Your search keyword '"Cephalexin chemical synthesis"' showing total 6 results

1. Penicillin acylase-catalyzed synthesis of beta-lactam antibiotics in highly condensed aqueous systems: beneficial impact of kinetic substrate supersaturation.

Author

Youshko MI, Moody HM, Bukhanov AL, Boosten WH, and Svedas VK

Subjects

Amoxicillin chemical synthesis, Ampicillin chemical synthesis, Catalysis, Cephalexin chemical synthesis, Cephalosporins chemistry, Enzyme Activation, Kinetics, Penicillanic Acid chemistry, Solutions, Substrate Specificity, Anti-Bacterial Agents chemical synthesis, Escherichia coli enzymology, Penicillanic Acid analogs & derivatives, Penicillin Amidase chemistry, Water chemistry, beta-Lactams chemical synthesis

Abstract

Advantages of performing penicillin acylase-catalyzed synthesis of new penicillins and cephalosporins by enzymatic acyl transfer to the beta-lactam antibiotic nuclei in the supersaturated solutions of substrates have been demonstrated. It has been shown that the effective nucleophile reactivity of 6-aminopenicillanic (6-APA) and 7-aminodesacetoxycephalosporanic (7-ADCA) acids in their supersaturated solutions continue to grow proportionally to the nucleophile concentration. As a result, synthesis/hydrolysis ratio in the enzymatic synthesis can be significantly (up to three times) increased due to the nucleophile supersaturation. In the antibiotic nuclei conversion to the target antibiotic the remarkable improvement (up to 14%) has been gained. Methods of obtaining relatively stable supersaturated solutions of 6-APA, 7-ADCA, and D-p-hydroxyphenylglycine amide (D-HPGA) have been developed and syntheses of ampicillin, amoxicillin, and cephalexin starting from the supersaturated homogeneous solutions of substrates were performed. Higher synthetic efficiency and increased productivity of these reactions compared to the heterogeneous "aqueous solution-precipitate" systems were observed. The suggested approach seems to be an effective solution for the aqueous synthesis of the most widely requested beta-lactam antibiotics (i.e., amoxicillin, cephalexin, cephadroxil, cephaclor, etc.)., (Copyright 2004 Wiley Periodicals, Inc.)

Published

2004

2. Integrated reactor concepts for the enzymatic kinetic synthesis of cephalexin.

Author

Schroën CG, Nierstrasz VA, Bosma R, Kroon PJ, Tjeerdsma PS, DeVroom E, VanderLaan JM, Moody HM, Beeftink HH, Janssen AE, and Tramper J

Subjects

Adsorption, Chelating Agents chemistry, Enzymes, Immobilized, Escherichia coli metabolism, Hydrogen-Ion Concentration, Hydrolysis, Naphthols chemistry, Penicillin Amidase biosynthesis, Polystyrenes, Quality Control, Resins, Synthetic, Sensitivity and Specificity, Cephalexin chemical synthesis, Cephalosporins chemistry, Combinatorial Chemistry Techniques methods, Multienzyme Complexes chemistry, Penicillin Amidase chemistry

Abstract

Integrated process concepts for enzymatic cephalexin synthesis were investigated by our group, and this article focuses on the integration of reactions and product removal during the reactions. The last step in cephalexin production is the enzymatic kinetic coupling of activated phenylglycine (phenylglycine amide or phenylglycine methyl ester) and 7-aminodeacetoxycephalosporanic acid (7-ADCA). The traditional production of 7-ADCA takes place via a chemical ring expansion step and an enzymatic hydrolysis step starting from penicillin G. However, 7-ADCA can also be produced by the enzymatic hydrolysis of adipyl-7-ADCA. In this work, this reaction was combined with the enzymatic synthesis reaction and performed simultaneously (i.e., one-pot synthesis). Furthermore, in situ product removal by adsorption and complexation were investigated as means of preventing enzymatic hydrolysis of cephalexin. We found that adipyl-7-ADCA hydrolysis and cephalexin synthesis could be performed simultaneously. The maximum yield on conversion (reaction) of the combined process was very similar to the yield of the separate processes performed under the same reaction conditions with the enzyme concentrations adjusted correctly. This implied that the number of reaction steps in the cephalexin process could be reduced significantly. The removal of cephalexin by adsorption was not specific enough to be applied in situ. The adsorbents also bound the substrates and therewith caused lower yields. Complexation with beta-naphthol proved to be an effective removal technique; however, it also showed a drawback in that the activity of the cephalexin-synthesizing enzyme was influenced negatively. Complexation with beta-naphthol rendered a 50% higher cephalexin yield and considerably less byproduct formation (reduction of 40%) as compared to cephalexin synthesis only. If adipyl-7-ADCA hydrolysis and cephalexin synthesis were performed simultaneously and in combination with complexation with beta-naphthol, higher cephalexin concentrations also were found. In conclusion, a highly integrated process (two reactions simultaneously combined with in situ product removal) was shown possible, although further optimization is necessary., (Copyright 2002 Wiley Periodicals, Inc.)

Published

2002

3. A two-step, one-pot enzymatic synthesis of cephalexin from D-phenylglycine nitrile.

Author

Wegman MA, van Langen LM, van Rantwijk F, and Sheldon RA

Subjects

Catalysis, Cephalexin isolation & purification, Cephalosporins chemistry, Escherichia coli enzymology, Glycine analogs & derivatives, Models, Chemical, Quality Control, Rhodococcus enzymology, Sensitivity and Specificity, Acetonitriles chemistry, Cephalexin chemical synthesis, Glycine chemistry, Hydro-Lyases chemistry, Multienzyme Complexes, Penicillin Amidase chemistry

Abstract

A cascade of two enzymatic transformations is employed in a one-pot synthesis of cephalexin. The nitrile hydratase (from R. rhodochrous MAWE)-catalyzed hydration of D-phenylglycine nitrile to the corresponding amide was combined with the penicillin G acylase (penicillin amidohydrolase, E.C. 3.5.1.11)-catalyzed acylation of 7-ADCA with the in situ-formed amide to afford a two-step, one-pot synthesis of cephalexin. D-Phenylglycine nitrile appeared to have a remarkable selective inhibitory effect on the penicillin G acylase, resulting in a threefold increase in the synthesis/hydrolysis (S/H) ratio. 1,5-Dihydroxynaphthalene, when added to the reaction mixture, cocrystallized with cephalexin. The resulting low cephalexin concentration prevented its chemical as well as enzymatic degradation; cephalexin was obtained at 79% yield with an S/H ratio of 7.7., (Copyright 2002 Wiley Periodicals, Inc.)

Published

2002

4. Advantages of using non-isothermal bioreactors for the enzymatic synthesis of antibiotics: the penicillin G acylase as enzyme model.

Author

Travascio P, Zito E, De Maio A, Schroën CG, Durante D, De Luca P, Bencivenga U, and Mita DG

Subjects

Catalysis, Cephalosporins chemistry, Coated Materials, Biocompatible, Enzymes, Immobilized, Equipment Design, Escherichia coli enzymology, Hydrogen-Ion Concentration, Hydrophobic and Hydrophilic Interactions, Methacrylates, Models, Chemical, Propylene Glycols chemistry, Sensitivity and Specificity, Temperature, Anti-Bacterial Agents chemical synthesis, Bioreactors, Cephalexin chemical synthesis, Membranes, Artificial, Nylons, Penicillin Amidase chemistry

Abstract

A new hydrophobic and catalytic membrane was prepared by immobilizing Penicillin G acylase (PGA, EC.3.5.1.11) from E. coli on a nylon membrane, chemically grafted with butylmethacrylate (BMA). Hexamethylenediamine (HMDA) and glutaraldehyde (Glu) were used as a spacer and coupling agent, respectively. PGA was used for the enzymatic synthesis of cephalexin, using D(-)-phenylglycine methyl ester (PGME) and 7-amino-3-deacetoxycephalosporanic acid (7-ADCA) as substrates. Several factors affecting this reaction, such as pH, temperature, and concentrations of substrates were investigated. The results indicated good enzyme-binding efficiency of the pre-treated membrane, and an increased stability of the immobilized PGA towards pH and temperature. Calculation of the activation energies showed that cephalexin production by the immobilized biocatalyst was limited by diffusion, resulting in a decrease of enzyme activity and substrate affinity. Temperature gradients were employed as a way to reduce the effects of diffusion limitation. Cephalexin was found to linearly increase with the applied temperature gradient. A temperature difference of about 3 degrees C across the catalytic membrane resulted into a cephalexin synthesis increase of 100% with a 50% reduction of the production times. The advantage of using non-isothermal bioreactors in biotechnological processes, including pharmaceutical applications, is also discussed., (Copyright 2002 Wiley Periodicals, Inc.)

Published

2002

5. Modeling of the enzymatic kinetic synthesis of cephalexin--influence of substrate concentration and temperature.

Author

Schroën CG, Nierstrasz VA, Moody HM, Hoogschagen MJ, Kroon PJ, Bosma R, Beeftink HH, Janssen AE, and Tramper J

Subjects

Cephalexin chemistry, Cephalosporins chemistry, Kinetics, Substrate Specificity, Temperature, Cephalexin chemical synthesis, Cephalosporins chemical synthesis, Enzymes chemistry, Models, Chemical

Abstract

During enzymatic kinetic synthesis of cephalexin, an activated phenylglycine derivative (phenylglycine amide or phenylglycine methyl ester) is coupled to the nucleus 7-aminodeacetoxycephalosporanic acid (7-ADCA). Simultaneously, hydrolysis of phenylglycine amide and hydrolysis of cephalexin take place. This results in a temporary high-product concentration that is subsequently consumed by the enzyme. To optimize productivity, it is necessary to develop models that predict the course of the reaction. Such models are known from literature but these are only applicable for a limited range of experimental conditions. In this article a model is presented that is valid for a wide range of substrate concentrations (0-490 mM for phenylglycine amide and 0-300 mM for 7-ADCA) and temperatures (273-298 K). The model was built in a systematic way with parameters that were, for an important part, calculated from independent experiments. With the constants used in the model not only the synthesis reaction but also phenylglycine amide hydrolysis and cephalexin hydrolysis could be described accurately. In contrast to the models described in literature, only a limited number (five) of constants was required to describe the reaction at a certain temperature. For the temperature dependency of the constants, the Arrhenius equation was applied, with the constants at 293 K as references. Again, independent experiments were used, which resulted in a model with high statistic reliability for the entire temperature range. Low temperatures were found beneficial for the process because more cephalexin and less phenylglycine is formed. The model was used to optimize the reaction conditions using criteria such as the yield on 7-ADCA or on activated phenylglycine. Depending on the weight of the criteria, either a high initial phenylglycine amide concentration (yield on 7-ADCA) or a high initial 7-ADCA concentration (yield on phenylglycine amide) is beneficial., (Copyright 2001 John Wiley & Sons, Inc.)

Published

2001

6. Use of aqueous two-phase systems for in situ extraction of water soluble antibiotics during their synthesis by enzymes immobilized on porous supports.

Author

Hernandez-Justiz O, Fernandez-Lafuente R, Terreni M, and Guisan JM

Subjects

Anti-Bacterial Agents isolation & purification, Biotechnology methods, Catalysis, Cephalosporins isolation & purification, Escherichia coli enzymology, Indicators and Reagents, Kinetics, Solubility, Water, Anti-Bacterial Agents biosynthesis, Cephalexin chemical synthesis, Cephalexin isolation & purification, Cephalosporins chemical synthesis, Enzymes, Immobilized, Penicillin Amidase metabolism

Abstract

Yields of kinetically controlled synthesis of antibiotics catalyzed by penicillin G acylase from Escherichia coli (PGA) have been greatly increased by continuous extraction of water soluble products (cephalexin) away from the surroundings of the enzyme. In this way its very rapid enzymatic hydrolysis has been avoided. Enzymes covalently immobilized inside porous supports acting in aqueous two-phase systems have been used to achieve such improvements of synthetic yields. Before the reaction is started, the porous structure of the biocatalyst can be washed and filled with one selected phase. In this way, when the pre-equilibrated biocatalyst is mixed with the second phase (where the reaction product will be extracted), the immobilized enzyme remains in the first selected phase in spite of its possibly different natural trend. Partition coefficients (K) of cephalexin in very different aqueous two-phase systems were firstly evaluated. High K values were obtained under drastic conditions. The best K value for cephalexin (23) was found in 100% PEG 600-3 M ammonium sulfate where cephalexin was extracted to the PEG phase. Pre-incubation of immobilized PGA derivatives in ammonium sulfate and further suspension with 100% PEG 600 allowed us to obtain a 90% synthetic yield of cephalexin from 150 mM phenylglycine methyl ester and 100 mM 7-amino desacetoxicephalosporanic acid (7-ADCA). In this reaction system, the immobilized enzyme remains in the ammonium sulfate phase and hydrolysis of the antibiotic becomes suppressed because of its continuous extraction to the PEG phase. On the contrary, synthetic yields of a similar process carried out in monophasic systems were much lower (55%) because of a rapid enzymatic hydrolysis of cephalexin., (Copyright 1998 John Wiley & Sons, Inc.)

Published

1998