Hypoxia-induced force increase (HIFI) is a novel mechanism underlying the strengthening of labor contractions, produced by hypoxic stresses

For successful birth, contractions need to become progressively stronger. The underlying mechanisms are unknown, however. We have found that a novel mechanism, hypoxia-induced force increase (HIFI), is switched on selectively, at term, and is essential to strengthening contractions. HIFI is initiated as contractions cyclically reduce blood flow and produce repeated hypoxic stresses, with associated metabolic and transcriptomic changes. The increases in contractility are a long-lasting, oxytocin-independent, intrinsic mechanism present only in the full-term pregnant uterus. HIFI is inhibited by adenosine receptor antagonism and blockade of cyclooxygenase-2 signaling, and partially reproduced by brief episodes of acidic (but not alkalotic) pH. HIFI explains how labor can progress despite paradoxical metabolic challenge, and provides a new mechanistic target for the 1 in 10 women suffering dysfunctional labor because of poor contractions.

An educational device for a hands-on activity to visualize the effect of atherosclerosis on blood flow

An educational device was created to develop a hands-on activity to illustrate how atherosclerosis can dramatically reduce blood flow in human vessels. The device was conceived, designed, and built at the University of Coimbra, in response to a request from the Exploratório Infante D. Henrique Science Centre Museum, where it is presently installed. The device was designed to allow lay audience to operate it, including school-age youngsters. The two blood flow reduction mechanisms that can be visualized are 1) thickening of the artery wall and 2) hardening of the artery wall. The main objective is to promote the understanding of atherosclerotic cardiovascular physiology by simple and direct experiments. This original educational interactive device was constructed using, in the conceptual and design stages of the project, a Newtonian theoretical flow model based on Poiseuille's equation. This device is driven by human force and provides a visualization of the effect of atherosclerosis on flow. The main aspects relating to its design and construction are described here to explain and disseminate this approach. Throughout more than 4 yr of real operation, this educational device proved to be a simple and attractive way of understanding atherosclerosis, especially among young people.

Comparative analysis of NMR and NIRS measurements of intracellular P O 2 in human skeletal muscle

1H NMR has detected both the deoxygenated proximal histidyl NδH signals of myoglobin (deoxyMb) and deoxygenated Hb (deoxyHb) from human gastrocnemius muscle. Exercising the muscle or pressure cuffing the leg to reduce blood flow elicits the appearance of the deoxyMb signal, which increases in intensity as cellular[Formula: see text] decreases. The deoxyMb signal is detected with a 45-s time resolution and reaches a steady-state level within 5 min of pressure cuffing. Its desaturation kinetics match those observed in the near-infrared spectroscopy (NIRS) experiments, implying that the NIRS signals are actually monitoring Mb desaturation. That interpretation is consistent with the signal intensity and desaturation of the deoxyHb proximal histidyl NδH signal from the β-subunit at 73 parts per million. The experimental results establish the feasibility and methodology to observe the deoxyMb and Hb signals in skeletal muscle, help clarify the origin of the NIRS signal, and set a stage for continuing study of O2regulation in skeletal muscle.

Effect of endogenous vasopressin on blood flow to choroid plexus during hypoxia and intracranial hypertension

Exogenous vasopressin decreases blood flow to the choroid plexus and production of cerebrospinal fluid. Some studies indicate that hypoxia and increases in intracranial pressure (ICP) produce increases in circulating vasopressin. We examined the hypothesis that endogenous release of vasopressin decreases blood flow to the choroid plexus during hypoxia and increased ICP. Blood flow to the choroid plexus was measured in anesthetized rabbits using microspheres. Hypoxia increased cerebral blood flow more than twofold but had little effect on blood flow to the choroid plexus. In contrast, hypoxia produced a marked increase in blood flow to the choroid plexus in the presence of a vasopressin V1-antagonist, [d(CH2)5Tyr(Me)]AVP. During intracranial hypertension, blood flow to the choroid plexus decreased from 409 +/- 42 to 295 +/- 25 ml.min-1 x 100 g-1 (means +/- SE; P < 0.05 vs. control) when ICP was increased from 1 to 40 mmHg. The vasopressin antagonist inhibited the decrease in blood flow to the choroid plexus in response to increased ICP. Thus release of vasopressin during hypoxia and increased ICP have a constrictor effect on blood vessels of the choroid plexus. Plasma levels of vasopressin increased minimally during hypoxia and increased ICP, which suggests that sources of vasopressin other than plasma affect blood vessels of the choroid plexus. We propose that endogenous vasopressin may play a protective role during hypoxia and intracranial hypertension by a negative feedback mechanism to reduce blood flow to the choroid plexus.

The Effects of the GABA Agonist Muscimol upon Blood Flow in Different Vascular Territories of the Rat Cortex

Local cerebral blood flow was measured in five regions of rat cortex immediately following intravenous administration of the γ-aminobutyric acid (GABA) agonist muscimol. In contrast to recent observations, no increases in blood flow were found at either of the two time points analysed, and the data revealed that decreases in blood flow previously reported 30 min after muscimol treatment were in evidence as early as 30 s. These results are totally consistent with the conclusion that the overall effects of GABA agonists in the intact animal are to reduce blood flow in line with reduced metabolic demand in the neuropil. However, the heterogeneity of the reductions in cortical blood flow found here possibly suggests a biological role for vascular GABA systems in providing a mitigating influence on fluctuating tissue perfusion.

Tissue oxygen extraction during hypovolemia: role of hemoglobin P50

When the delivery of O2 to tissues (QO2 = blood flow X O2 content) falls below a critical threshold, tissue O2 uptake (VO2) becomes limited by QO2. The mechanism responsible for this extraction limitation is not understood but may involve molecular diffusion limitation as mean capillary PO2 drops below a critical minimum level in some capillaries. We tested this hypothesis by measuring the critical QO2 necessary to maintain VO2 independent of QO2 in anesthetized, paralyzed normal dogs (n = 7) and in a second group in which PO2 at 50% saturation of hemoglobin (P50) was reduced by exchange transfusion with low-P50 erythrocytes (n = 7). QO2 was reduced in stages by removing blood volume to reduce blood flow while VO2 was measured by spirometry at each step. To the extent that O2 extraction was limited by a critical capillary PO2, we reasoned that the onset of diffusion limitation should occur at a higher QO2 with low P50, since a lower end-capillary PO2 is required to achieve the same O2 extraction. The critical QO2 (7.8 +/- 1.2 ml X min-1 X kg-1) and extraction ratio (0.63 +/- 0.06) in dogs with reduced P50 were not different from controls. At the critical delivery, mixed venous PO2 was lower in low P50 (16.1 +/- 2.9 Torr) than controls (29.9 +/- 2.3 Torr). We concluded that diffusion limitation does not initiate the early fall in VO2 below the critical QO2 and offer an alternative model to explain the onset of supply dependency.(ABSTRACT TRUNCATED AT 250 WORDS)