Jorge Rodríguez

In central nervous system, acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) hydrolyse acetylcholine. Diminished cholinesterase activity is known to alter several mental and psychomotor functions. The symptoms of cholinergic crisis and those observed during acute attacks of acute intermittent porphyria are very similar. The aim of this study was to investigate if there could be a link between the action of some porphyrinogenic drugs on brain and the alteration of the cholinergic system. To this end, AChE and BuChE activities were assayed in whole and different brain areas. Muscarinic acetylcholine receptor (mAChR) levels were also measured. Results obtained indicate that the porphyrinogenic drugs tested affect central cholinergic transmission. Quantification of mAChR gave quite different levels depending on the xenobiotic. Veronal administration inhibited 50% BuChE activity in whole brain, cortex and hippocampus; concomitantly cortex mAChR was 30% reduced. Acute and chronic isoflurane anaesthesia diminished BuChE activity by 70-90% in whole brain instead cerebellum and hippocampus mAChR levels were only altered by chronic enflurane anaesthesia. Differential inhibition of cholinesterases in the brain regions and their consequent effects may be of importance to the knowledge of the mechanisms of neurotoxicity of porphyrinogenic drugs.

The Gram-positive cocci (GPC), Staphylococcus aureus, Streptococcus pneumoniae, Enterococcus faecalis and Enterococcus faecium, have become important causes of community and nosocomial-acquired infections. The prevalence of multiple resistant isolates to standard antimicrobial drugs has significantly increased over the past decades. Few prospective studies have been performed in Puerto Rico (PR) concerning the GPC antimicrobial susceptibilities pattern. The purpose of this study was to evaluate the in vitro susceptibility of GPC clinical isolates from PR to selected standard antibiotics and to the new antimicrobial agents, linezolid (LZ), quinupristin/dalfopristin (Q/D) and gemifloxacin (GM). The in vitro susceptibility utilizing disk diffusion and Etest methods to selected antibiotics was determined for a total of 429 isolates obtained during a period of 5 months from the Puerto Rico Medical Center Bacteriology Laboratory. The distribution of GPC collected was as follows: 213 S. aureus isolates, 162 E. faecalis, 16 E. faecium and 38 S. pneumoniae. The results of the susceptibility test demonstrated: 1) that in S. aureus, 100% of the isolates were susceptible to vancomycin (VAN), LZ and Q/D; 93% to GM; and 61% to methicillin/oxacillin; 2) in S. pneumoniae, 100% were susceptible to LN and GM; 87% to Q/D; and 53% to penicillin; 3) in E. faecalis, 99% were susceptible to ampicillin; 93% to LZ; 79% to GM; 78.6% to VAN; and 0% to Q/D. Sixty eight and 66% of the E. faecalis isolates were susceptible to gentamicin and streptomycin respectively; and 4) in E. faecium, 100% were susceptible to LZ; 94% to Q/D; 69% to GM; 37.5% to VAN and 20% to ampicillin. In E. faecium isolates, 50% and 31% were susceptible to gentamicin and streptomycin, respectively. Of the vancomycin resistant enterococci, 88.9% and 21% of E. faecium and faecalis showed VanA phenotypic resistance, respectively. These results show that there is a significant degree of antimicrobial resistance in GPC, including 38% methicillin resistance in S. aureus, a near 50% penicillin resistant S. pneumoniae, and a significant resistance of enterococcal species to VAN. The new agents, LZ, Q/D and GM, proved to be effective against both, S. aureus and S. pneumoniae. For E. faecium, both, LZ and Q/D were active, while for E. faecalis, only LZ showed consistent activity.

... Joan R. Hernandez Biological and Agricultural Engineering Department, TAMU, College Station, Texas 77843 Froilan L. Aquino ... Page 3. 2 Introduction Fossil fuel combustion in the United States generates more than 90% of its total greenhouse gas emissions. ...

1 A B S T R A C T Title: Ruminal anaerobic microorganism recovery using an experimental oro-ruminal probe Ruminal microbial ecosystem studies have traditionally required the use of canulado animals. The high cost of animal surgery and their maintenance has limited many labora- tories having easy access to rumen samples and exploring their microbial diversity. Methods like using oro-ruminal

... Removal concentration and desalination of bovine seroalbumin (BSA) with membrane technology SO Fem ndez, JA Rodriguez, A. P6rez Padilla* INTEQUI (CONICET ... [6] G. Mitra and K. Paul, in: WC McGregor, ed., Membrane Separations in Biotechology, Marcel Dekker, New ...

A new approach to optimization of processes described by fuzzy rules, in which the functional relationship between the decision variables and the objective function is not completely known, is introduced in this paper. It is based on stochastic algorithms and allows to determine optimal values of state variables and to optimize fuzzy rules (parameters of membership functions). Stochastic algorithms have

Mathematical modelling in environmental biotechnology has been a traditionally difficult resource to access for researchers and students without programming expertise. The great degree of flexibility required from model implementation platforms to be suitable for research applications restricts their use to programming expert users. More user friendly software packages however do not normally incorporate the necessary flexibility for most research applications. This work presents a methodology based on Excel and Matlab-Simulink for both flexible and accessible implementation of mathematical models by researchers with and without programming expertise. The models are almost fully defined in an Excel file in which the names and values of the state variables and parameters are easily created. This information is automatically processed in Matlab to create the model structure and almost immediate model simulation, after only a minimum Matlab code definition, is possible. The framework proposed also provides programming expert researchers with a highly flexible and modifiable platform on which to base more complex model implementations. The method takes advantage of structural generalities in most mathematical models of environmental bioprocesses while enabling the integration of advanced elements (e.g. heuristic functions, correlations). The methodology has already been successfully used in a number of research studies.

Anaerobic wastewater treatment is shifting from a philosophy of solely pollutants removal to a philosophy of combined resource recovery and waste treatment. Simultaneous wastewater treatment with energy recovery in the form of energy rich products, brings renewed interest to non-methanogenic anaerobic bioprocesses such as the anaerobic production of hydrogen, ethanol, solvents, VFAs, bioplastics and even electricity from microbial fuel cells. The existing kinetic-based modelling approaches, widely used in aerobic and methanogenic wastewater treatment processes, do not seem adequate in investigating such energy limited microbial ecosystems. The great diversity of similar microbial species, which share many of the fermentative reaction pathways, makes quantify microbial groups very difficult and causes identifiability problems. A modelling approach based on the consideration of metabolic reaction networks instead of on separated microbial groups is suggested as an alternative to describe anaerobic microbial ecosystems and in particular for the prediction of product formation as a function of environmental conditions imposed. The limited number of existing relevant fermentative pathways in conjunction with the fact that anaerobic reactions proceed very close to thermodynamic equilibrium reduces the complexity of such approach and the degrees of freedom in terms of product formation fluxes. In addition, energy limitation in these anaerobic microbial ecosystems makes plausible that selective forces associated with energy further define the system activity by favouring those conversions/microorganisms which provide the most energy for growth under the conditions imposed.

ABSTRACT The power recovery and COD removal efficiency, which depend on organic influent loading rate, have been studied in a high aspect ratio longitudinal tubular MFC reactor (liquid volume, 1 L). The power output from four anode/cathode pairs (modules) along the MFC's length was compared in two different modes of electrical connection (i.e. independently connected and connected in parallel to the loads). Independent connection to resistive loads for each of the four modules produced higher total maximum power generation than parallel connection (6% higher at 0.8 g l−1/d and 36% higher at 0.08 g l−1/d). The cumulative power production lengthwise along the reactor modules increased to 2.6 mW in the two higher OLRs tested (0.8 and 0.38 g l−1/d). However, at lower OLRs, the power tended to saturate at a lower level due to reduced organic concentrations in the later modules. Step perturbation of organic influent concentration from 960 to 22 mg sucrose l−1 resulted in a delayed voltage decrease, probably due to storage effects in the biofilm on the anode electrode. The power recovery and organic removal could be maximized by extending the number of modules in the longitudinal tubular reactor, which could control effluent quality and power yield, thus facilitating scale-up.

ABSTRACT The on-going research towards sustainable fuel production entails the improvement of the microbial catalysts involved. The possible reversibility of specific anaerobic catabolic reactions opens up a range of possibilities for the development of novel reductive bioprocesses. These reductive biohydrogenation pathways enable production of high energy density chemicals of interest as biofuels such as alcohols and long chain fatty acids. Anaerobic bioprocesses take place under energy scarcity conditions due to the absence of strong electron acceptors such as oxygen, and provide metabolic pathways towards these energy dense (reduced) chemicals. Metabolic reactions take place very close to thermodynamic equilibrium with minimum energy dissipation and consequently, environmental changes in product and substrate concentrations can easily reverse the driving force of the chemical reaction catalysed. The objective of this work is to investigate the potential reversibility of specific anaerobic pathways of interest. The thermodynamics of the different steps in biochemical pathways are analysed and combined with assumptions concerning kinetic and physiological constraints to evaluate if pathways are potentially reversible by imposing changes in process conditions. The results suggest that (i) in homoacetogenesis they may operate in both reductive and oxidative directions depending on the hydrogen partial pressure in the system, (ii) acetate reduction to butyrate with hydrogen is not feasible, but no biochemical bottlenecks are apparent in butyrate production from acetate with ethanol or lactate as electron donors, (iii) the reduction of short chain to longer chain fatty acids with ethanol as the electron donor appears thermodynamically and kinetically feasible, and (iv) alcohol production from the corresponding fatty acids (e.g. ethanol from acetate) was found to require proton translocations at specific sites in the biochemical pathways in order to compensate for the ATP required for phosphatation of acetate and to enable energy harvesting. Overall, the methodology proposed here allows for analysing the potential reversibility of catabolic pathways and therewith contributes to the development of efficient and reliable anaerobic bioprocesses for the production of biofuels and chemicals.

We study the coordination of excess NaCl to zwitterionic DPPC lipid bilayers using molecular dynamics simulations. We find that Na ions directly coordinate with the DPPC lipid carbonyl groups. As the number of excess ions increases, the number of coordinated ions increases, until it reaches a plateau at a ratio near 1 ion per every four lipids at 310 K, and 1 ion per every six lipids at 323 K. The area per lipid decreases as the number of excess ions is increased. For low number of ions per lipids (1:16 and 1:8), most Na ions are bound to the lipid carbonyls, while the Cl form an ionic cloud around the lipid choline groups. As a result of the Na binding, the lipid has an effective positive charge density. The residence time of Na ions bound to the lipid is longer than 40 ns, while Cl ions exchange faster than the nanoseconds timescale. We find that the bound Na ions replace ordered water around the carbonyls. The net linear charge density near the carbonyl groups stays positive, regardless of the presence of excess salt in the solution.

Four different 5-nitroindazole derivatives (1–4) and its inclusion with Heptakis(2,6-di-O-methyl)-β-cyclodextrin (DMβCD) were investigated. The stoichiometric ratios and stability constants describing the extent of formation of the complexes were determined by phase-solubility measurements obtaining in all cases a type-AL diagram. Also electrochemical studies were carried out, where the observed change in the EPC value indicated a lower feasibility of the nitro group reduction. The same behavior was observed in the ESR studies. The detailed spatial configuration is proposed based on 2D NMR methods. These results are further interpreted using molecular modeling studies. The latter results are in good agreement with the experimental data.

Energy recovery while treating low organic loads has been investigated using longitudinal tubular microbial fuel cell (MFC) reactors. Duplicate reactors, each consisting of two modules, were operated with influent sucrose organic loading rates (OLRs) between 0.04 and 0.42 g COD/l/d. Most soluble COD (sCOD) removal occurred in the first modules with predominantly VFAs reaching the second modules. Coulombic efficiency (CE) in the second modules ranged from 9% to 92% which was 3-4 times higher than the first modules. The maximum energy production was 1.75 W h/g COD in the second modules at OLR 0.24 g/l/d, up to 10 times higher than the first modules, attributable to non-fermentable substrate. A simple plug flow model of the reactors, including a generic non-electrogenic reaction competing for acetate, was developed. This modular tubular design can reproducibly distribute bioprocesses between successive modules and could be scalable, acting as a polishing stage while reducing energy requirements in wastewater treatment.

A fuzzy-logic-based diagnosis system for the determination of acidification states on an anaerobic wastewater treatment plant was developed. The diagnosis system uses experts’ knowledge to determine the acidification state of the process. The information of several on-line measured variables, which are classified under linguistic labels, and the expert knowledge are implemented by means of a fuzzy-based rules structure. The acidification state of the system within the anaerobic reactor is determined by means of evaluating the fuzzy inference system for the given inputs. A representative experiment of application of the developed diagnosis system to a progressive acidification caused by a hydraulic overload in the digester is presented and discussed.