Noninvasive cardiac output determination using inhaled oxygen-15-labeled carbon dioxide

Inhaled oxygen-15-labeled carbon dioxide (CO2*) is hydrated in the alveolar capillary blood to produce oxygen-15-labeled water (H2O*). This allows noninvasive delivery of a traceable indicator into the pulmonary circulation. Removal of oxygen-15 marker from the lung is a function of pulmonary perfusion. Two techniques were evaluated for computing cardiac output (CO) following single bolus inhalation of CO2*: 1) continuous monitoring of arterial blood activity through an external detector and 2) noninvasive positron imaging of oxygen-15-label washout from the chest and simultaneous emergence of activity in arterial blood. In seven mongrel dogs studied using technique 1, 46 determinations of CO were made from 1.2 to 8.0 l/min and compared with simultaneous indocyanine green dye-dilution determination. Correlation coefficient was 0.90 with slope of linear regression of 1.05. In 12 mongrel dogs studied using technique 2, 23 determinations of CO were made from 0.9 to 9.2 l/min and compared with simultaneous indocyanine green dye determination. Correlation coefficient was 0.985 (P less than 0.001) with slope of linear regression of 0.898. This noninvasive technique (2) for determination of CO is independent of assumptions regarding regional ventilation or perfusion of the lung and appears valid in animal studies.     

Gase als zelluläre Signalstoffe. Gasotransmitter

Gasotransmitters – gases as cellular signalling molecules The gases nitric oxide (NO), carbon monoxide (CO) and hydrogen sulphide (H₂S) because of their capacity as signalling molecules have been now collectively termed “gasotransmitters”. These gases play an important role in inter‐ and intracellular signalling, as in the digestive, respiratory or urogenital tract, in controlling heart activity or in nerve function. Research now tries to work out functions and further details about the mechanism of action of these gases and their implications for physiology, pathophysiology and pharmacology. The most recent candidate, H2S, is found in high concentrations in the brain and in the testis and hence is involved in learning/memory and in reproductive functions. The development of new substances interfering with the production of H₂S or its targets may constitute an interesting pharmacological potential.     

Microbial CO conversions with applications in synthesis gas purification and bio-desulfurization

Recent advances in the field of microbial physiology demonstrate that carbon monoxide is a readily used substrate by a wide variety of anaerobic micro-organisms, and may be employed in novel biotechnological processes for production of bulk and fine chemicals or in biological treatment of waste streams. Synthesis gas produced from fossil fuels or biomass is rich in hydrogen and carbon monoxide. Conversion of carbon monoxide to hydrogen allows use of synthesis gas in existing hydrogen utilizing processes and is interesting in view of a transition from hydrogen production from fossil fuels to sustainable (CO2-neutral) biomass. The conversion of CO with H2O to CO2 and H2 is catalyzed by a rapidly increasing group of micro-organisms. Hydrogen is a preferred electron donor in biotechnological desulfurization ofwastewaters and flue gases. Additionally, CO is a good alternative electron donor considering the recent isolation of a CO oxidizing, sulfate reducing bacterium. Here we review CO utilization by various anaerobic micro-organisms and their possible role in biotechnological processes, with a focus on hydrogen production and bio-desulfurization.     

The Secretion of Oxygen into the Swim-bladder of Fish : II. The simultaneous transport of carbon monoxide and oxygen

Toadfish, Opsanus tau, L., were maintained in sea water equilibrated with gas mixtures containing a fixed proportion of oxygen and varying proportions of carbon monoxide. The swim-bladder was emptied by puncture, and, after an interval of 24 or 48 hours, the newly secreted gases were withdrawn and analyzed. Both carbon monoxide and oxygen are accumulated in the swim-bladder at tensions greater than ambient. The ratio of concentrations, carbon monoxide (secreted): carbon monoxide (administered) bears a constant relation to the ratio, oxygen (secreted): oxygen (administered). The value of the partition coefficient describing this relation is (α = 5.44). The two gases are considered to compete for a common intracellular carrier mediating their active transport. The suggestion is advanced that the intracellular oxygen carrier is a hemoglobin. Comparison of the proportions of carboxy- and oxyhemoglobin in the blood with the composition of the secreted gas proves that the secreted gases are not evolved directly from combination with blood hemoglobin. The suggestion is advanced that cellular oxygen secretion occurs in the rete mirabile: the rete may build up large oxygen tensions in the gas gland capillaries. It is suggested that the gas gland acts as a valve impeding back diffusion of gases from the swim-bladder.     

Microbial CO Conversions with Applications in Synthesis Gas Purification and Bio-Desulfurization

ABSTRACT

Recent advances in the field of microbial physiology demonstrate that carbon monoxide is a readily used substrate by a wide variety of anaerobic micro-organisms, and may be employed in novel biotechnological processes for production of bulk and fine chemicals or in biological treatment of waste streams. Synthesis gas produced from fossil fuels or biomass is rich in hydrogen and carbon monoxide. Conversion of carbon monoxide to hydrogen allows use of synthesis gas in existing hydrogen utilizing processes and is interesting in view of a transition from hydrogen production from fossil fuels to sustainable (CO₂-neutral) biomass. The conversion of CO with H₂O to CO₂ and H₂ is catalyzed by a rapidly increasing group of micro-organisms. Hydrogen is a preferred electron donor in biotechnological desulfurization of wastewaters and flue gases. Additionally, CO is a good alternative electron donor considering the recent isolation of a CO oxidizing, sulfate reducing bacterium. Here we review CO utilization by various anaerobic micro-organisms and their possible role in biotechnological processes, with a focus on hydrogen production and bio-desulfurization.     

Homonuclear and heteronuclear transition metal complexes by syn-proportionation reactions

Redox processes consisting of disproportionation and syn-proportionation are reviewed with special attention to metal complexes containing carbon-based ligands, i.e. carbon monoxide or unsaturated hydrocarbons. An introduction and a survey of reactions aimed to show the large applicability of syn-proportionation reactions in the field of coordination chemistry, is followed by examples of the use of these redox processes for the preparation of catalytic precursors. The latter studies derive from the idea that if a syn-proportionation reaction can be carried out between two complexes containing different metals in different oxidation states, inter-metallic systems could be formed which may act as active catalysts, e.g. for polymerization reactions.     

Heterogeneity in the actin activation of myosin

The soluble proteolytic fragments of myosin, heavy meromyosin and subfragment 1, were prepared with varying amounts of the proteases chymotrypsin and papain, respectively. The actin-activated ATP hydrolysis were examined with oxygen-18-labeled ATP. Each preparation of heavy meromyosin and subfragments 1 displayed two pathways of ATP hydrolysis, called respectively the high and low oxygen exchange mechanisms. The contributions of the two mechanisms were found to be sensitive to the potassium chloride concentration. With a fixed concentration of actin (300 microM), the contribution of the low-exchange mechanism decreased from a maximum of 90% of the ATP hydrolysis at 10 and 20 mM KCl to 12% at 180 mM KCl. The results suggested that the two mechanisms were competing reactions catalyzed by a single species of myosin.     

Circulatory effects and kinetics following acute administration of carbon monoxide in a porcine model

Carbon monoxide is produced in the endothelial cells and has possible vasodilator activity through three different pathways. The aim of this study was to demonstrate circulatory effects after administration of saturated carbon monoxide blood and to describe the pharmacokinetics of carbon monoxide. Six pigs were anesthetized and 150 ml blood was removed. This blood was bubbled with carbon monoxide until the carboxyhemoglobin (COHb) levels were 90-99%. A specific amount of this blood was then injected back to the animal. At predetermined times; arterial and mixed venous blood was drawn and analyzed for carbon monoxide. Systemic and pulmonary vascular resistance index (SVRi and PVRi) were measured and exhaled air was sampled and measured for carbon monoxide. Blood samples were gathered over 300 minutes along with measurements of invasive pressures, heart rate, cardiac output, oxygen saturation (SpO2), Hb, temperature and blood gases. We conclude that this type of exposure to carbon monoxide appears to have little or no effect on general vasomotor tone and, after correcting for basal levels of carbon monoxide, elimination occurs through the lungs as predicted by a single compartment model. The half-life of carbon monoxide was determined to be 60.5 minutes (SEM 4.7).     

The inhibition of mitochondrial cytochrome oxidase by the gases carbon monoxide, nitric oxide, hydrogen cyanide and hydrogen sulfide: chemical mechanism and physiological significance

The four gases, nitric oxide (NO), carbon monoxide (CO), hydrogen sulfide (H₂S) and hydrogen cyanide (HCN) all readily inhibit oxygen consumption by mitochondrial cytochrome oxidase. This inhibition is responsible for much of their toxicity when they are applied externally to the body. However, recently these gases have all been implicated, to greater or lesser extents, in normal cellular signalling events. In this review we analyse the chemistry of this inhibition, comparing and contrasting mechanism and discussing physiological consequences. The inhibition by NO and CO is dependent on oxygen concentration, but that of HCN and H₂S is not. NO and H₂S are readily metabolised by oxidative processes within cytochrome oxidase. In these cases the enzyme may act as a physiological detoxifier of these gases. CO oxidation is much slower and unlikely to be as physiologically important. The evidence for normal physiological levels of these gases interacting with cytochrome oxidase is equivocal, in part because there is little robust data about their steady state concentrations. A reasonable case can be made for NO, and perhaps CO and H₂S, inhibiting cytochrome oxidase in vivo, but endogenous levels of HCN seem unlikely to be high enough.     

Metabolism of haloforms to carbon monoxide. IV. Studies on the reaction mechanism in vivo

In vivo studies have been carried out in order to understand more fully the mechanism of haloform oxidation to carbon monoxide. A deuterium isotope effect on carbon monoxide production from chloroform was observed in both control and phenobarbital-treated rats. Diethyl maleate treatment decreased blood carbon monoxide concentrations produced from bromoform and chloroform and attenuated the effect of deuterium substitution on the metabolism of both compounds to carbon monoxide. Cysteine also decreased blood carbon monoxide concentrations seen after giving chloroform. A reaction mechanism similar to that proposed on the basis of in vitro data, which included a central role for dihalocarbonyl compounds in the formation of 2-oxothiazolidine-4-carboxylic acid, carbon monoxide, and carbon dioxide, is suggested for the in vivo metabolism of haloforms to carbon monoxide. These data indicate that carbon monoxide production may be a detoxification pathway for haloforms and that both the inhibition of carbon monoxide production from haloforms and the potentiation of haloform-hepatotoxicity by diethyl maleate are due to the depletion of glutathione.     

Heme oxygenase activity as measured by carbon monoxide production

A method is described for the in vitro determination of heme oxygenase (HO) activity in animal tissue preparations through determination of carbon monoxide production. Tissue homogenates were centrifuged and the 13,000g supernatants were incubated in septum-sealed vials with methemalbumin in the presence and absence of NADPH at 37 degrees C for 15 min. The reaction was terminated by quick-freezing to -78 degrees C and the amount of carbon monoxide released into the headspace was determined by gas chromatography with a reduction gas detector. The CO produced through mediation of NADPH is used as a measure of HO activity and is expressed as nanomoles of CO produced per hour per milligram protein. The method permits analysis of as little as 2 microliter normal rat tissue homogenate representing 0.4 mg liver tissue (approx 40 micrograms total protein). The assay rate is 10-15 duplicate samples per hour with a precision of 3% for sample (4.47 +/- 0.13 SD nmol CO/h/mg protein) and 6% for blank reactions (0.59 +/- 0.10 nmol CO/h/mg protein) for 10 microliter liver supernatant. Various reaction parameters were studied. The method was used to compare HO activity in several tissue homogenates from normal rats and rats treated with COCl2.     

Kinetic and equilibrium studies of the reactions of heme-substituted horse heart myoglobins with oxygen and carbon monoxide.

In order to study the effects of chemical modifications of the vinyl groups of heme on oxygen and carbon monoxide binding to myoglobin, apomyoglobins from horse heart were reconstituted with six different hemins with various side chains. Laser flash photolysis experiments of these reconstituted myoglobins showed that the combination rate constants for oxygen (k') and carbon monoxide (l') were closely related to the electron-attractive properties of the side chains. The k' values obtained in 0.1 M potassium phosphate buffer, pH 7.0, at 20 degrees were 0.83 (meso-), 2.4 (deutero-), 1.1 (reconstituted proto-), 1.2 (native proto-), 1.5 (2-formyl-4-vinyl-), 1.9 (2-vinyl-4-formyl-), and 2.7 X 10(7) M-1 S-1 (2,4-diformylmyoglobins), and the corresponding l' values were 2.8, 18, 4.8, 5.1, 7.1, 15, and 35 X 10(5) M-1 S-1, respectively. These rate constants tend to increase as the electron-withdrawing power of the side chains increases, indicating that reduced electron density of the iron atom of heme in myoglobin favors the combination reaction for both oxygen and carbon monoxide. Equilibrium constants (L) between carbon monoxide and various myoglobins were also determined by measuring the partition coefficients (M) between oxygen and carbon monoxide for the myoglobins, and were also found to be closely related to the electronic properties (pK3 of porphyrin) of the heme side chains. The equilibrium association constants for carbon monoxide thus obtained increased with a decrease in pK3 value of the porphyrin. This order was completely opposite to the case of the oxygen binding reaction. The dissociation rate constants for oxygen (k) and carbon monoxide (l) were calculated from the equilibrium and the combination rate constants. The dissociation rate constants showed a similar characteristic to the combination rate constants and increased with the increase in electron attractivity of heme side chains. The concomitant increase in both the combination and dissociation rate constants with increase in electronegativity of the iron atom suggests that these reactions have different rate determining steps, although such a reaction process is contradictory to the generally accepted concept that in a reversible reaction, both on and off reactions proceed through the same transition state. In the on reaction sigma bond formation appears to be dominant, while in the off reaction eta bond break-up is more important.     

Synthesis of organic compounds from carbon monoxide and water by UV photolysis

The photolysis of water vapor with carbon monoxide at 1849 Å yields alcohols, aldehydes and organic acids, with an overall quantum yield of 3.3×10^–2. This rather high quantum yield could have led to a contribution of 10¹¹ organic molecules cm^–2 sec^–1 to the pool of organic material on the primitive Earth. The reactions are initiated by the photolysis of water molecules and the resulting hydrogen atoms reduce the carbon monoxide to a variety of one and two carbon compounds. The organic molecules are dissolved in water and thus escape destruction by photolysis. Photolysis of water vapor with carbon dioxide did not yield organic compounds under these conditions.     

Glycine and alanine synthesis from formaldehyde and hydroxylamine in the field of ultrasound waves

High intensity ultrasound waves coupled with other form of energy obviously were initiators of pre-biochemical reactions; these reactions occurred in the water masses of the primordial Earth.Essential biological substances like formaldehyde, ammonia, hydrocyanic acid, and amino acids compounds similar to carbohydrates by their properties were synthesized in the field of ultrasound waves in model experiments.The main partners of these reactions are water and gases of reductional atmosphere: hydrogen, carbon monoxide, methane, nitrogen and argon.Formation of amino acids takes place in aqueous solutions of formaldehyde and hydroxylamine. The sonication yielded alanine and glycine, 2.0×10^–7 and 1.8×10^–7 molecules per 100 eV respectively.     

Oxygen and carbon monoxide kinetics of Glycera dibranchiata monomeric hemoglobin.

Oxygen and carbon monoxide kinetics of Glycera dibranchiata monomeric hemoglobin have been studied using laser photolysis, air flash, and stopped flow techniques. The reactions of this hemoglobin with both ligands were found to be more rapid than the corresponding reactions involving myoglobin and were also biphasic in nature, the rate constants being approximately an order of magnitude different for the fast and slow phases in each case. No pH or hemoglobin concentration dependence of the pseudo-first order rate constants was apparent between pH 6 and 9 and in the concentration range of 1.25 to 40 muM heme. Both fast and slow pseudo-first order oxygen combination rate constants varied linearly with oxygen concentration between 16 and 1300 muM. A first order slow relaxation was also noted which was linearly dependent on heme concentration and inversely dependent on oxygen concentration. This reaction has been shown to be due to a replacement of oxygen by carbon monoxide. The presence of this reaction is a result of the high affinity of Glycera monomer for carbon monoxide as shown by the partition coefficient Mr = approximately 20,000 ana an equilibrium dissociation constant of the order L = 1.1 X 10(-9) M.     

Gene‐Centric Metagenome Analysis Reveals Gene Clusters for Carbon Monoxide Conversion and Validates Isolation of a Clostridial Acetogen for C2 Chemical Production

Syngas fermentation is largely dependent on acetogens that occur in various anaerobic environmental samples including soil, sediment, and feces. Here the authors report the metagenomic isolation of acetogens for C2 chemical production from syngas. Screening acetogens for C2 chemical production typically involves detecting the presence of the Wood‐Ljungdahl Pathway for carbon monoxide conversion. The authors collect samples from river‐bed sediments potentially having conditions suitable for carbon monoxide‐converting anaerobes, and enrich the samples under carbon monoxide selection pressure. Changes in the microbial community during the experimental procedure are investigated using both amplicon and shotgun metagenome sequencing. Combined next‐generation sequencing techniques enabl in situ tracking of the major acetogenic bacterial group and lead to the discovery of a 16 kb of gene cluster for WLP. The authors isolat an acetogenic clostridial strain from the enrichment culture (strain H21‐9). The functional activity of H21‐9 is confirmed by its high level of production of C2 chemicals from carbon monoxide (77.4 mM acetate and 2.5 mM of ethanol). This approach of incorporating experimental enrichment with metagenomic analysis can facilitate the discovery of novel strains from environmental habitats by tracking target strains during the screening process, combined with validation of their functional activity.     

Carbon monoxide-induced localized toxic anoxia in the rat brain cortex.

A new method has been developed for the determination of maximal reduction of NAD in the rat cerebral cortex. NADH fluorescence (450 nm) induced by 366-nm light and UV reflectance were measured by a time-sharing light pipe fluorometer. The redox state of the cortical surface was altered by perfusion of oxygen or carbon monoxide through a Teflon chamber adjacent to the dura. This study examines changes caused by local perfusion with the two gases in normoxia, hypoxia, and anoxia. Alternation of topical carbon monoxide and oxygen becomes effective in altering the intracellular redox state at 15% inspired oxygen and caused 20% changes at zero inspired oxygen. Conversely, topical application of oxygen to the systemically anoxic tissue causes oxidation of reduced NAPH in the cells within the field of fluorometric observation equivalent to that caused by breathing approximately 8% oxygen systemically.     

Signal transduction by heme-containing PAS-domain proteins.

The most common physiological strategy for detecting the gases oxygen, carbon monoxide, and nitric oxide is signal transduction by heme-based sensors, a broad class of modular proteins in which a heme-binding domain governs the activity of a neighboring transmitter domain. Different structures are possible for the heme-binding domains in these sensors, but, so far, the Per-ARNT-Sim motif, or PAS domain, is the one most commonly encountered. Heme-binding PAS (heme-PAS) domains can accomplish ligand-dependent switching of a variety of partner domains, including histidine kinase, phosphodiesterase, and basic helix-loop-helix (bHLH) DNA-binding modules. Proteins with heme-PAS domains occur in all kingdoms of life and are quite diverse in their physiological roles. Examples include the neuronal bHLH-PAS carbon monoxide sensor NPAS2 that is implicated in the mammalian circadian clock, the acetobacterial oxygen sensor AxPDEA1 that directs cellulose production, and the rhizobial oxygen sensor FixL, which governs nitrogen fixation. What factors determine the range of detection of these sensors? How do they transduce their signal? This review examines the recent advances in answering these questions.