Ionic liquids and deep eutectic solvents for the stabilization of biopharmaceuticals: A review.

Biopharmaceuticals have allowed the control of previously untreatable diseases. However, their low solubility and stability still hinder their application, transport, and storage. Hence, researchers have applied different compounds to preserve and enhance the delivery of biopharmaceuticals, such as ionic liquids (ILs) and deep eutectic solvents (DESs). Although the biopharmaceutical industry can employ various substances for enhancing formulations, their effect will change depending on the properties of the target biomolecule and environmental conditions. Hence, this review organized the current state-of-the-art on the application of ILs and DESs to stabilize biopharmaceuticals, considering the properties of the biomolecules, ILs, and DESs classes, concentration range, types of stability, and effect. We also provided a critical discussion regarding the potential utilization of ILs and DESs in pharmaceutical formulations, considering the restrictions in this field, as well as the advantages and drawbacks of these substances for medical applications. Overall, the most applied IL and DES classes for stabilizing biopharmaceuticals were cholinium-, imidazolium-, and ammonium-based, with cholinium ILs also employed to improve their delivery. Interestingly, dilute and concentrated ILs and DESs solutions presented similar results regarding the stabilization of biopharmaceuticals. With additional investigation, ILs and DESs have the potential to overcome current challenges in biopharmaceutical formulation.

Enabling Sustainable Chemistry with Ionic Liquids and Deep Eutectic Solvents: A Fad or the Future?

Ionic liquids (ILs) and deep eutectic solvents (DESs) debuted with a promise of a superior sustainability footprint due to their low vapor pressure. However, their toxicity and high cost compromise this footprint, impeding their real-world applications. Fortunately, their property tunability through a rational selection of precursors, including bioderived ones, provides a strategy to ameliorate toxicity, lower cost, and endow new functions. This Review discusses whether ILs and DESs are sustainable solvents and how they contribute to sustainable chemical processes.

Microbial lipase: a new approach for a heterogeneous biocatalyst.

Lipases are enzymes employed in several industrial process and their applicability can be increased if these biocatalysts are in the immobilize form. The objective of this work was to study the immobilization of lipase produced by submerged cultivation of Aspergillus sp. by hydrophobic interaction, evaluating its stability and reuse capacity. The immobilization process on octyl-sepharose (C8) and octadecyl-sepabeads (C18) carriers was possible after the removal of oil excess presented in the fermented broth. The results showed that the enzyme was isolated and concentrated in octyl-sepharose with 22% of the initial activity. To increase the amount of enzyme adsorbed on the carrier, 4 immobilization cycles were performed in a row, on the same carrier, with a final immobilization yield of 151.32% and an increase in the specific activity of 136%. The activity test with immobilized lipase showed that the immobilized enzyme maintained 75% of the initial activity after 20 cycles.

Screening of wild type Streptomyces isolates able to overproduce clavulanic acid.

The selection of new microorganisms able to produce antimicrobial compounds is hoped for to reduce their production costs and the side effects caused by synthetic drugs. Clavulanic acid is a ß-lactam antibiotic produced by submerged culture, which is widely used in medicine as a powerful inhibitor of ß-lactamases, enzymes produced by bacteria resistant to antibiotics such penicillin and cephalosporin. The purpose of this work was to select the best clavulanic acid producer among strains of Streptomyces belonging to the Microorganism Collection of the Department of Antibiotics of the Federal University of Pernambuco (DAUFPE). Initially, the strains were studied for their capacity to inhibit the action of ß-lactamases produced by Klebsiella aerogenes ATCC 15380. From these results, five strains were selected to investigate the batch kinetics of growth and clavulanic acid production in submerged culture carried out in flasks. The results were compared with the ones obtained by Streptomyces clavuligerus ATCC 27064 selected as a control strain. The best clavulanic acid producer was Streptomyces DAUFPE 3060, molecularly identified as Streptomyces variabilis, which increased the clavulanic acid production by 28% compared to the control strain. This work contributes to the enlargement of knowledge on new Streptomyces wild strains able to produce clavulanic acid by submerged culture.

Screening of wild type Streptomyces isolates able to overproduce clavulanic acid

The selection of new microorganisms able to produce antimicrobial compounds is hoped for to reduce their production costs and the side effects caused by synthetic drugs. Clavulanic acid is a β-lactam antibiotic produced by submerged culture, which is widely used in medicine as a powerful inhibitor of β-lactamases, enzymes produced by bacteria resistant to antibiotics such penicillin and cephalosporin. The purpose of this work was to select the best clavulanic acid producer among strains of Streptomyces belonging to the Microorganism Collection of the Department of Antibiotics of the Federal University of Pernambuco (DAUFPE). Initially, the strains were studied for their capacity to inhibit the action of β-lactamases produced by Klebsiella aerogenes ATCC 15380. From these results, five strains were selected to investigate the batch kinetics of growth and clavulanic acid production in submerged culture carried out in flasks. The results were compared with the ones obtained by Streptomyces clavuligerus ATCC 27064 selected as a control strain. The best clavulanic acid producer was Streptomyces DAUFPE 3060, molecularly identified as Streptomyces variabilis, which increased the clavulanic acid production by 28% compared to the control strain. This work contributes to the enlargement of knowledge on new Streptomyces wild strains able to produce clavulanic acid by submerged culture.

LPS-protein aggregation influences protein partitioning in aqueous two-phase micellar systems.

Lipopolysaccharide endotoxins (LPS) are the most common pyrogenic substances in recombinant peptides and proteins purified from Gram-negative bacteria, such as Escherichia coli. In this respect, aqueous two-phase micellar systems (ATPMS) have already proven to be a good strategy to purify recombinant proteins of pharmaceutical interest and remove high LPS concentrations. In this paper, we review our recent experimental work in protein partitioning in Triton X-114 ATPMS altogether with some new results and show that LPS-protein aggregation can influence both protein and LPS partitioning. Green fluorescent protein (GFPuv) was employed as a model protein. The ATPMS technology proved to be effective for high loads of LPS removal into the micelle-rich phase (%REM(LPS) > 98 %) while GFPuv partitioned preferentially to the micelle-poor phase (K GFP(uv) < 1.00) due to the excluded-volume interactions. However, theoretically predicted protein partition coefficient values were compared with experimentally obtained ones, and good agreement was found only in the absence of LPS. Dynamic light scattering measurements showed that protein-LPS interactions were taking place and influenced the partitioning process. We believe that this phenomenon should be considered in LPS removal employing any kind of aqueous two-phase system. Nonetheless, ATPMS can still be considered as an efficient strategy for high loads of LPS removal, but being aware that the excluded-volume partitioning theory available might overestimate partition coefficient values due to the presence of protein-LPS aggregation.

Produção e extração de colorantes naturais de Penicillium purpurogenum DPUA 1275 / Production and extraction of natural colorants from Penicillium purpurogenum DPUA 1275

Há interesse mundial no desenvolvimento de pesquisas envolvendo produção e extração de colorantes naturais, devido a sérios problemas de segurança industrial associados ao uso de colorantes sintéticos. Este trabalho objetivou produzir colorantes naturais de Penicillium purpurogenum DPUA 1275 por cultivo submerso (em frascos agitados e em biorreator) e estudar a extração dos colorantes vermelhos. Para a produção, os estudos iniciais mostraram que 5 discos de micélio, sacarose e extrato de levedura como fontes de carbono e nitrogênio, respectivamente, e 336 horas de cultivo eram condições adequadas para a produção dos colorantes. Visando à otimização da produção, realizaram-se planejamentos fatoriais, com as variáveis independentes: tempo de cultivo; velocidade de agitação; pH; temperatura; concentração de sacarose e de extrato de levedura. As variáveis-respostas foram produção de colorantes amarelos, laranjas e vermelhos. Dos resultados obtidos, as variáveis mais significativas ao processo foram concentrações de extrato de levedura e de sacarose. A produção dos colorantes vermelhos foi otimizada, alcançando a produção de 2,97 UA490nm, nas condições 48,90 e 11,80 g/L de sacarose e extrato de levedura, respectivamente, 30°C, pH 4,5 150 rpm e 336 horas de cultivo. Nos experimentos em biorreator, o melhor resultado foi obtido na frequência de agitação de 500 rpm e na mudança do pH do meio para 8,0, após 96 horas de bioprocesso. Ademais, avaliou-se a estabilidade dos colorantes vermelhos presentes no meio fermentado em diferentes condições (pH, temperatura, sais, polímeros e tensoativos). Referente a pH e temperatura, os colorantes vermelhos mostraram-se mais estáveis nas condições alcalinas e a 70 °C. Tanto os sais (NaCl e Na2SO4) quanto os polímeros (PEG 1.000, 6.000 e 10.000 g/mol e NaPA 8.000 g/mol a 5 e 15%) e os tensoativos (Tween 20, CTAB e SDS) não causaram perda da cor nas condições avaliadas. Estudos de solubilidade e de coeficiente de partição octanol-água mostraram que os colorantes vermelhos apresentam solubilidade superior em solventes polares e característica mais hidrofílica. Nos estudos de extração, as técnicas avaliadas foram Sistemas Poliméricos de Duas Fases Aquosas (SPDFA) formados pelo sistema PEG/NaPA e Colloidal Gas Aphrons (CGA). Pela primeira técnica, os colorantes vermelhos migraram preferencialmente para a fase PEG. Os polímeros PEG 6.000 g/mol, na presença de NaCl 0,1 e 0,5 M, e PEG 10.000 g/mol, com Na2SO4 0,5M, se destacaram dentre as condições analisadas com coeficiente de partição (K) próximo a 13, em ambos os casos, e seletividade de proteínas (SeP) próximas a 3. Para a técnica de CGA, o CTAB proporcionou os melhores resultados, seguido do Tween 20. Porém, o valor de K foi inferior ao obtido com SPDFA, com um máximo de 5 (CTAB 2 mM/pH 9,0). Os resultados obtidos demonstram um novo produtor de colorantes naturais, as quais têm potencial de aplicação em diversos segmentos industriais. Ademais, os resultados obtidos mostraram a eficiência das técnicas utilizadas para extração dos colorantes vermelhos, com destaque para SPDFA, que apresentou maiores valores de K

There is worldwide interest in developing research projects involving the production and extraction of natural colorants due to serious safety problems associated with industrial use of synthetic ones. The aim of this work was to investigate the production of natural colorants from Penicillium purpurogenum DPUA 1275 by submerged culture (rotatory shaker and bioreactor) besides studying the red colorants extraction. To the production step, initial studies showed that 5 agar mycelial discs, sucrose and yeast extract as carbon and nitrogen sources, respectively, and 336 hours of bioprocess promoted the best results. To optimize the colorants production a serie of factorial designs were performed. The independent variables studied were: fermentation time, agitation speed, pH, temperature, sucrose and yeast extract concentration under the responses production of yellow, orange and red colorants. From these results, the most significant variables for the process were sucrose and yeast extract concentration. The red colorants production was optimized achieving 2.97 UA490nm, in the following conditions: 48.90 and 11.80 g/L of sucrose and yeast extract, respectively, 30 °C, 4.5 pH, 150 rev min-1 and 336 hours of culture. In the experiments performed in bioreactor, the condition that promoted the best results was 500 rpm and pH adjusted for 8.0 after 96 hours of bioprocess. Furthermore, we evaluated the red colorants stability at different conditions (pH, temperature, salts, polymers and surfactants). Concerning to pH and temperature, the red colorants were more stable under basic conditions and 70 °C; not only the salts (NaCl and Na2SO4) but also the polymers (PEG 1000, 6000 and 10000 g/mol and NaPA 8000 g/mol) and the surfactants (Tween 20, CTAB and SDS) not promoted loss of color upon the conditions evaluated. Studies of red colorants solubility and octanol water coefficient showed that these compounds exhibit a higher solubility in polar solvents and present hydrophilic characteristics. Subsequently, the extraction of red colorant was evaluated through two extraction methods: Polymeric Systems Aqueous Two Phase (ATPS) composed by PEG and NaPA and Colloidal Gas Aphrons (CGA). For the first technique, the red colorant preferentially migrated to the PEG phase. The best results were obtained with PEG 6000 g/mol in the presence of 0.1 to 0.5 M NaCl and with PEG 10000 g/mol with 0.5 M Na2SO4. To both cases the partition coefficient (K) was close to 13 and the Selectivity in terms of proteins (SeP) was close to 3. For the CGA technique, CTAB gave the best results followed by Tween 20. However, the K values were lower than the ones obtained with ATPS with a maximum of 5 in the following condition: CTAB 2 mM/pH 9.0. For the SeP, the values obtained for both techniques were close. The results above show a new producer of natural colorants which have potential application in various industries. Moreover, the results show the efficiency of the techniques used to extract the red colorants, especially to ATPS that presented higher K values