Gastrointestinal ischemia monitoring through impedance spectroscopy as a tool for the management of the critically ill

Impedance spectroscopy (IS) has been proposed as a tool for monitoring mucosal tissue ischemia and damage in the gut of critically ill patients resulting from shock and hypoperfusion. A specific device and system have been developed and tested for this specific application over the past 12 years by our research group. This paper reviews previously published studies as well as unpublished experimental results, and puts the whole in context and perspective to help understand this technology. Results presented include summaries of gastric reactance measurement understanding, in vivo measurements in animal models, clinical significance of the measurement, and future perspectives of clinical use of this technology. All of the experimental work done to date has been designed to determine the evolving device prototypes’ performance and limitations from an instrumentation point of view. Although there are still questions to be answered with regard to the IS measurement, we conclude that we have reached enough confidence in the measurement and the device’s performance and safety to begin clinically oriented research to learn how this technology may be useful in the diagnosis and management of different populations of the critically ill.     

Hemodynamic indices versus gastric tonometric measurements for prognosis of hemorrhagic shock: a porcine model

The aim of the study reported here was to assess the prognostic value of gastric tonometry and its implications in the initial phases of hemorrhagic shock. Hemorrhagic shock was induced by use of femoral arterial bleeding in 12 hybrid swine under general anesthesia. Approximately 30% of the circulating blood volume was removed, until mean arterial pressure of 45 mmHg was reached. The shock conditions were observed over a limited period (90 min) by comparing traditional hemodynamic parameters with gastric tonometric measurements and tissue oxygenation. After a shock period of 90 min without pharmacologic treatment, blood was collected in acid-citrate dextrose-treated bags and was reinfused via the right femoral vein. At the end of the experiment, seven animals had good hemodynamic recovery on reinfusion (group A), whereas values in five animals deceased in the same phase (group B). Hemodynamic and gastric tonometric results were compared between survivors and nonsurvivors. Intravascular volume restoration and reduction of systemic vascular resistance (SVR) enabled the animals of group A to maintain standard ventricular kinetics and recover in terms of splanchnic regional flow. In addition, increase in intramucosal gastric pH (pHi), decrease in the pH-gap (pHa-Hi), and progressive restoration in gastric wall tissue oxygenation (PtO2) also were observed. These results suggest that useful diagnostic and therapeutic indications can be obtained by acquisition of simple hemodynamic measurements at the beginning of the shock period. On the basis of results of statistical analysis, only mean arterial pressure and SVR were good indicators of shock development, whereas pHi was not a significant factor in this experimental model.     

血乳酸水平动态监测在危重症患者的应用的临床价值分析

目的:探讨动态监测动脉乳酸水平对危重患者的应用的临床价值分析。方法:对2010年2月~2011年6月间收治的危重病患者的血乳酸水平进行动态监测,通过比较死亡组患者和存活组患者乳酸水平及其它临床指标,比较不同乳酸水平组患者的临床资料来分析乳酸在危重症患者的应用价值。结果:死亡组和存活组患者在性别、年龄差异无明显的统计学意义(P>0.05);病死组乳酸水平、APACHEⅡ评分、住ICU时间(天)、机械通气时间明显高于生存组,差异有显著的统计学意义(P<0.01);严重乳酸酸中毒组患者在APACHEⅡ评分、休克发生率、MODS发生率、死亡发生率均明显高于乳酸酸中毒组和高乳酸血症组,差异有明显的统计学意义(P<0.05),乳酸酸中毒组休克发生率、MODS发生率、死亡发生率均明显高于高乳酸血症组,差异有明显的统计学意义(P<0.05)。结论:动态监测动脉乳酸水平是判断危重患者预后的一个良好指标,动脉乳酸越高,预后差。     

Brain Metabolism and Intracellular pH During Ischaemia: Effects of Systemic Glucose and Bicarbonate Administration Studied by 31P and 1H Nuclear Magnetic Resonance Spectroscopy In Vivo in the Lamb

Brain metabolism and intracellular pH were studied during and after episodes of incomplete cerebral ischaemia in lambs under sodium pentobarbitone anaesthesia. 31P and 1H magnetic resonance spectroscopy was used to monitor brain pHi and brain concentrations of inorganic phosphate (Pi), phosphocreatine (PCr), beta-nucleoside triphosphate (beta NTP), and lactate. Simultaneous measurements were made of arterio-cerebral venous concentration differences (AVDs) for oxygen, glucose, and lactate. Cerebral ischaemia was induced by a combination of bilateral carotid clamping and hypotension, and the acute effects of systemic administration of glucose and sodium bicarbonate were examined. The molar ratio of glucose to oxygen uptake by the brain (6G/O2) increased above unity during cerebral ischaemia. Statistically significant AVDs for lactate were not observed. Cerebral ischaemia was associated with a reduction in brain pHi PCr/Pi ratio, and an increase in brain lactate. No effect of arterial plasma glucose on brain lactate concentration or brain pHi was evident during cerebral ischaemia or in the postischaemic period. Administration of sodium bicarbonate systemically in the postischaemic period was associated with a rise in arterial and brain tissue PCO2. A fall in brain pHi occurred which was attributable in part to coincidental brain lactate accumulation. The increase in brain lactate measured by 1H nuclear magnetic resonance in vivo during ischaemia was insufficient to account for the change in buffer base calculated to have occurred from previous estimates of brain buffering capacity.     

Regulation of pH in individual pancreatic beta-cells as evaluated by fluorescence ratio microscopy

Pancreatic beta-cells are known to maintain intracellular pH (pHi) at a value well above that predicted from the electrochemical gradient. The mechanisms for the active extrusion of protons were examined by continuously monitoring pHi in individual beta-cells from ob/ob mice using the fluorescent indicator 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF). In a medium nominally devoid of bicarbonate, the steady-state pHi was 6.82 +/- 0.02 and the intracellular buffering capacity was equivalent to 79 +/- 3 mM/pH unit. pHi remained unaffected after raising the glucose concentration from 3 to 20 mM, it was lowered when depolarizing the beta-cells with tolbutamide and it increased in the presence of carbachol. After removal of Na+ there was a significant drop of pHi and blockage of the pHi recovery following acid loading with the NH4+ prepulse technique. Whereas addition of amiloride had a similar, but less pronounced effect, omission of Cl- resulted in moderate alkalinisation. After switching to a medium containing bicarbonate, minor acidification was followed by adjustment of pHi to a steady state higher than the initial one. The results indicate that the acid load arising from glucose metabolism in the beta-cells is effectively buffered and the protons extruded both by Na+-H+ and Cl- -HCO3- exchangers.     

pH regulation in spread cells and round cells

The aim of this work was to characterize the changes in pH regulation that lead to increased intracellular pH (pHi) in well-spread cells on tissue culture plastic relative to cells on a nonadhesive surface. Bicarbonate was not required for maintenance of a control steady state pHi or of the difference in pHi between round and spread cells. In the absence of bicarbonate, lowering the sodium content of the medium led to decreased pHi and elimination of the difference between round and spread cells. In the presence or absence of bicarbonate, adding ethylisopropyl amiloride lowered pHi and eliminated the difference between round and spread cells. Measurements of recovery from acute acidification in the absence of bicarbonate confirmed that Na+/H+ exchange was enhanced in spread cells. However, recovery from both acidification and alkalinization in the presence of bicarbonate showed that bicarbonate-dependent recovery in both directions, most likely due to sodium-dependent and -independent HCO3-/Cl- exchangers, was also stimulated in spread cells. We conclude that Na+/H+ exchange has a primary role in determining steady state pHi in 3T3 cells in serum and is responsible for the lower pHi in round cells. Bicarbonate-dependent pH regulatory mechanisms are also inhibited in round cells.     

基于能量代谢监测下肠内营养对老年危重症患者营养状态、肠道功能及免疫功能的影响

摘要 目的：探讨基于能量代谢监测下肠内营养（EN）对老年危重症患者肠道功能、营养状态、免疫功能的影响。方法：按照随机数字表法将南京市第一医院EICU 2020年4月~2023年1月期间收治的136例老年危重症患者分为对照组（常规EN）和研究组（基于能量代谢监测下接受常规EN）,各为68例。对比两组临床指标、营养状态、免疫功能指标、肠道功能指标和并发症发生率。结果：研究组的7 d内EN达标率、7 d内撤机成功率高于对照组,研究组的ICU住院时间、机械通气时间短于对照组,并发症总发生率低于对照组（P<0.05）。干预14 d后,研究组的白蛋白（ALB）、血清总蛋白（TP）、前白蛋白（PA）及血红蛋白（Hb）水平高于对照组（P<0.05）。干预14 d后,研究组的免疫球蛋白（Ig）M、IgG及IgA水平高于对照组（P<0.05）。干预14 d后,研究组的D-乳酸、二胺氧化酶（DAO）水平低于对照组（P<0.05）。结论：基于能量代谢监测下EN干预老年危重症患者,可进一步改善患者的营养状态、肠道功能及免疫功能。     

Increased heme catabolism in critically ill patients: correlation among exhaled carbon monoxide, arterial carboxyhemoglobin, and serum bilirubin IXalpha concentrations

It has been reported that exhaled carbon monoxide (CO) concentrations and arterial carboxyhemoglobin (CO-Hb) concentration in blood may be increased in critically ill patients. However, there was no study that examined correlation among amount of CO in exhaled air, CO-Hb concentrations in erythrocytes, and bilirubin IXalpha (BR) in serum, i.e., the three major indexes of heme catabolism, within the same subject. Here, we examined CO concentrations in exhaled air, CO-Hb concentrations in arterial blood, and BR levels in serum in 29 critically ill patients. Measurements of exhaled CO, arterial CO-Hb, and serum total BR have been done in the intensive care unit. As control, exhaled CO concentration was also measured in eight healthy volunteers. A median exhaled CO concentration was significantly higher in critically ill patients compared with control. There was significant correlation between CO and CO-Hb and CO and total BR level. We also found CO concentrations correlated with indirect BR but not direct BR. Multivariate linear regression analysis for amount of exhaled CO concentrations also showed significant correlation with CO-Hb and total BR, despite the fact that respiratory variables of study subjects were markedly heterogeneous. We found no correlation among exhaled CO, patients' severity, and degree of inflammation, but we found a strong trend of a higher exhaled CO concentration in survivors than in nonsurvivors. These findings suggest there is an increased heme breakdown in critically ill patients and that exhaled CO concentration, arterial CO-Hb, and serum total BR concentrations may be useful markers in critically ill conditions.     

Integrated duodenal protective response to acid.

The proximal duodenum is unique in that it is the only leaky epithelium regularly exposed to concentrated gastric acid. To prevent injury from occurring, numerous duodenal defense mechanisms have evolved. The most studied is bicarbonate secretion, which is presumed to neutralize luminal acid. Less well studied in their protective roles are the mucus gel layer and blood flow. Measuring duodenal epithelial intracellular pH [pHi], blood flow and mucus gel thickness (MGT), we studied duodenal defense mechanisms in vivo so as to more fully understand the mucosal response to luminal acid. Exposure of the mucosa to physiologic acid solutions promptly lowered pHi, followed by recovery after acid was removed, indicating that acid at physiologic concentrations readily diffuses into, but does not damage duodenal epithelial cells. Cellular acid then exits the cell via an amiloride-inhibitable process, presumably sodium-proton exchange (NHE). MGT and blood flow increase promptly during acid perfusion; both decrease after acid challenge and are inhibited by vanilloid receptor antagonists or by sensory afferent denervation. Bicarbonate secretion is not affected by acid superfusion but increases after challenge. Inhibition of cellular base loading lowers pHi, whereas inhibition of apical base extrusion alkalinizes pHi. These observations support the following hypothesis: luminal acid diffuses into the epithelial cells, lowering pHi. Acidic pHi increases the activity of a basolateral NHE, acidifying the submucosal space and increasing cellular base loading. The acidic submucosal space activates capsaicin receptors on afferent nerves, increasing MGT and blood flow. With concontinued acid exposure, a new steady state with thickened mucus gel, increased blood flow, and a higher cellular buffering power protects against acid injury. After acid challenge, mucus secretion decreases, blood flow slows, and pHi returns to normal, the latter occurring via apical bicarbonate extrusion, increasing bicarbonate secretion. Through these integrated mechanisms, the epithelial cells are protected from damage due to repeated pulses of concentrated gastric acid.     

Reduction of intracellular pH inhibits constitutive expression of cyclooxygenase-2 in human colon cancer cells

Cyclooxygenase-2 (COX-2) over-expression is critically involved in tumor formation. Intracellular pH (pHi) has been shown to be alkaline in cancer cells, and to be an important trigger for cell proliferation. This study therefore analyzed the relationship between pHi and COX-2 expression. HRT-18 and Caco-2 cells cultured in medium with bicarbonate maintained a pHi of approximately 7.6, which is higher than that of non-neoplastic cells. Cells grown in bicarbonate-free medium with a pH at 6.8 showed a reduction in pHi to approximately 7.0. Importantly, reduction of pHi resulted in a complete inhibition of COX-2 mRNA and protein expression. When cells were grown in bicarbonate-supplemented medium at pH 6.8, pHi maintained at approximately 7.6 and COX-2 expression was not inhibited. Additionally, analysis utilizing protein synthesis inhibitor cycloheximide demonstrated that pHi mediated inhibition of COX-2 mRNA expression requires de novo protein synthesis of regulatory protein(s). These data strongly suggest that an alkaline pHi is an important trigger for constitutive COX-2 expression. Defining pHi-mediated mechanisms that govern the constitutive COX-2 expression may help in developing new strategies to block COX-2 over-expression in cancer cells.     

Vacuolating cytotoxin A is associated with increased thrombin generation in gastric mucosa

BACKGROUND: Activation of the coagulation system is a critical response for both the repair of tissue injury and the host defense against microbial pathogens. Activation of the coagulation cascade culminates with the generation of thrombin. In vitro studies have shown that thrombin protects gastric epithelial cells from injury. The present study was undertaken to assess in vivo the relationship between gastric intramucosal generation of thrombin and Helicobacter pylori infection. MATERIALS AND METHODS: This study comprised 59 patients with gastroduodenal disorders. There were 27 patients with H. pylori infection (Hp+), 14 without it (Hp-), and 18 patients with cured H. pylori infection (Hp c). The gastric intramucosal concentrations of thrombin-antithrombin complex (TAT), epidermal growth factor (EGF), prostaglandin E2 (PGE2), and vacuolating cytotoxin A (VacA) were measured by specific immunoassays. RESULTS: The level of TAT was significantly increased in patients with Hp+ compared to Hp- and Hp c. The levels of TAT, EGF and PGE2 were higher in VacA (+) patients than in those with VacA (-). VacA induced significant expression of tissue factor in gastric epithelial cells in vitro. The gastric intramucosal level of VacA antigen was proportionally and significantly correlated with TAT, EGF and PGE2 in Hp+ patients. The level of TAT was proportionally and significantly correlated with EGF in Hp+ patients but not in Hp- and HP c patients. CONCLUSIONS: These results showed that VacA produced by H. pylori is associated with increased thrombin generation, and that thrombin may play a protective role in H. pylori-associated gastroduodenal disorders.     

Continuous hemodiafiltration with PMMA Hemofilter in the treatment of patients with septic shock

Septic shock is the most severe form of sepsis. It is widely accepted that cytokines play pivotal roles in the pathophysiology of septic shock. We reported previously that continuous hemodiafiltration (CHDF) using a polymethylmethacrylate (PMMA) membrane hemofilter removed various cytokines from blood continuously and efficiently, mainly by adsorption to membrane matrix of the hemofilter. Furthermore, in April 2000, we introduced to clinical practice a rapid assay system that determines blood levels of IL (interleukin)-6 in approximately 30 min. This enabled us to routinely measure blood IL-6 as an index of cytokine cascade activation in critically ill patients for real-time clinical monitoring of hypercytokinemia. The aim of the present cohort study was to evaluate the clinical efficacy of PMMA-CHDF in septic shock, a typical condition associated with hypercytokinemia. Forty-three patients with septic shock were assessed by monitoring of blood IL-6 level with a rapid assay system and immediate initiation of critical care including PMMA-CHDF for cytokine removal. Following initiation of PMMA-CHDF, early improvement of hemodynamics was noted, as well as an increase in urine output. PMMA-CHDF treatment improved both hypercytokinemia (assessed by measurement of blood IL-6 level) and dysoxia (assessed by measurement of blood lactate level). The present findings suggest that cytokine-oriented critical care using PMMA-CHDF might be an effective strategy for the treatment of septic shock.     

Kinetic assay for the determination of the oxidative stress biomarker, advanced oxidation protein products (AOPP) in the human blood plasma

A number of human diseases and pathological conditions were found to be associated with increased oxidative stress. In the literature several techniques are available for the assessment of oxidative stress, but most of them are not applicable for a routine medical laboratory due to the complex methodology and/or financial reasons. We report here on a simple, inexpensive, kinetic assay for the determination of the oxidative stress biomarker, advanced oxidation protein products (AOPP) in the human blood plasma. METHODS: This study involved 70 patients (47M/23F; mean age: 64.6 y; range: 16-85) admitted to our Department with a wide range of cardiovascular and peripheral vascular diseases. Three critically ill patients were assigned for monitoring purposes. Plasma AOPP were simultaneously determined using an end-point assay as reference method and by a kinetic method developed in our laboratory. Plasma fibrinogen concentration was measured according to the Clauss method. RESULTS: There was a highly significant correlation (r2 = 0.588; p < 0.0001) between AOPP concentration (reference method) and AOPP reactivity (kinetic method). Both AOPP concentration and AOPP reactivity also significantly correlated with plasma fibrinogen concentration (r2 = 0.780; p < 0.0001; r2 = 0.564; p < 0.0001). The three representative cases presented appear to support the relevance of our novel method in the monitoring of critically ill patients. CONCLUSIONS: This simple and inexpensive kinetic assay can be widely used in any routine laboratory interested in oxidative stress research. It is especially recommended for monitoring critically ill or other patients.     

Effect of glucose on the intracellular pH of pancreatic islet cells.

To characterize the effect of glucose on the intracellular pH (pHi) of pancreatic islet cells, we measured the accumulation of 14C-labelled 5,5-dimethyloxazolidine-2,4-dione ( [14C]DMO) in beta-cell-rich islets from ob/ob mice. D-Glucose (20 mM) stimulated insulin release and enhanced the [14C]DMO equilibrium uptake corresponding to an increase of pHi by about 0.15 unit. The glucose effect on DMO uptake was concentration-dependent, with half-maximal effect at about 4 mM-glucose and maximum effect at about 10 mM-glucose. It was inhibited by 20 mM-mannoheptulose and potentiated by 4 mM-L-5-hydroxytryptophan, but not affected by 2 mM-theophylline. Mannoheptulose is an inhibitor and L-5-hydroxytryptophan and theophylline are potentiators of glucose-stimulated insulin release. The glucose-induced increase in pHi appeared rapidly (7 min) and persisted for at least 30 min and it was observed both in bicarbonate/CO2-buffered and in Hepes [4-(2-hydroxyethyl)-1-piperazine-ethanesulphonic acid]-buffered media. Addition of extracellular bicarbonate buffer lowered the pHi, but did not affect basal insulin release, whereas 5 mM-NH4+ increased pHi and induced a 4-fold increase of basal insulin release. We conclude that, in contrast with previous assumptions, glucose increases intracellular pH in the islet cells. This effect may be coupled to the glucose metabolism and associated with triggering of insulin release.     

Enteral nutrition and hepatosplanchnic region in critically ill patients - friends or foes?

Enteral nutrition (EN) is a preferred way of feeding in critically ill patients unless obvious contraindications such as ileus or active gastrointestinal bleeding are present. Early enteral nutrition as compared to delayed EN or total parenteral nutrition decreases morbidity in postsurgical and trauma patients. The hepatosplanchnic region plays a pivotal role in the pathophysiology of sepsis and multiple organ dysfunction syndrome. The beneficial effects of EN on splanchnic perfusion and energy metabolism have been documented both in healthy volunteers and animal models of sepsis, hemorrhagic shock and burns. By contrast, EN may increase splanchnic metabolic demands, which in turn may lead to oxygen and/or energy demand/supply mismatch, especially when hyperemic response to EN is not preserved. Therefore, the timing of initiation and the dose of EN in patients with circulatory failure requiring vasoactive drugs are a matter of controversy. Interestingly, the results of recent clinical studies suggest that early enteral nutrition may not be harmful even in patients with circulatory compromise. Nevertheless, possible onset of serious complications, the non-occlusive bowel necrosis in particular, have to be kept in mind. Unfortunately, there is only a limited number of clinically applicable monitoring tools for the effects of enteral nutrition in critically ill patients.     

Vascular and lymphatic regulation of gastrointestinal function and disease risk

The vascular and lymphatic systems in the gut regulate lipid transport while restricting transfer of commensal gut microbiota and directing immune cell trafficking. Increased permeability of the endothelial systems in the intestine associates with passage of antigens and microbiota from the gut into the bloodstream leading to tissue inflammation, the release of pro-inflammatory mediators and ultimately to abnormalities of systemic metabolism. Recent studies show that lipid metabolism maintains homeostasis and function of intestinal blood and lymphatic endothelial cells, BECs and LECs, respectively. This review highlights recent progress in this area, and information related to the contribution of the lipid transporter CD36, abundant in BECs and LECs, to gastrointestinal barrier integrity, inflammation, and to gut regulation of whole body metabolism. The potential role of endothelial lipid delivery in epithelial tissue renewal after injury and consequently in the risk of gastric and intestinal diseases is also discussed.     

Gastric exocrine “failure” in critically ill patients: incidence and associated features

Following the observation that many critically ill patients cannot maintain their gastric juice pH below 4 without treatment a study was performed to measure the gastric juice pH in such patients and relate it to other clinical data. The case notes of 64 patients who had been admitted to the intensive care unit and taken part in two trials of ranitidine treatment were reviewed. During those trials gastric juice was aspirated hourly and the pH and volume measured. In this study the values recorded during a six hour untreated control phase were used. Data on age, diagnosis, treatment, outcome, episodes of hypoxia, episodes of hypotension, and use of inotropic drugs were also reviewed. Full data were available for 61 patients: 27 had a mean baseline pH of >5 during the control phase and 34 a mean baseline pH of <5. Significantly more of those with a high pH suffered hypotension (21/27 v 13/34) and received inotropic drugs (16/27 v 8/34).These findings suggest that hypotension in critically ill patients adversely affects gastric exocrine function; prophylaxis with drugs that can improve gastric mucosal blood flow may be more effective than with antacids.     

Perfusion pressure manipulation in porcine sepsis: effects on intestinal hemodynamics

Limited information is available about selection of the threshold for arterial blood pressure in critically ill patients, particularly in sepsis when normal organ blood flow autoregulation may be altered. The present experimental study investigated whether increasing perfusion pressure using norepinephrine in normotensive hyperdynamic porcine bacteremia affects intestinal macro- and microcirculation. Nine pigs received continuous i.v. administration of Pseudomonas aeruginosa (PSAE) to develop hyperdynamic, normotensive (mean arterial pressure [MAP] 65 mm Hg) sepsis. Norepinephrine was used to achieve 10-15 % increase in MAP. Mesenteric arterial blood flow (Q(gut)), ileal mucosal microvascular perfusion (LDF(gut)) and ileal-end-tidal PCO(2) gap (PCO(2) gap) were measured before norepinephrine, after 60 min of norepinephrine infusion and 60 min after norepinephrine infusion had been discontinued. During a 12 h period of PSAE infusion all pigs developed hyperdynamic circulation with significantly decreased MAP. Although the mesenteric blood flow remained unchanged, infusion of PSAE resulted in a gradual fall of ileal microvascular perfusion, which was associated with progressively rising PCO(2) gap. Norepinephrine which induced a 10-15 % increase in perfusion pressure (i.e. titrated to attain near baseline values of MAP) affected neither Q(gut) nor the intestinal blood flow distribution (Q(gut)/CO). Similarly, norepinephrine did not change either LDF(gut) or PCO(2) gap. In this hyperdynamic, normotensive porcine bacteremia, norepinephrine-induced increase in perfusion pressure exhibited neither beneficial nor deleterious effects on intestinal macrocirculatory blood flow and ileal mucosal microcirculation. The lack of changes suggests that the gut perfusion was within its autoregulatory range.     

Basic concepts of fluid responsiveness

Predicting fluid responsiveness, the response of stroke volume to fluid loading, is a relatively novel concept that aims to optimise circulation, and as such organ perfusion, while avoiding futile and potentially deleterious fluid administrations in critically ill patients. Dynamic parameters have shown to be superior in predicting the response to fluid loading compared with static cardiac filling pressures. However, in routine clinical practice the conditions necessary for dynamic parameters to predict fluid responsiveness are frequently not met. Passive leg raising as a means to alter biventricular preload in combination with subsequent measurement of the change in stroke volume can provide a fast and accurate way to guide fluid management in a broad population of critically ill patients.     

Dual control of the intracellular pH in aortic smooth muscle cells by a cAMP-sensitive HCO3-/Cl- antiporter and a protein kinase C-sensitive Na+/H+ antiporter

Two mechanisms are involved in the regulation of the intracellular pH (pHi) of aortic smooth muscle cells: the Na+/H+ antiporter and a Na+-independent HCO3-/Cl- antiporter. The Na+/H+ antiporter acts as a cell alkalinizing mechanism. It is activated by vasopressin and by phorbol esters when cells are incubated in the presence of bicarbonate but is not affected in the absence of bicarbonate. The HCO3-/Cl- antiporter acts as a cell acidifying mechanism. Agents such as forskolin, 8-Br-cAMP, and isoproterenol which raise intracellular cAMP levels inhibit the HCO3-/Cl- antiporter by shifting its pHi dependence in the alkaline direction. Thus, within the same cell type, different hormones control pHi variations by acting on different pHi regulating systems. An increase in pHi can be achieved either by a stimulation of a cell alkalinizing mechanism or by inhibition of a cell acidifying mechanism. A change of the activity of one pHi regulating mechanism modifies the responsiveness of the other to regulatory agents. Bicarbonate turns on the HCO3-/Cl- antiporter, decreases pHi and allows its regulation by protein kinase C through the Na+/H+ antiporter. Inhibition of the HCO3-/Cl- antiporter by cAMP increases the pHi and switches off the protein kinase C-mediated regulation.