Plasma Urotensin II Act as a Diagnostic Biomarker for Acute Coronary Syndromes

Urotensin II (U-II), one of powerful vasoconstrictor peptides, is involved in the pathogenesis of hypertension, diabetes, myocardial infarction and heart failure. However, its role in patients with acute coronary syndromes (ACS) is still unknown. We performed the present study to measure plasma U-II level in patients with ACS and the healthy subjects in the Chinese Han population. Plasma U-II level in patients with unstable angina (UA 313 ± 286 pg/dl) and acute myocardial infarction (AMI 333 ± 269 pg/dl) was higher than in healthy controls (183 ± 154 pg/dl). Plasma U-II level is positively correlated with the Gensini score (r = 0.285, P = 0.003) and Apo B level (r = 0.239, P = 0.015). Moreover, the area under the receiver operating characteristic curve for the combination of CRP and U-II was significantly higher than it for CRP (P = 0.024). We conclude that U-II, which is elevated in ACS patients, may act as a clinical non-invasive biomarker for ACS diagnosis.     

Organization of the Human Mitochondrial Hydrogen Sulfide Oxidation Pathway

Sulfide oxidation is expected to play an important role in cellular switching between low steady-state intracellular hydrogen sulfide levels and the higher concentrations where the physiological effects are elicited. Yet despite its significance, fundamental questions regarding how the sulfide oxidation pathway is wired remain unanswered, and competing proposals exist that diverge at the very first step catalyzed by sulfide quinone oxidoreductase (SQR). We demonstrate that, in addition to sulfite, glutathione functions as a persulfide acceptor for human SQR and that rhodanese preferentially synthesizes rather than utilizes thiosulfate. The kinetic behavior of these enzymes provides compelling evidence for the flow of sulfide via SQR to glutathione persulfide, which is then partitioned to thiosulfate or sulfite. Kinetic simulations at physiologically relevant metabolite concentrations provide additional support for the organizational logic of the sulfide oxidation pathway in which glutathione persulfide is the first intermediate formed.     

Biomechanical and structural response of healing Achilles tendon to fatigue loading following acute injury

Achilles tendon injuries affect both athletes and the general population, and their incidence is rising. In particular, the Achilles tendon is subject to dynamic loading at or near failure loads during activity, and fatigue induced damage is likely a contributing factor to ultimate tendon failure. Unfortunately, little is known about how injured Achilles tendons respond mechanically and structurally to fatigue loading during healing. Knowledge of these properties remains critical to best evaluate tendon damage induction and the ability of the tendon to maintain mechanical properties with repeated loading. Thus, this study investigated the mechanical and structural changes in healing mouse Achilles tendons during fatigue loading. Twenty four mice received bilateral full thickness, partial width excisional injuries to their Achilles tendons (IACUC approved) and twelve tendons from six uninjured mice were used as controls. Tendons were fatigue loaded to assess mechanical and structural properties simultaneously after 0, 1, 3, and 6 weeks of healing using an integrated polarized light system. Results showed that the number of cycles to failure decreased dramatically (37-fold, p<0.005) due to injury, but increased throughout healing, ultimately recovering after 6 weeks. The tangent stiffness, hysteresis, and dynamic modulus did not improve with healing (p<0.005). Linear regression analysis was used to determine relationships between mechanical and structural properties. Of tendon structural properties, the apparent birefringence was able to best predict dynamic modulus (R²=0.88–0.92) throughout healing and fatigue life. This study reinforces the concept that fatigue loading is a sensitive metric to assess tendon healing and demonstrates potential structural metrics to predict mechanical properties.     

Closed loop identification of transfer function model for unstable bioreactors for tuning PID controllers

Closed loop identification of transfer function model for an unstable bioreactor is proposed based on an optimization method using either a step or a pulse response of PI/PID controlled bioreactor. A simple method is proposed for the initial guesses of the parameters of the first order plus time delay (FOPTD) transfer function model. A PID controller is designed for the identified model. Simulation study on the nonlinear model equations of an unstable bioreactor exhibiting multiple steady-states shows that the PID controller designed on the identified FOPTD model gives a good closed loop response similar to the one designed based on the linearized model from the nonlinear model equations.     

A New Klebsiella planticola Strain (Cd-1) Grows Anaerobically at High Cadmium Concentrations and Precipitates Cadmium Sulfide

Heavy metal resistance by bacteria is a topic of much importance to the bioremediation of contaminated soils and sediments. We report here the isolation of a highly cadmium-resistant Klebsiella planticola strain, Cd-1, from reducing salt marsh sediments. The strain grows in up to 15 mM CdCl₂ under a wide range of NaCl concentrations and at acidic or neutral pH. In growth medium amended with thiosulfate, it precipitated significant amounts of cadmium sulfide (CdS), as confirmed by x-absorption spectroscopy. In comparison with various other strains tested, Cd-1 is superior for precipitating CdS in cultures containing thiosulfate. Thus, our results suggest that Cd-1 is a good candidate for the accelerated bioremediation of systems contaminated by high levels of cadmium.     

Kinetics of ethanol production by immobilized cells of Zymomonas mobilis at varying d-glucose concentrations

Ethanol fermentation by cells of Zymomonas mobilis immobilized in calcium alginate gel has been studied using 5 to 30 wt% initial d-glucose in the medium. Up to 27% d-glucose was completely fermented and the maximum ethanol concentration of 12.6% (w/v) was obtained using an immobilized cell concentration of 58 g dry wt l^?1 of bead volume. The ethanol yield coefficient was almost unaffected by initial d-glucose concentration and its value was >95% of theoretical. The rates of ethanol production and d-glucose utilization first increased, with an increase in initial d-glucose concentration up to 13.6%, and then started to decrease upon a further increase in initial d-glucose concentration. Cell leakage from the calcium alginate beads was very low.     

Optimisation of culture conditions for production of eicosapentaenoic acid byMortierella elongate NRRL 5513

Summary WhenMortierella elongata NRRL 5513 was cultured in shake flasks at 25°C, mycelial growth reached a stationary phase at 48 h but maximum eicosapentaenoic acid (EPA) production was observed at 6 days. When incubated at 11°C, EPA production also continued to rise during the stationary phase of growth, reaching a maximum after 10 days. An initial culture pH of 6.1 was found to be optimum for EPA production. The effect of temperature on EPA production was dependent on medium constituents. In glucose and linseed oil supplemented media, optimum temperature for EPA production was 11 and 15°C respectively. A maximum EPA yield of 0.61 g/l was obtained in linseed oil (2%), yeast extract (0.5%) supplemented basal medium. Maximum EPA content as a percentage of lipids (15.12%) was observed when the latter medium was supplemented with 0.25% urea.     

Hydroxyapatite from Cuttlefish Bone: Isolation,Characterizations, and Applications

Hydroxyapatite (HA), a bioceramic, is a widely utilized material for bone tissue repair and regeneration because of its excellent properties such as biocompatibility, exceptional mechanical strength, and osteoconductivity. HA can be obtained by both synthetic and natural means. Animal bones are often considered a promising natural resource for the preparation of pure HA for biological and biomedical applications. Cuttlefish bone, also called as cuttlebone, mainly consists of calcium carbonate, and pure HA can be produced by adding phosphoric acid or ammonium hydrogen phosphate to it. Recently, cuttlefish bone-derived HA has shown promising results in terms of bone tissue repair and regeneration. The synthesized cuttlefish bone-derived has shown excellent biocompatibility, cell proliferation, increased alkaline phosphate activity, and efficient biomineralization ability with mesenchymal stem cells and osteoblastic cells. To further improve the biological properties of cuttlefish bone-derived HA, bioglass, polycaprolactone, and polyvinyl alcohol were added to it, which gave better results in terms of cell proliferation and osteogenic differentiation. Cuttlefish bone-derived HA with polymeric substances provides excellent bone formation under in vivo conditions. The studies indicate that cuttlefish bone-derived HA, along with polymeric and, protein materials, will be promising biomaterials in the field of bone tissue regeneration.     

Correction to: Escherichia coli persistence kinetics in dairy manure at moderate,mesophilic, and thermophilic temperatures under aerobic and anaerobic environments

Bioprocess and Biosystems Engineering - Escherichia coli persistence kinetics in dairy manure at moderate, mesophilic, and thermophilic temperatures.