, gradually increases through the next 4 weeks, and is relatively constant thereafter. The decrease in EBF, in spite of an increase in MAP, occurs because the endoneurial vascular resistance is increasing faster than the MAP. 3. The higher EBF in younger rats is not due to the smaller diameter of their nerves. Sural and tibial nerves of 12-week-old rats, with diameters comparable to that of the sciatic nerve of a 3-week-old rat, have EBFs similar to that of the sciatic nerve of a 12-week-old rat. 4. There was no compelling evidence of autoregulation of EBF in 3-week-old rats over a MAP range from -40 to +30 mmHg of the normal value. 5. The increase of nerve vascular resistance with maturation is probably due to a decrease in capillary density and, to a lesser extent, to an increase in plasma viscosity and haematocrit. 6. The higher EBF in immature rats is likely to be a developmentally adaptive mechanism which permits greater blood-nerve exchange of material to accommodate the greater metabolic needs of rapidly elongating and myelinating axons and proliferating Schwann cells.

Quantitative histochemical changes in enzymes involved in energy metabolism in the rat brain during postnatal development. I. Cytochrome oxidase and lactate dehydrogenase

The postnatal maturation of cytochrome oxidase and lactate dehydrogenase activity was assessed by histochemistry in rats at 8 postnatal stages, P0, P5, P10, P14, P17, P21, P35 and the adult stage. Enzyme activities were revealed on cryostat brain sections with diaminobenzidine for cytochrome oxidase and nitroblue tetrazolium for lactate dehydrogenase. Lactate dehydrogenase activity remained unchanged between P0 and P10, significantly increased in 8 areas of the 14 studied between P10 and P14 and in 6 structures from P14 to P17. These were mainly parietal, auditory and cerebellar cortices, hippocampus, thalamus, hypothalamus and medial geniculate body. There was no further change until P35 and lactate dehydrogenase activity increased then significantly to reach higher adult levels in hippocampus and medial geniculate body. Cytochrome oxidase activity was low from P0 to P10 and increased in 8 regions between P10 and P14. These were all cortices, caudate nucleus, hippocampus, inferior colliculus and genu. Enzyme activity further increased between P14 and P17 in auditory cortex, medial geniculate body and brainstem, did not vary from P17 to P21 but increased by 92 to 371% in all areas between P21 and P35. Cytochrome oxidase activity rose further from P35 to adult stage in hippocampus and medial geniculate body. From birth to adulthood, cytochrome oxidase activity increased 5 to 19 fold and lactate dehydrogenase activity 1.8 to 3.0. The present study shows that there is a quite good correlation between postnatal changes in regional cerebral glucose utilization and activity of enzymes involved in glycolytic and oxidative glucose metabolism in the rat.

The glial cells and glia-neuron relations in the buccal ganglia of Planorbis corneus (L.): cytological, qualitative and quantitative changes during growth and ageing

The glial tissue in Planorbis ganglia surrounds and ensheaths the neurons. The majority of the glial processes are interwoven around the neuronal perikarya and their major axon branches. Glial cell processes form a layer between the blood and nerve perikarya, but this does not significantly interfere with the movements of many small molecules in and out of the tissue. Such movements can occur paracellularly, through the extracellular spaces, since there are no occluding junctions between the cells.

Brain metabolism and blood flow during development and aging of the Fischer-344 rat

In cerebral cortical regions of the conscious Fischer-344 rat, regional cerebral blood flow (rCBF) as measured with 14C-indoantipyrine, and the cerebral metabolic rate for O2(CMRO2) do not decline after 3 months of age. On the other hand, the regional cerebral metabolic rate for glucose (rCMRglc) as measured with 14C-2-deoxy-D-glucose, falls significantly in some but not all cerebral cortical regions after 3 months. More generally, rCBF and rCMRglc do not follow identical courses during development and aging of the rat brain, although they remain stoichiometrically coupled among specific regions at any given age. Between 1 and 3 months, both increase in most brain regions, but after 3 months of age rCMRglc tends to fall throughout the brain, whereas rCBF tends to rise or remain unchanged in cerebral cortical regions, and falls after 12 months in posterior brain regions. The courses of rCBF, rCMRglc and CMRO2 during development and aging of the rat brain indicate that (a) stoichiometric coupling between flow and metabolism is maintained between 1 and 34 months of age, (b) the calculated coupling relation between rCBF and rCMRglc changes with age, possibly because rCBF increasingly sensitive to metabolism or because "constants" are employed to calculate rCMRglc or rCBF change with aging, and (c) cerebral cortical oxidative metabolism does not generally decline after 1 year of age. This constantly suggests that plasticity responses in the cerebral cortex of the rat compensate for senescence-associated morphological and neurochemical defects so as to preserve resting cortical functional activity.

Ontogenetic studies of seizure patterns and seizure activities induced by cortical focus

Ontogenetic studies of epileptogenic process were carried out in albino rats ranging in age from birth to 45 days. Experimental epilepsy was produced by two different procedures and the results were compared with each other. Tungstic acid gel was applied to the motor area of the left side of the cortex, and the following results were obtained. The latency of the seizure appearance was long during 10 days after birth, became progressively short thereafter and reached the minimum in about 20 days of age, and gradually returned to the adult level again by 45 days of age. No abvvious seizure was exhibited until five days of age. Seizure patterns developed from tonic or twitch-like jerky convulsion (10 days old) to rhythmic or clonic type of seizure (13 days old), and the seizure patterns similar to those in the adult rat were observed in about 20 days of age. Cortical seizure activity was initially observed in about 10-day-old rats; single high amplitude slow wave appeared and small spikes became superimposed on it in the course of maturation. Atypical spike and wave complexes were observed after 20 days of age. Electrical stimulation was applied to the left cortical motor area by constant current stimulator, and the following seizure patterns were observed: No obvious seizure could be elicited in newborn rat, whereas from three days of age, tonic seizure of the whole body, and from seven days old twitch-like convulsion of extremities were observed. In ages from 10 to 20 days, seizure induced by electrical stimulation was mainly tonic in pattern; extension of forelimbs and flexion of hindlimbs in most cases were observed before 13 days old, but both fore-and hindlimbs were extended therafter. Tonic-clonic seizure patterns were exhibited after 20 days of age. From these results, it was considered that tonic convulsions and high voltage slow cortical seizure activites were produced from the activites of the local cortical neuronal connections, and rhythmic and/or clonic seizure patterns and spike and wave seizure activities were elicited from the more complex, i.e. cortico-subcortical neuronal circuits. Possible contributing factors for the determination of seizure susceptibility in immautre rats were also discussed.

Acquisition and retention of habituation in the preweanling rat

The acquisition and retention of habituation to air-puff was studied in rats on Days 1-19 postpartum. Animals of all ages demonstrated habituation but the rate of habituation varied with age: slower on each successive day from Day 1 to Day 8, but thereafter more rapid on each successive day. This peak of elicited responding is discussed in relation to the peak of spontaneous activity at Day 16 and to the pattern of neural development, including changes in acetylcholinesterase, norepinephrine, and serotonin, measured during the preweaning period. All ages showed 30-min retention of habituation, with 60-min retention developing after the 1st week. No evidence of 24-hr retention appeared at any age.