Deformation versus Sphericity in the Ground States of the Lightest Gold Isotopes.

The changes in mean-squared charge radii of neutron-deficient gold nuclei have been determined using the in-source, resonance-ionization laser spectroscopy technique, at the ISOLDE facility (CERN). From these new data, nuclear deformations are inferred, revealing a competition between deformed and spherical configurations. The isotopes ^{180,181,182}Au are observed to possess well-deformed ground states and, when moving to lighter masses, a sudden transition to near-spherical shapes is seen in the extremely neutron-deficient nuclides, ^{176,177,179}Au. A case of shape coexistence and shape staggering is identified in ^{178}Au which has a ground and isomeric state with different deformations. These new data reveal a pattern in ground-state deformation unique to the gold isotopes, whereby, when moving from the heavy to light masses, a plateau of well-deformed isotopes exists around the neutron midshell, flanked by near-spherical shapes in the heavier and lighter isotopes-a trend hitherto unseen elsewhere in the nuclear chart. The experimental charge radii are compared to those from Hartree-Fock-Bogoliubov calculations using the D1M Gogny interaction and configuration mixing between states of different deformation. The calculations are constrained by the known spins, parities, and magnetic moments of the ground states in gold nuclei and show a good agreement with the experimental results.

Large Shape Staggering in Neutron-Deficient Bi Isotopes.

The changes in the mean-square charge radius (relative to ^{209}Bi), magnetic dipole, and electric quadrupole moments of ^{187,188,189,191}Bi were measured using the in-source resonance-ionization spectroscopy technique at ISOLDE (CERN). A large staggering in radii was found in ^{187,188,189}Bi^{g}, manifested by a sharp radius increase for the ground state of ^{188}Bi relative to the neighboring ^{187,189}Bi^{g}. A large isomer shift was also observed for ^{188}Bi^{m}. Both effects happen at the same neutron number, N=105, where the shape staggering and a similar isomer shift were observed in the mercury isotopes. Experimental results are reproduced by mean-field calculations where the ground or isomeric states were identified by the blocked quasiparticle configuration compatible with the observed spin, parity, and magnetic moment.

The effect of lactate infusion on myocardial metabolism and ventricular function following ischemia and cardioplegia.

Impaired myocardial fatty acid and glucose metabolism following ischemia and cardioplegia may limit the recovery of myocardial oxidative metabolism and ventricular function. Lactate, a simple three carbon compound, can be readily metabolized to pyruvate and is possibly the preferred substrate for aerobic metabolism. Therefore, increasing arterial lactate concentrations may improve myocardial metabolic recovery after ischemia and cardioplegia. Myocardial lactate metabolism and ventricular function were assessed in a canine model of 45 mins of global normothermic ischemia followed by 60 mins of cold potassium cardioplegic arrest. Thirteen dogs received a perioperative infusion of sodium lactate to elevate arterial concentrations (from 6 to 12 mmol/L) and 12 dogs received an equivalent amount of saline. The high arterial lactate concentrations were associated with an increased myocardial lactate consumption and oxidation (as assessed by 14C-labelled lactate) during reperfusion. Myocardial ATP concentrations fell during reperfusion despite improved myocardial oxidation. The recovery of ventricular function (as assessed by a compliant intraventricular balloon) was incomplete and only marginally better with the high arterial lactate concentrations. An infusion of lactate improved myocardial oxidative metabolism following ischemia and cardioplegia. However, the recovery of ventricular function was incomplete perhaps because of inadequate preservation of myocardial ATP.

Improving myocardial metabolic and functional recovery after cardioplegic arrest.

The myocardial oxidation of fatty acids and glucose, the predominant substrates for aerobic metabolism, is impaired after cardioplegic arrest for coronary revascularization. Because lactate can be readily metabolized to pyruvate, it may be the preferred substrate for aerobic metabolism after cardioplegic arrest when arterial concentrations are elevated. Nineteen patients undergoing elective coronary revascularization with blood cardioplegia were randomized to receive LOW (nine patients, no exogenous lactate) or HIGH (10 patients, a perioperative infusion of Ringer's lactate) arterial lactate concentrations. Coronary sinus catheterization and lactate labeled with carbon 14 permitted calculation of myocardial oxygen consumption and lactate oxidation which were significantly increased during reperfusion in the group with HIGH arterial lactate concentrations. Atrial pacing at 110 beats/min on cardiopulmonary bypass resulted in myocardial lactate production (suggesting ischemic anaerobic metabolism) in the LOW lactate group, but atrial pacing increased lactate consumption and oxidation in the HIGH lactate group (suggesting increased aerobic metabolism). Systolic function (the relation between end-systolic pressure and volume) as assessed by nuclear ventriculography 3 hours postoperatively was significantly better (p less than 0.05 by analysis of covariance) in the HIGH lactate group. Postoperative myocardial creatine kinase release was significantly lower in the HIGH lactate group, which suggested less perioperative ischemic injury. Lactate was the preferred substrate for myocardial oxidative metabolism after cardioplegic arrest, and the higher arterial lactate concentrations improved myocardial metabolic and functional recovery and reduced perioperative ischemic injury.

Exogenous substrate preference of the post-ischaemic myocardium.

Myocardial exogenous substrate preference was studied under conditions of increased plasma lactate concentration before and after a severe (halving of tissue ATP concentration, sixfold increase in tissue lactate concentration) but reversible (less than 1% necrosis on reperfusion) global ischaemic stress produced by continuous hypothermic electromechanical arrest of the heart of four hours' duration by aortic cross clamping and multidose potassium cardioplegia. Fatty acid oxidation was studied using 1-14C-palmitate under steady state conditions and under similar isovolumic fixed pressure conditions with the heart at a constant rate using a left ventricular intracavitary balloon. Exogenous free fatty acid oxidation during the pre-ischaemic period with an increased lactate concentration (3.9-5.8 mmol . litre-1) was 0.62(0.21) mumol . min-1 X 100 g-1 (mean (SEM)). This represented a mean of 32% of the total carbon dioxide produced in contrast to a post-ischaemia free fatty oxidation rate of 2.67(0.87) mumol . min-1 X 100 g-1, in the presence of even further increased plasma lactate concentrations (8.47-11.17 mmol . litre-1), representing a mean of 82% of the total carbon dioxide output. These data suggest that the substrate preference of the myocardium, under conditions of increased plasma lactate concentration, shifts to greater oxidation of exogenous free fatty acids after ischaemic stress.

Plasma progesterone levels throughout the ovarian cycle of the common marmoset (Callithrix jacchus).

Radioimmunoassay of progesterone in marmoset plasma has been used to determine ovarian cycle length. Total cycle length was 30.1 +/- 3.8 days (mean +/- SD, n = 30, range 24-41 days, median 29.5 days). The pre-ovulatory (follicular) phase, during which progesterone levels were below 10 ng/ml, lasted for 8.8 +/- 3.7 days (mean +/- SD, n = 30, range 3-20 days, median 8.5 days). The post-ovulatory (luteal) phase, during which progesterone levels were greater than 10 ng/ml, lasted for 21.5 +/- 2.2 days (mean +/- SD, n = 30, range 14-29 days, median 21.5 days). Total cycle length was almost twice that recorded in an earlier study. The reasons for this difference are discussed.