[The mathematical modelling of water-osmotic equilibrium during the performance of hemodialysis]

The model has been designed by the authors to prevent complications as a result of redistribution of liquid between cellular and extracellular spaces arising in the patient's body in the course of hemodialysis. Because movements of the liquid between the spaces depends on the osmolality gradient, two principal systems were identified: body water system and system of osmotically active substances. The latter incorporates sodium and potassium salts and urea. The model is based on 6 differential equations. The least squares method derived individual parameters of the model. Using the model, the physician can regulate to optimal the regimen of hemodialysis: blood flow rate, speed of ultrafiltration, concentration of sodium and potassium in dialysate.

Delayed hyperglycemia and intracellular acidosis during focal cerebral ischemia in cats

The effects of hyperglycemia on permanent focal brain ischemia is controversial; its effects on the size of the infarct are variable according to experimental conditions. In this study, nuclear magnetic resonance (NMR) spectroscopy was used to assess brain pH and high-energy phosphate metabolites after focal middle cerebral artery (MCA) ischemia in hyperglycemic and normoglycemic cats. Sixteen adult cats underwent (MCA) occlusion under general anesthesia and nuclear magnetic resonance 31P spectroscopy to assess intracellular brain pH and energy metabolites throughout permanent ischemia. Animals were treated two hours after the onset of ischemia with either saline or glucose perfusions. Significant hyperglycemia (488 vs 105 mg/100 ml) was achieved in the experimental group. The response to hyperglycemia was dependent on the initial characteristics of the infants. A distinct pattern of phosphocreatine/inorganic phosphate recovery within 20 minutes of ischemia predicted a small infarct size. The addition of hyperglycemia did not affect acidosis, infarct size, or metabolite ratios in these animals. The lack of phosphocreatine/inorganic phosphate recovery within 20 minutes of ischemia was predictive of an eventual large infarct. In these animals, the delayed addition of hyperglycemia significantly lowered intracellular pH during the ischemic period (5.45 vs. 6.25, p = 0.25). These data support the theory that the response to hyperglycemia is very dependent on the initial metabolic state of the injured brain. This state can be predicted by early 31P spectroscopy data, which may, in turn, prove to be a useful marker for recoverable ischemic deficit in the cerebral region of interest.

Calmodulin regulates the intracellular trafficking in epithelial cells

In this study we have demonstrated the role of calmodulin in membrane trafficking. By means of specific calmodulin-antagonist (W13, N-(4-aminobutyl)-5-chloro-2-naphthalenesulfonamide) the transcytosis, recycling and receptor-mediated endocytosis of IgA were investigated. In W13 treated MDCK cells, exHpressing the polymeric immunoglobulin receptor (pIgR) and plated on polycarbonate filters (transwells), it has been shown that transcytosis of IgA was inhibited, the recycling was concomitantly increased and there were no modification on its internalization. Altogether, point to a role of calmodulin in regulating the function of endocytic compartment in epithelial cells.

The induction of counter-interactions in tumor cells as a basis for the development of a therapy

A tumor cell in a stringent situation is under the influence of two, opposite vectorial 'forces'. Resulting from the stringent situation, one of these 'forces' acts as an inhibitor of the synthesis process, whilst the perpetuation of the genetic induction of synthesis processes in the nucleus causes the second 'force' to act in the opposite manner. The influence of these 'forces' results in the formation of a counter interaction which leads to a 'breaking away' or decoupling of interdependent functions which are tuned to each other. This could be characterized as an apospasis and leads to irreversible cell-damage. If there is no decoupling, then there is a differentiation, or loss of the self-renewing capacity. Due to the fact that the counter interaction is inducible in tumor cells with proliferation activities as well as in tumor cells without proliferation activities, cells in both the growth and non-growth fraction can be attacked.

Intracellular calcium, myosin light chain phosphorylation, and contractile force in experimental cerebral vasospasm

It remains unknown what proportion of delayed arterial narrowing after subarachnoid hemorrhage depends on ongoing metabolic activity within arterial smooth muscle cells versus changes in the passive structural properties of the arterial wall. To determine this, vasospasm was induced by the double subarachnoid hemorrhage model. Anterior spinal artery segments were harvested from control dogs and from dogs with vasospasm. The segments were suspended in a force transducer and stretched to an optimal length for contraction. The difference in tension between 37 and 0 degrees C was defined as the intrinsic tone, and the residual tension at 0 degrees C was defined as the passive tension. The segments taken from dogs with vasospasm had increased intrinsic tone and passive tension (the differences were 3.8 kN/m2 [P < 0.05] and 14.8 kN/m2 [P < 0.025], respectively). Hence, the passive component accounted for 79.6% of the increased tension in vasospastic arterial segments. The intracellular calcium concentration was measured in these segments, using the luminescent calcium indicator, aequorin. The vasospastic segments had increased basal intracellular calcium concentration (398 versus 258 nmol/L, P < 0.025). In parallel experiments, control and vasospastic vessels were immediately excised when the animals were killed, and the vessels were quick-frozen. Subsequently, using two-dimensional gel electrophoresis to measure percent myosin light chain phosphorylation, vasospastic vessels were found to have increased myosin light chain phosphorylation (37 versus 2%, P < 0.05). The increased intracellular calcium concentration and increased percent myosin light chain phosphorylation in vasospastic segments implicate a role for the Ca(2+)-dependent pathway of smooth muscle cell contraction in vasospasm.

Staphylococcus aureus small colony variants are induced by the endothelial cell intracellular milieu

Recent studies have reported that Staphylococcus aureus small colony variants (SCVs) can cause highly persistent infections in humans and in cultured endothelial cells. To understand the process by which SCVs of S. aureus appear in subjects who have not received antibiotic treatment, bovine endothelial cells were coincubated with a wild S. aureus strain for 72 h in the presence of lysostaphin. Intracellular bacteria were harvested and screened for stable SCVs. Intracellular bacteria developed the SCV phenotype at a greater rate than control bacteria not exposed to endothelial cells: The intracellular induction rate was approximately 10(-3) versus a spontaneous rate of <10(-7). This observation suggest that SCVs are induced by the intracellular milieu and suggest a possible mechanism for the intriguing pathophysiology of tissue persistence of staphylococci.

Swelling, intracellular acidosis, and damage of glial cells

Cerebral ischemia and severe head injury among others are associated with a limited availability of oxygen, leading to cell catabolism as well as anaerobic glycolysis. Resulting metabolites, such as arachidonic- and lactic acid, can be expected to leak into perifocal brain areas, contributing there to cytotoxic swelling and damage of neurons and glia. Since elucidation of mechanisms underlying cell swelling and damage in the brain is difficult in vivo, respective investigations were carried out in vitro using suspended glial cells. Thereby, effects of arachidonic acid (AA) and of lactacidosis on glial cell volume, intracellular pH (pHi), and cell damage were analyzed utilizing flow cytometry. AA led to an immediate, dose dependent swelling and intracellular acidosis of glial cells. A concentration of 0.1 mM increased cell volume to 110% of control and decreased pHi to 7.05. Whereas glial swelling was permanent, pHi recovered to baseline after 90 min. Cell viability of 90% remained unchanged after addition of AA up to 0.1 mM, while at 0.5 mM it was significantly decreasing. Glial swelling from AA was nearly completely inhibited by the aminosteroid U-74389F or by using a Na(+)-free suspension medium for the experiment. Acidification of the medium to pH 6.8 or 6.2 led to a cell volume of 110% or 120% of control without affecting cell viability. The cells were not capable to defend their normal pHi during lactacidosis of the suspension medium but became acidotic as well. Addition of amiloride or utilization of Na(+)-free medium inhibited cell swelling from lactacidosis, while intracellular acidosis was even more pronounced. The results indicate that AA as well as acidosis are potent mediators of glial swelling and damage at levels found under pathophysiological conditions in the brain in vivo. Whereas intracellular acidification caused by AA was reversible, glial cells were unable to regulate their pHi during maintenance of extracellular acidosis. Concerning the mechanisms of glial swelling by AA, the production of oxygen- and lipid radicals might play a major role in the swelling process. The results indicate a role of the Na+/H(+)-antiporter in acidosis-induced glial swelling, whereas the exchanger has a limited significance for maintenance of pHi. As seen, the final pathway of glial swelling from both, AA and lactacidosis, requires a net influx of Na(+)-ions, probably together with Cl-ions, and osmotically obliged water.

Inhibition of in vitro meningioma proliferation after growth factor stimulation by calcium channel antagonists: Part II--Additional growth factors, growth factor receptor immunohistochemistry, and intracellular calcium measurements

We have previously reported that calcium channel antagonists can block both the growth of meningiomas in culture and the potent growth stimulation of meningioma cells by epidermal growth factor (EGF) and platelet-derived growth factor (PDGF). This study further defines the nature of this growth inhibition. Primary meningioma cultures were established, and cells were characterized. Fibroblast growth factor or insulin-like growth factor-I growth stimulation in the presence of calcium channel antagonists was examined. In addition, the effects of ethylene glycol-bis-(aminoethylether) N,N,N',N"-tetraacetic acid and Bay K 8644, a calcium channel agonist, on the growth factors were analyzed. Growth factor receptor immunohistochemistry was performed on the original tumors and the in vitro meningioma cells. Twelve of 17 (71%) meningiomas in this study were positive for the EGF receptor, and 14 of 17 (82%) were positive for the PDGF receptor. Five of six (83%) of the culture cells were positive for the EGF receptor, and four of five (80%) were positive for the PDGF receptor. Intracellular calcium changes were quantified using the intracellular calcium-chelating, fluorescent dye, Fura-2. The growth stimulation of fibroblast growth factor and insulin-like growth factor-I on meningioma cells in culture was decreased in a dose-dependent manner by calcium channel antagonists. The growth stimulation of fibroblast growth factor and insulin-like growth factor-I was not affected by a reduction of extracellular calcium, whereas the growth stimulation of EGF and PDGF was. Interestingly, intracellular calcium was not increased after exposure to growth factors but was increased after serum stimulation. This increase could be blocked by preincubation with verapamil. Calcium channel antagonists can inhibit proliferation of meningioma cells in culture after stimulation with a number of growth factors. These drugs might disrupt intracellular calcium homeostasis or interfere with key elements of the growth factor signal transduction pathways. These mechanisms as well as the potential clinical relevance of these findings are discussed.

Spin-lattice relaxation times of water in polarized and depolarized rabbit vagus nerves

Spin-lattice relaxation times (T1) of intracellular water of the nonmyelinated fibers of rabbit cervical vagus nerve were measured using a paramagnetic shift reagent, s-FDF. Spin-lattice relaxation decay curves were composed of the fast (T1,F) and slow (T1,S) relaxation components. The mean values of T1,F and T1,S in the polarized nerve fibers at 25 degrees C were 0.12 +/- 0.04 and 0.61 +/- 0.13 sec., respectively, and their fractions were 0.71 +/- 0.07 and 0.29 +/- 0.07, respectively (n = 21). On the other hand, those values in the depolarized nerve fibers were 0.16 +/- 0.01 sec., 0.77 +/- 0.17 sec., 0.77 +/- 0.10 and 0.23 +/- 0.10, respectively (n = 15). T1,F and T1,S for the depolarized nerve fibers were significantly elongated (P < 0.01).

Redistribution of body fluids during postural manipulations

Inter-compartmental body-fluid distribution is contingent upon posture, exercise state and environmental temperature. This investigation aimed at quantifying the distribution of intra- and extravascular fluid volumes during postural manipulations. Fluid shifts were measured in eight males utilizing a simultaneous, radionuclide dilution technique, in which radioiodinated serum fibrinogen, radiochromated erythrocytes, radiobromine and tritiated water were used to measure plasma, red cell, extracellular and total body water volumes. Subjects were exposed to three postural changes [seated (control), supine and standing] for 30 min at an air temperature of 22.0 degrees C, with each posture separated by 30 min seated rest. Total body water content remained stable throughout postural changes (P = 0.842). Relative to seated volumes, BV increased by 89 mL when supine, and decreased by 406 mL while standing (P = 0.003), with such shifts being primarily a result of plasma movement (P = 0.011). Red cell volume changes were not significant. Vascular fluid lost during standing was filtered into the interstitial compartment (P = 0.014), with the extracellular and intracellular volumes remaining unaffected. (P = 0.271 and P = 0.800, respectively). These observations confirmed the influence of posture on inter-compartmental body-fluid distribution. The intravascular fluid loss when standing was caused by the filtration of plasma into the interstitium, while, during supine rest, intravascular volume increased, reflecting fluid flux from the interstitium to the circulation.

Activation delay in healed myocardial infarction: a comparison between model and experiment

Conduction delay in healed myocardial infarction, facilitating reentry, is frequently based on an increased path length the activation has to travel in a matrix of merging and diverging bundles that survive in the infarcted area. Additional delay occurs at sites where bundles bifurcate. The purpose of this study was to investigate conduction delay at sites where bundles bifurcate. A computer model was developed to simulate spread of activation in a two-dimensional sheet of excitable elements. A structure consisting of two isolated bundles merging into a single one was modeled. Extracellular electrograms calculated in the model were comparable to electrograms obtained in a superfused infarcted papillary muscle model. A zone of crowded isochrones or local conduction delay was found at the site where an isolated bundle bifurcated. The position of the isochrones in this area depended on the way activation times were determined. Lines of activation delay were mainly perpendicular to the fiber direction. In conclusion, the results have enabled us to better understand extracellular electrograms at pivoting points and show that activation sequences at a microscopic level can best be constructed on the basis of Laplacian signals.

Cell swelling and depolarization in hemorrhagic shock

Although an increase in intracellular water volume (IWV) in hemorrhagic shock has been inferred from measured changes in transmembrane potential, it has not been measured directly. We have described the presence of a circulating protein that appears in hemorrhagic shock [circulating shock protein (CSP) 70] that depolarizes numerous cell types. To determine if this substance produced a concurrent increase in intracellular water, cells were incubated with CSP 70. Then we measured IWV as the difference between the 3H water space and the [14C]mannitol space. CSP 70 increased IWV 9% in rat red blood cells (RBCs) (n = 8, p < 0.05), 22% in rat H9c2 cells (n = 7, p < 0.05), 11% in dog RBCs (n = 10, p < 0.005), and 31% in dog white blood cells (n = 8, p < 0.005). The results indicate that a protein that circulates in hemorrhagic shock depolarizes cells and increases intracellular water. This suggests that the changes in transmembrane potential observed in hemorrhagic shock are accompanied by movement of extracellular fluid into cells and may account for the inability to restore blood volume after large hemorrhage.

Extracellular glutamate flux regulates intracellular glutaminase activity in LLC-PK1-F+ cells

The role of extracellular glutamate flux in regulating intracellular glutaminase activity was assessed in confluent monolayers of proximal tubule-like LLC-PK1-F+ cells grown on porous supports. Glutamate is a well-known inhibitor of phosphate-dependent glutaminase (PDG). We hypothesized that, by restricting the flux of glutamate from the extracellular media, cellular level would fall, effecting deinhibition of the cellular glutaminase activity. To test this, cellular glutamate uptake and extracellular production were inhibited for 18 h by the addition of D-aspartate (10 mM) or acivicin (0.7 mM) to both apical and basal media. Inhibiting glutamate flux depressed cellular glutamate content 43 and 41%, respectively. Intracellular relative glutaminase activity, monitored as the breakdown of 14C-radiolabeled glutamine to glutamate, measured over 60 s in the presence of D-aspartate or acivicin showed a 2- to 2.5-fold increase with the fall in cellular glutamate. Interestingly, enhanced glutamine uptake after PDG deinhibition was predominantly expressed on the basal surface. Indeed, measuring glutamine utilization after gamma-glutamyltranspeptidase inhibition over the entire 18-h time course revealed inhibition at the apical surface but relative enhancement of uptake at the basal surface. The increased intracellular glutaminase pathway was also reflected in increased alanine production measured over the 18-h time course, despite the reduction in overall glutamine utilization. These results point to a major role for extracellular glutamate fluxes in regulating cellular glutamine metabolism and suggest that the intracellular pathway may be suppressed under these conditions.

Apoptosis induced by IL-2 withdrawal is associated with an intracellular acidification

It is known that phorbol esters can protect IL-2-dependent lymphocytes against apoptosis induced by IL-2 withdrawal. However, the mechanism of this effect remains unclear. In this article we show that apoptosis induced by IL-2 withdrawal in the CTLL-2 cell line correlates with a decrease in intracellular pH (pHi). Supplementing the incubation medium with phorbol esters during IL-2 deprivation protects CTLL-2 cells against both apoptosis and intracellular acidification. Interestingly, IL-4 also supports short-term cell survival and maintenance of normal pHi. The protein kinase inhibitor staurosporine prevents the protective effects of IL-2, PMA, and IL-4 on apoptosis and intracellular acidification. In contrast, inhibition of the Na+/H+ antiporter by 5-N-ethyl-N-isopropyl amiloride reverts the protective effects of PMA and IL-4, but only weakly affects IL-2-mediated suppression of apoptosis. Taken together, these results indicate that intracellular acidification may be an important event during apoptosis induced by IL-2 deprivation in the CTLL-2 cell line. Moreover, they suggest a key role for protein kinase C activation both in the maintenance of pHi and in the suppression of apoptosis, through mechanisms which rely on the activation of the Na+/H+ antiporter to a different extent, depending on the rescuing factor employed.

Fluid phase endocytosis by isolated rabbit lacrimal gland acinar cells

It is well known that lacrimal gland acinar cells retrieve secretory vesicle membrane constituents from their apical plasma membranes after stimulated exocytosis of secretory proteins. There have also been indications of a recycling traffic involving the basal-lateral plasma membranes. In an effort to document this traffic, determine how it is regulated, and discern whether it involves more than one intracellular compartment, we studied internalization of the fluid phase marker, Lucifer Yellow, and its relationship to protein release in acinar cells isolated from rabbit lacrimal glands. Loading of intracellular vesicles was apparent with fluoresence microscopy. Stimulation with carbachol increased both the rate of internalization and the intracellular volume equilibrating with extracellular fluid, suggesting the loading of two compartments. A carbachol concentration of 10 microM increased uptake by 80% during 20-min incubations at 37 degrees C. Increasing the carbachol concentration to 1 mM reduced the response by 50%, and it appeared to do so by decreasing the intracellular volume accessible to extracellular fluid, rather than the rate of endocytosis. Carbachol affected protein release differently, increasing it by 50% at 10 microM and 80% at 1 mM. Acceleration of endocytosis by 10 microM carbachol was transient, becoming negligible after 60 min. Vasoactive intestinal peptide (VIP) and isoproterenol increased internalization 35% and 25% respectively; neither reduced uptake at the highest concentrations tested; and only isoproterenol significantly affected protein secretion. Combinations of VIP and carbachol exerted synergistic effects on both fluid phase internalization and protein release. Steady-state uptake at 18 degrees C in the presence of 10 microM carbachol was equal to uptake at 37 degrees C in the absence of carbachol, suggesting a temperature block in the pathway to at least one endocytic compartment. Decreasing the temperature to 18 degrees C eliminated the inhibitory action of excessive carbachol, suggesting that the compartment whose loading was impaired by excessive carbachol was positioned distal to the temperature block. Carbachol accelerated release of marker from preloaded cells, indicating that it stimulated recycling between the plasma membranes and endocytic compartments. This effect was maximal at a concentration of 10 microM and unchanged with increasing concentrations. In accord with the hypothesis that traffic into and out of a certain compartment was particularly dependent on stimulation, a fraction of the marker taken up by optimally stimulated cells at 37 degrees C was retained unless carbachol or VIP was present in the efflux medium.(ABSTRACT TRUNCATED AT 400 WORDS)

Na(+)-H+ exchange in resident alveolar macrophages: activation by osmotic cell shrinkage

Intracellular pH (pHi) homeostasis in resident alveolar macrophages (m phi) under nominally CO2-free conditions is mediated primarily by the activity of plasmalemmal H(+)-ATPase. The m phi also possess an Na(+)-H+ exchanger (NHE) but this mechanism has no detectable role in pHi regulation in the physiologic range. To further explore the physiological significance of the NHE in this cell type, resident alveolar m phi from rabbits were subjected to a hyperosmotic challenge (approximately 620 mOsm/kg) in the nominal absence of CO2-HCO3-. Osmotic cell shrinkage was accompanied by an amiloride-sensitive increase in baseline pHi. The NHE-mediated rate of pHi recovery from intracellular acid loads also increased under hyperosmotic conditions. Cell shrinkage caused an alkaline shift in the pHi set point of the NHE without altering the exchanger's affinity for extracellular Na+. The results indicate that Na(+)-H+ exchange in resident alveolar m phi is activated by osmotic cell shrinkage and imply that the NHE may be involved in volume regulatory responses of the cell.

Effects of physiological state on oral habituation in developing rats: cellular and extracellular dehydration

Hydrational state has been demonstrated to influence intake of various solutions in young rat pups. For instance, both cellular and extracellular dehydration produce an enhancement of intake in pups tested at 6 days of age. However, the behavioral mechanisms that result in increased intake following manipulations of hydrational state have been less extensively studied. The impact of hydrational state on behavioral responsiveness in young rat pups was examined by assessing the pattern of responding to a series of repeated oral infusions of diet. Pups were tested at 6, 12, or 18 days of age following either acute cellular dehydration produced by injection of 1 M NaCl or acute extracellular dehydration produced by injection of 10% polyethylene glycol (PEG). Oral responsiveness to a series of 30 brief infusions of one of four taste solutions (water, 10% sucrose, 0.135 M NaCl, or 1 M NaCl) was measured. Each infusion lasted 3 s and there was 1 min between infusions. The pattern of oral responding to solutions was affected by the developmental age of the pup, the hydrational state of the pup, and the solution offered, with the largest effects of dehydration observed in the youngest animals. In all conditions except one, pups habituated to repeated infusions. The exception was the failure of extracellularly dehydrated 6-day-old pups to display habituation to oral infusions of sucrose. These results suggest that, although intake is enhanced by both cellular and extracellular dehydration in very young pups, the behavioral changes responsible for the enhancement of intake after cellular dehydration are different from the behavioral changes resulting from extracellular dehydration. This dissociation of behavioral effects of dehydration in young pups demonstrates that intake measures alone may obscure subtle differences in behavior and argues for the utility of dissection of behavioral components in understanding the neural and physiological control of behavior.

Survival factors, intracellular signal transduction, and the activation of endonucleases in apoptosis

Cell survival is normally mediated by factors in the extracellular environment, whereas genetic changes that constitutively activate intracellular survival pathways often occur in cancer. It is suggested that a Ras/Raf/MAP kinase-dependent pathway is critical for cell survival. Apoptosis results from loss of these survival factors or deregulation of survival pathways. If protein kinase cascades mediate survival, then it is likely that phosphatases mediate apoptosis. Potential targets for dephosphorylation include regulators of ion homeostasis as these have been implicated in the regulation of endonucleases associated with apoptosis. Survival factors also modulate anticancer drug response and understanding these pathways may improve therapy.

Regulation of intracellular pH in periportal and perivenular hepatocytes isolated from ethanol-treated rats

The aim of this study was to gain information on intracellular pH (pHi) regulation in periportal (PP) and perivenular (PV) hepatocytes isolated from rats pair-fed liquid diets with either ethanol (T rats) or isocaloric carbohydrates (C rats). pHi was analyzed by the pH-sensitive dye BCECF in perfused subconfluent hepatocyte monolayers. Cells were acid-loaded by pulse exposure to NH4Cl and were alkali-loaded by suddenly reducing external CO2 and HCO3- (from 10% and 50 mM, respectively, to 5% and 25 mM) at constant pHout. In cells from C rats: (a) steady-state pHi was higher in PP than in PV hepatocytes in the presence, but not in the absence, of bicarbonate; (b) pHi recovery from an acid load was 35% higher in PP than in PV cells in the presence of HCO3-, whereas it was similar in HCO3(-)-free experiments; and, on the contrary, (c) pHi recovery from an alkaline load was 30% higher in PV than in PP cells. In cells from T rats: (a) steady-state pHi was always lower than in cells isolated from pair-fed animals; (b) steady-state pHi was similar in PP and PV hepatocytes either in the presence or absence of bicarbonate in the perfusate; (c) pHi recovery from an acid load was not significantly different in PP and PV cells either in the presence of HCO3- or in HCO3(-)-free experiments; and (d) pHi recovery from an alkaline load was similar in PP and PV cells. Our data suggest that chronic ethanol treatment selectively modifies pHi by affecting the activity of ion transport mechanisms regulating pHi in PP and PV hepatocytes isolated from rat liver.

Platelet-vessel wall interactions, focal adhesions, and the mechanism of action of endothelial factors

Endothelial cells produce a variety of vasoactive substances including prostacyclin (PGI2) and endothelium-derived relaxing factor (EDRF/NO) which are potent inhibitors of platelet adhesion/aggregation and vascular smooth muscle cell contraction/proliferation. PGI2 and EDRF elevate cAMP or cGMP, respectively, in vascular cells and other targets. The intracellular effects of cAMP and cGMP in vascular smooth muscle cells and platelets are primarily mediated by the family of cAMP- and cGMP-dependent protein kinases and their substrates. Important effector systems include enzymes, channels and regulatory proteins responsible for the regulation of intracellular Ca++. Other evidence suggests that VASP, a focal adhesion protein phosphorylated in platelets and smooth muscle cells in response to PGI2 and EDRF, is important for the regulation of integrins and cell-matrix interactions.

Criteria for intracellular identification of pre-sympathetic neurons in the rostral ventrolateral medulla in the rat

Previous studies revealed that a relatively small group of reticulospinal neurons located in the rostral ventrolateral medulla (RVLM) plays a key role in the generation of resting vasomotor tone and in reflex control of arterial blood pressure. These medullary pre-sympathetic neurons have been extensively studied with extracellular microelectrodes, but so far few attempts have been made to examine their intracellular properties in vivo. This report, based on intracellular recordings from 8 RVLM pre-sympathetic neurons in anaesthetised rats, sets out criteria for intracellular identification of such neurons. We propose that two features are sufficient to classify RVLM neurons as pre-sympathetic during intracellular recording: inhibitory response to stimulation of the aortic depressor nerve with short bursts of pulses applied at low frequency; and antidromic stimulation from the upper thoracic segments. Cardiac oscillations in the membrane potential or responses during large changes in blood pressure can be due to movement artefact, and are therefore not reliable as a means of demonstrating baroreceptor input. Further intracellular studies of these neurons will undoubtedly result in further progress in understanding their function.

Inter- and intracellular computation models based on Boolean vs. non-Boolean inconsistency

Systems involving both intracellular and intercellular computation are destined to be described as non-computable. We propose a model for such systems by introducing the inconsistent relation of Boolean and non-Boolean logic. Cellular automata fashioned model exhibits an evolution like class 4 located at the edge of chaos, while there is no local rule for universality existing over the whole space in our model. A system featuring the inconsistent vertical scheme is approximately articulated into a hierarchical system, whose wholeness cannot be deduced by any approximated local rule. In other words, undecidability between a part and whole comprises a hierarchical structure.

Intramuscular pressure, torque and swelling for the exercise-induced sore vastus lateralis muscle

This study investigated changes in intramuscular fluid pressure (IMP), torque and swelling related to delayed onset muscle soreness (DOMS) of the vastus lateralis muscle. IMP was measured via catheterization in the unstretched (0 degree, full extension) and stretched (90 degrees of knee flexion) muscle at rest; then IMP and knee extension torque were determined during maximal contractions pre and 2 d after (post) repetitive eccentric activity in one leg for eight male subjects. DOMS of the vastus lateralis muscle was associated with a significant elevation in IMP at rest as indicated by pre (0 degree: 5.4 mmHg, 90 degrees: 80 mmHg) and post (0 degree: 8.4 mmHg, 90 degrees: 13.2 mmHg) comparisons (P = 0.02). Soreness symptoms were aggravated when the muscle was stretched and this was accompanied by a significantly higher post IMP at 90 degrees vs. 0 degree (P = 0.01). During maximal contractions, peak torque declined by 15% relative to pre and peak IMP declined by 26%; DOMS symptoms, however, were most severe during this manoeuvre. Biopsies from the sore vastus lateralis muscle revealed significantly larger fibre areas for all fibre types as compared with contralateral controls (P < 0.01); however, no differences were detected for extracellular volume percent comparisons. This study shows that DOMS of the vastus lateralis muscle is associated with extensive intracellular swelling and with elevated IMP. In line with previous studies, fibre swelling may be a common subsequence to repetitive eccentric activity; the ability of IMP measurements to detect this swelling at rest and during various manoeuvres for other muscles may depend on compartmental compliance.

Hemolytic properties of Ca(2+)-treated human erythrocytes under hydrostatic pressure

The effect of intracellular Ca2+ on high pressure-induced hemolysis of human erythrocytes was examined. Red cells were incubated with Ca2+ (0.01-1 mM) in the presence of ionophore A23187. The Ca(2+)-loaded cells were subjected to a pressure of 200 mPa. Treatment with 0.1 mM Ca2+ had the greatest suppressive effect on the hemolysis. On removal of intracellular Ca2+, red cells showed a morphological change from echinocytes to normal discocytes but the hemolysis remained unaltered. Measurement of intracellular K+ and viscosity demonstrated that the suppressive effect of Ca2+ on the hemolysis is irreversible and is largely associated with the increase of intracellular viscosity induced by K+ efflux.