Reinvestigating hyperpolarized (129)Xe longitudinal relaxation time in the rat brain with noise considerations.

The longitudinal relaxation time of hyperpolarized (HP) (129)Xe in the brain is a critical parameter for developing HP (129)Xe brain imaging and spectroscopy and optimizing the pulse sequences, especially in the case of cerebral blood flow measurements. Various studies have produced widely varying estimates of HP (129)Xe T(1) in the rat brain. To make improved measurements of HP (129)Xe T(1) in the rat brain and investigate how low signal-to-noise ratio (SNR) contributes to these discrepancies, we developed a multi-pulse protocol during the washout of (129)Xe from the brain. Afterwards, we applied an SNR threshold theory to both the multi-pulse protocol and an existing two-pulse protocol. The two protocols yielded mean +/- SD HP (129)Xe T(1) values in the rat brain of 15.3 +/- 1.2 and 16.2 +/- 0.9 s, suggesting that the low SNR might be a key reason for the wide range of T(1) values published in the literature, a problem that might be easily alleviated by taking SNR levels into account.

Single-channel and whole-cell studies of calcium currents in young and aged rat hippocampal slice neurons.

The hippocampal slice preparation has contributed greatly to analysis of the basic neurophysiology of brain neurons. In addition, because traumatic dissociative procedures are not used, the in vitro slice is particularly well suited for studies of electrophysiological properties of hippocampal neurons in young and aged rodent brain. Using the slice, we have previously observed an aging-dependent enhancement of voltage-activated Ca2+ influx using a combination of intracellular sharp electrode current-clamp and voltage-clamp techniques. The Ca(2+)-dependent afterhyperpolarization as well as the Ca2+ action potential were significantly larger in aged rat neurons. Using the sharp electrode clamp method, similar effects were found for high voltage-activated whole-cell Ca2+ currents. In order to study the mechanistic bases of these aging phenomena at the single-channel level, we have recently focused on recording cell-attached patches from neurons in the partially dissociated hippocampal slice ('zipper' slice). This technique, developed by Gray et al. in 1990, subjects slices to a mild enzymatic treatment resulting in the exposure of individual neurons for patch-clamp procedures. Using this technique, we are currently recording single Ca2+ channel activity in hippocampal slices from 4- to 29-month-old rats.

Mechanisms of neuronal death in brain aging and Alzheimer's disease: role of endocrine-mediated calcium dyshomeostasis.

This paper reviews evidence that brain aging and Alzheimer's disease (AD) are somehow closely related and that the hippocampus (CA1) is highly vulnerable to cell loss under both conditions. In addition, two current lines of evidence on the mechanisms of hippocampal cell loss with aging are considered, including studies of neuronal calcium dysregulation and studies of cumulative glucocorticoid (GC) neurotoxicity. Moreover, recent electrophysiological studies have shown that excess glucocorticoid activation of hippocampal neurons increases the influx of calcium through voltage-activated calcium channels. Second messenger systems may mediate the steroid modulation of calcium channels. Therefore, it is hypothesized that excess glucocorticoid activation and neuronal calcium dysregulation may be two phases of a single process that increases the susceptibility of neurons to neurodegeneration during aging and Alzheimer's disease.