Comparison of Methemoglobin, Deoxyhemoglobin, and Ferrous Nitrosyl Hemoglobin as Potential MRI Contrast Agents.

Gadolinium-based contrast agents (GBCAs) are in widespread use to enhance magnetic resonance imaging for evaluating vascular pathology. However, safety concerns and limitations regarding the use of GBCAs has led to an increased interest in alternative contrast agents. Previously, methemoglobin (metHb) and oxygen-free hemoglobin (HHb) have been shown to increase the T1-weighted signal intensity of blood, which is associated with a decrease in the T1 parameter and an enhanced contrast of the image. Thus, a lower T1 value compared to the baseline value is favorable for imaging. However, it is unknown as to whether metHb or HHb would be a stronger and more appropriate contrast agent and to what extent the T1-weighted signal is affected by concentration. This study evaluated T1-weighted images of blood samples over a range of metHb and HHb concentrations, as well as ferrous nitrosyl hemoglobin (HbIINO) concentrations. Comparison of T1 values from a baseline value of ~ 1500 ms showed that metHb is the strongest contrast agent (T1 ~ 950 ms at 20% metHb) and that HHb is a relatively weak contrast agent (T1 ~ 1450 ms at 20% HHb). This study showed for the first time that HbIINO can provide a contrast effect, although not as strong as metHb but stronger than HHb (T1 estimated as 1250 ms at 20% HbIINO). With metHb providing a viable contrast between 10 and 20%, metHb has the potential to be a safe and effective contrast agent since it can be naturally converted back to hemoglobin.

Rapid Formation of Methemoglobin via Nitric Oxide Delivery for Potential Use as an MRI Contrast Agent.

Contrast-enhanced magnetic resonance angiography is a vital tool for evaluating vascular pathology. However, concerns about the limitations and safety of gadolinium-based contrast agents have led to an interest in alternative agents. Methemoglobin (metHb) increases the T1-weighted signal intensity of the magnetic resonance image of blood and could provide a safe and effective alternative. MetHb can be produced by the reaction of nitric oxide (NO) gas with oxyhemoglobin followed by natural conversion back to hemoglobin by cytochrome b5 reductase. Since rapid production of metHb via NO has not been studied, the effectiveness of producing metHb via NO delivery to blood was evaluated using a hollow-fiber module. MetHb production began immediately and > 90% conversion was achieved within 10 min. MetHb remained stable for at least 90 min when NO delivery was removed following metHb formation. Comparison of experimental data for metHb formation with model predictions showed that only a fraction of the NO delivered was utilized for metHb production, suggesting an additional fast reaction of NO with other blood constituents. Directly delivering NO to blood for the rapid formation of metHb provides a potential platform for producing metHb as an alternative contrast agent.

Positive cooperativity during Azotobacter vinelandii nitrogenase-catalyzed acetylene reduction.

The MoFe protein component of the nitrogenase enzyme complex is the substrate reducing site and contains two sets of symmetrically arrayed metallo centers called the P (Fe8S7) and the FeMoco (MoFe7S9-C-homocitrate) centers. The ATP-binding Fe protein is the specific reductant for the MoFe protein. Both symmetrical halves of the MoFe protein are thought to function independently during nitrogenase catalysis. Forming [AlF4]- transition-state complexes between the MoFe protein and the Fe protein of Azotobacter vinelandii ranging from 0 to 2 Fe protein/MoFe protein produced a series of complexes whose specific activity decreases with increase in bound Fe protein/MoFe protein ratio. Reduction of 2H+ to H2 was inhibited in a linear manner with an x-intercept at 2.0 with increasing Fe protein binding, whereas acetylene reduction to ethylene decreased more rapidly with an x-intercept near 1.5. H+ reduction is a distinct process occurring independently at each half of the MoFe protein but acetylene reduction decreases more rapidly than H+ reduction with increasing Fe protein/MoFe protein ratio, suggesting that a response is transmitted between the two αß halves of the MoFe protein for acetylene reduction as Fe protein is bound. A mechanistic model is derived to investigate this behavior. The model predicts that each site functions independently for 2H+ reduction to H2. For acetylene reduction, the model predicts positive (synchronous) not negative cooperativity arising from acetylene binding to both sites before substrate reduction occurs. When this model is applied to inhibition by Cp2 and modified Av2 protein (L127∆) that form strong, non-dissociable complexes, positive cooperativity is absent and each site acts independently. The results suggest a new paradigm for the catalytic function of the MoFe protein during nitrogenase catalysis.

Measurement and prediction of mass transfer coefficients for syngas constituents in a hollow fiber reactor.

Syngas fermentation for producing biofuels and other products suffers from mass transfer limitations due to low CO and H2 solubility in liquid medium. Therefore, it is critical to characterize mass transfer rates of these gases to guide bioreactor design and optimization. This work presents a novel technique to measure the volumetric mass transfer coefficients (kia) for H2 and CO using gas chromatography in a non-porous hollow fiber reactor (HFR). The largest measured kia for H2 and CO were 840 and 420 h-1, respectively. A model was developed to predict kia for H2 and CO that agreed well with experimental data. This study is the first to measure, compare, and model both H2 and CO mass transfer coefficients in an HFR. Based on model predictions, HFRs have the potential to be a reactor of choice for syngas fermentation as a result of high mass transfer that can support high cell densities.

Ethanol production during semi-continuous syngas fermentation in a trickle bed reactor using Clostridium ragsdalei.

An efficient syngas fermentation bioreactor provides a mass transfer capability that matches the intrinsic kinetics of the microorganism to obtain high gas conversion efficiency and productivity. In this study, mass transfer and gas utilization efficiencies of a trickle bed reactor during syngas fermentation by Clostridium ragsdalei were evaluated at various gas and liquid flow rates. Fermentations were performed using a syngas mixture of 38% CO, 28.5% CO2, 28.5% H2 and 5% N2, by volume. Results showed that increasing the gas flow rate from 2.3 to 4.6sccm increased the CO uptake rate by 76% and decreased the H2 uptake rate by 51% up to Run R6. Biofilm formation after R6 increased cells activity with over threefold increase in H2 uptake rate. At 1662h, the final ethanol and acetic acid concentrations were 5.7 and 12.3g/L, respectively, at 200ml/min of liquid flow rate and 4.6sccm gas flow rate.

A comparison of mass transfer coefficients between trickle-bed, hollow fiber membrane and stirred tank reactors.

Trickle-bed reactor (TBR), hollow fiber membrane reactor (HFR) and stirred tank reactor (STR) can be used in fermentation of sparingly soluble gasses such as CO and H2 to produce biofuels and bio-based chemicals. Gas fermenting reactors must provide high mass transfer capabilities that match the kinetic requirements of the microorganisms used. The present study compared the volumetric mass transfer coefficient (K(tot)A/V(L)) of three reactor types; the TBR with 3 mm and 6 mm beads, five different modules of HFRs, and the STR. The analysis was performed using O2 as the gaseous mass transfer agent. The non-porous polydimethylsiloxane (PDMS) HFR provided the highest K(tot)A/V(L) (1062 h(-1)), followed by the TBR with 6mm beads (421 h(-1)), and then the STR (114 h(-1)). The mass transfer characteristics in each reactor were affected by agitation speed, and gas and liquid flow rates. Furthermore, issues regarding the comparison of mass transfer coefficients are discussed.

A thermodynamic analysis of electron production during syngas fermentation.

Currently, syngas fermentation is being developed as one option towards the production of biofuels from biomass. This process utilizes the acetyl-CoA (Wood-Ljungdahl) metabolic pathway. Along the pathway, CO and CO(2) are used as carbon sources. Electrons required for the metabolic process are generated from H(2) and/or from CO. This study showed that electron production from CO is always more thermodynamically favorable compared to electron production from H(2) and this finding is independent of pH, ionic strength, gas partial pressure, and electron carrier pairs. Additionally, electron production from H(2) may be thermodynamically unfavorable in some experimental conditions. Thus, it is unlikely that H(2) can be utilized for electron production in favor of CO when both species are present. Therefore, CO conversion efficiency will be sacrificed during syngas fermentation since some of the CO will provide electrons at the expense of product and cell mass formation.

Analysis of functionalized polyethylene terephthalate with immobilized NTPDase and cysteine.

Polyethylene terephthalate (PET) was functionalized to introduce carboxyl groups onto its surface by a carboxylation technique. Surface and bulk properties, such as possible surface deterioration, surface roughness and the mechanical strength of the carboxylated polymers, were studied and compared with those of aminolyzed and hydrolyzed PET. Atomic force microscopy studies showed that unlike aminolysis and hydrolysis, which increased the surface roughness significantly due to cracking and pitting, the surface roughness of unmodified and carboxylated PET were comparable. While hydrolysis and aminolysis of PET resulted in significant loss of strength, tensile testing revealed that unmodified and carboxylated polymers had similar strength. The development of mechanically stable, functionalized PET would vastly improve the biomedical applications of this polymer. To understand the potential for improving biomedical applications, biologically active molecules, namely nucleoside triphosphate diphosphohydrolase (NTPDase) and cysteine, were immobilized on the carboxylated PET using amide bonds. NTPDase was also immobilized to aminolyzed PET using imine bonds, while cysteine was immobilized on aminolyzed PET using both imine and amide bonds. Attachment of NTPDase and cysteine was verified by analyzing the NTPDase activity and the cysteine surface concentration. The stability of these immobilizations was also studied.

Effect of pH and metal ions on the decomposition rate of S-nitrosocysteine.

S-nitrosothiols (RSNOs) have many biological functions including platelet deactivation, immunosupression, neurotransmission, and host defense. Most of the functions are attributed to nitric oxide (NO) release during S-nitrosothiol decomposition. As the simplest biologically occurring S-nitrosothiol, S-nitrosocysteine (CySNO) has been widely used as an NO donor and has also been incorporated into biomedical polymers. Knowledge of the CySNO decomposition rate is important for assessing the impact of CySNO on various bioengineering applications or biological systems. In this work, spectrophotometer measurements of CySNO decomposition in the presence of metal ions showed that the decomposition rate is highly susceptible to the pH. The maximum decomposition occurs near physiological pH (near 7.4) while in the acidic (pH < 6) and alkaline (pH > 9) condition CySNO is very stable. This demonstrates that blood provides an optimized environment for the decomposition of CySNO leading to the release of NO. The CySNO decomposition rate can also be affected by buffers with different purity levels in the presence and absence of metal ion chelators-although all buffers show the same pH phenomenon of maximizing near physiological pH. An equilibrium model of metal ions as a function of pH provides a plausible explanation for the pH dependence on the experimental decomposition rate.

Fermentation of biomass-generated synthesis gas: effects of nitric oxide.

The production of renewable fuels, such as ethanol, has been steadily increasing owing to the need for a reduced dependency on fossil fuels. It was demonstrated previously that biomass-generated synthesis gas (biomass-syngas) can be converted to ethanol and acetic acid using a microbial catalyst. The biomass-syngas (primarily CO, CO(2), H(2), and N(2)) was generated in a fluidized-bed gasifier and used as a substrate for Clostridium carboxidivorans P7(T). Results showed that the cells stopped consuming H(2) when exposed to biomass-syngas, thus indicating that there was an inhibition of the hydrogenase enzyme due to some biomass-syngas contaminant. It was hypothesized that nitric oxide (NO) detected in the biomass-syngas could be the possible cause of this inhibition. The specific activity of hydrogenase was monitored with time under varying concentrations of H(2) and NO. Results indicated that NO (at gas concentrations above 40 ppm) was a non-competitive inhibitor of hydrogenase activity, although the loss of hydrogenase activity was reversible. In addition, NO also affected the cell growth and increased the amount of ethanol produced. A kinetic model of hydrogenase activity with inhibition by NO was demonstrated with results suggesting there are multiple binding sites of NO on the hydrogenase enzyme. Since other syngas-fermenting organisms utilize the same metabolic pathways, this study estimates that NO < 40 ppm can be tolerated by cells in a syngas-fermentation system without compromising the hydrogenase activity, cell growth, and product distribution.

Improved hemocompatibility of poly(ethylene terephthalate) modified with various thiol-containing groups.

Thiol groups were attached to polyethylene terephthalate (PET) to promote the transfer of a known platelet inhibitor, nitric oxide (NO), from nitrosated thiols naturally found in the body to PET, followed by the release of NO from PET to prevent platelet adhesion. In order to immobilize the most thiols on the modified polymer, the processing parameters used to attach the following three thiol containing groups were assessed: L-cysteine, 2-iminothiolane, and a cysteine polypeptide. When comparing the immobilized concentrations of thiol groups from each of the optimized processes the amount of immobilized thiol groups increased in order with the following groups: cysteine polypeptide <2-iminothiolane

Fermentation of biomass-generated producer gas to ethanol.

The development of low-cost, sustainable, and renewable energy sources has been a major focus since the 1970s. Fuel-grade ethanol is one energy source that has great potential for being generated from biomass. The demonstration of the fermentation of biomass-generated producer gas to ethanol is the major focus of this article in addition to assessing the effects of producer gas on the fermentation process. In this work, producer gas (primarily CO, CO(2), CH(4), H(2), and N(2)) was generated from switchgrass via gasification. The fluidized-bed gasifier generated gas with a composition of 56.8% N(2), 14.7% CO, 16.5% CO(2), 4.4% H(2), and 4.2% CH(4). The producer gas was utilized in a 4-L bioreactor to generate ethanol and other products via fermentation using a novel clostridial bacterium. The effects of biomass-generated producer gas on cell concentration, hydrogen uptake, and acid/alcohol production are shown in comparison with "clean" bottled gases of similar compositions for CO, CO(2), and H(2). The successful implementation of generating producer gas from biomass and then fermenting the producer gas to ethanol was demonstrated. Several key findings following the introduction of producer gas included: (1) the cells stopped growing but were still viable, (2) ethanol was primarily produced once the cells stopped growing (ethanol is nongrowth associated), (3) H(2) utilization stopped, and (4) cells began growing again if "clean" bottled gases were introduced following exposure to the producer gas.

Nitric oxide delivery in stagnant systems via nitric oxide donors: a mathematical model.

As a small biological molecule, nitric oxide (NO), plays a key role in diverse functions including smooth muscle cell regulation, neurotransmission, inhibition of platelet aggregation, and cytotoxic actions. The assessment of NO effects in biological systems has extensively been studied using NO donor compounds that often have differing NO release mechanisms and kinetic rates. Due to the differing kinetic rates and release mechanisms, in addition to reactions involving NO (such as autoxidation of NO), the NO concentrations to which biological systems are exposed may vary significantly depending upon the NO donor compound. Thus, quantifying the effects of NO using different NO donors is difficult unless the NO concentration profile in the experimental system is predicted or measured. In this study, the spatial and temporal NO concentration in a stagnant system (such as a culture plate or micro-well) is modeled following the addition of an NO donor characterized with first-order NO release kinetics. Two NO donors were utilized: diethylamine NONOate (DEA/NO) and spermine NONOate (SPER/NO). The use of a mathematical model can eliminate the need of complex in situ NO measurements and be useful for predicting the physical loss of NO from the experimental system. In addition, properly scaling the NO concentration can be useful in estimating the maximum NO concentration that will exist in solution. The results show that under widely used in vitro experimental conditions, including varying NO donor concentrations, cellular oxygen consumption rates, and aqueous phase heights, the spatial and temporal NO concentration range can vary significantly. In addition, hypoxic conditions can occur in the vicinity of cells, and in some situations, the physical loss of NO from the experimental system may be significant.

Free radical profiles in an encapsulated pancreatic cell matrix model.

The survival of encapsulated pancreatic cells or islets is often limited because of nutrient deficiency, fibrotic overgrowth, and immune attack. Activated immune cells, such as macrophages, release nitric oxide (NO) and superoxide (O2-). These species or their reactive intermediates, such as peroxynitrite, can be cytotoxic, mutagenic, and/or carcinogenic. The transport of these free radicals to encapsulated pancreatic cells cannot be impeded by the present immunoisolation technology. A model has been developed simulating free radical profiles within an encapsulation matrix due to macrophage immune cells attached to the surface of an encapsulation matrix. The model incorporates the transport and reactions of NO, O2- , O2, and total peroxynitrite (PER). The model predictions of NO, O2-, and PER concentrations to which pancreatic cells are potentially exposed are in the range of 8-42 microM, 0.5-8 nM, and 0.1-0.8 microM, respectively, for a 100-500 microm radius encapsulation matrix. The results demonstrate that the potential exists for free radical damage of encapsulated pancreatic cells and also demonstrates that additional exposure studies may be necessary for assessing free radical effects on pancreatic cell function. Also, care must be taken in assuming that encapsulated cell systems are completely protected from immunological action.

Improved haemocompatibility of cysteine-modified polymers via endogenous nitric oxide.

A novel method for improving the haemocompatibility of biomedical materials through endogenous nitric oxide (NO) is presented. L-cysteine was covalently immobilized onto two biomedical polymers: polyurethane (PU) and polyethylene terephthalate (PET). The L-cysteine content on the polymers was approximately 5-8 nmol/cm2 as quantified via a chemiluminescence-based assay. The haemocompatibility of the modified polymers was evaluated in terms of the number of adhered platelets when exposed to a platelet suspension labeled with Cr51. Platelet adherence on the L-cysteine-modified polymers was reduced more than 50% as compared to the control (glycine-modified polymers) when the platelet suspension contained plasma constituents. No difference in platelet adhesion was observed in the absence of plasma constituents. Further experiments demonstrated that NO was easily transferred to the L-cysteine-modified polymers from S-nitroso-albumin in PBS buffer. The NO was then released from the polymer. NO transfer or release was not observed for the control. The results suggest that L-cysteine-modified polymers are effective in reducing platelet adhesion via the transfer of NO from endogenous S-nitrosoproteins in plasma to the polymer followed by the subsequent release of NO. Thus, exploiting endogenous NO is a viable option for improving the haemocompatibility of biomaterials.