Federico Ruiz‐Ruiz scite author profile

BACKGROUND Bacteriophage M13 is an Escherichia coli‐specific non‐lytic filamentous virus commonly used in applications ranging from antibody screening and nanomaterial construction to drug delivery, among others. In this tenor, alternative methods for the fractionation, recovery and partial purification of phage particles are desired. In this work, the use of aqueous two‐phase systems (ATPS) was evaluated as an alternative method for the recovery of phage particles. RESULTS The partition behavior of M13 in PEG–salt and ionic liquid (IL)–salt ATPS was characterized using a pre‐purified feedstock. In PEG‐salt ATPS, M13 was preferentially partitioned to the interface. In IL ATPS, however, M13 showed a high‐top phase preference with recovery yields above 65%. Selected systems were tested for the extraction of M13 from a crude fermentation broth. From crude broth, a PEG 400‐potassium phosphate system with volume ratio (VR) of 1 and 25% w/w tie line length (TLL) gave the best M13 top phase recovery (83%) and purification fold (18.2) in terms of total protein concentration. CONCLUSIONS The results presented here demonstrate the practical application of ATPS as an efficient process for the primary recovery and partial purification of M13 and represent the first study of the extraction of viral particles directly from a crude broth as well as the use of IL‐Salt ATPS. © 2017 Society of Chemical Industry

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Marine-Derived Bioactive Peptides for Biomedical Sectors: A Review

Ruiz‐Ruiz¹,

Mancera-Andrade²,

Iqbal

2017

PPL

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Marine-based resources such as algae and other marine by-products have been recognized as rich sources of structurally diverse bioactive peptides. Evidently, their structural characteristics including unique amino acid residues are responsible for their biological activity. Several of the above-mentioned marine-origin species show multi-functional bioactivities that are useful for a new discovery and/or reinvention of biologically active ingredients, nutraceuticals and/or pharmaceuticals. Therefore, in recent years, marine-derived bioactive peptides have gained a considerable attention with high-value biomedical and/or pharmaceutical potentials. Furthermore, a wider spectrum of bioactive peptides can be produced through proteolytic-assisted hydrolysis of various marine resources under controlled physicochemical (pH and temperature of the reaction media) environment. Owing to their numerous health-related beneficial effects and therapeutic potential in the treatment and/or prevention of many diseases, such marine-derived bioactive peptides exhibit a wider spectrum of biological activities such as anti-cancerous, anti-proliferative, anti-coagulant, antibacterial, antifungal, and anti-tumor activities among many others. Based on emerging evidence of marine-derived peptide mining, the above-mentioned marine resources contain noteworthy levels of high-value protein. The present review article mainly summarizes the marine-derived bioactive peptides and emphasizing their potential applications in biomedical and/or pharmaceutical sectors of the modern world. In conclusion, recent literature has provided evidence that marine-derived bioactive peptides play a critical role in human health along with many possibilities of designing new functional nutraceuticals and/or pharmaceuticals to clarify potent mechanisms of action for a wider spectrum of diseases.

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Economic analysis of pilot‐scale production of B‐phycoerythrin

Torres‐Acosta

Ruiz‐Ruiz

Aguilar‐Yáñez

et al. 2016

Biotechnology Progress

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β-Phycoerythrin is a color protein with several applications, from food coloring to molecular labeling. Depending on the application, different purity is required, affecting production cost and price. Different production and purification strategies for B-phycoerythrin have been developed, the most studied are based on the production using Porphyridium cruentum and purified using chromatographic techniques or aqueous two-phase systems. The use of the latter can result in a less expensive and intensive recovery of the protein, but there is lack of a proper economic analysis to study the effect of using aqueous two-phase systems in a scaled-up process. This study analyzed the production of B-Phycoerythrin using real data obtained during the scale-up of a bioprocess using specialized software (BioSolve, Biopharm Services, UK). First, a sensitivity analysis was performed to identify critical parameters for the production cost, then a Monte Carlo analysis to emulate real processes by adding uncertainty to the identified parameters. Next, the bioprocess was analyzed to determine its financial attractiveness and possible optimization strategies were tested and discussed. Results show that aqueous two-phase systems retain their advantages of low cost and intensive recovery (54.56%); the costs of production per gram calculated (before titer optimization: US$15,709 and after optimization: US$2,374) allowed to obtain profit (in the range of US$millions in a 10-year period) for a potential company taking this production method by comparing the production cost against commercial prices. The bioprocess analyzed is a promising and profitable method for the generation of a highly purified B-phycoerythrin. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 32:1472-1479, 2016.

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Genetic manipulation of microalgae for the production of bioproducts

et al. 2018

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Microalgae have been used during the past four decades in the Bio-industries for the production of high added value products and development of useful approaches with environmental applications. The fast growing rate, simple growth requirements and using sunlight as the major source of energy are the key factors for usage of algae. In the past 15 years, a considerable progress has been made regarding the use of microalgae for production of proteins, nutraceuticals, food supplements, molecular tags for diagnostics and fixation of greenhouse gases. Nevertheless, genetic manipulation of microalgae still remains a fairly un-explored area which could boost the production of bioproducts. It is anticipated that in the near future use of microalgae will revolutionize its applications in diverse industries. The aim of this work is to present a critical review on potential of microalgae for the production of high-added value molecules, their practical applications, and the role of genetic engineering in its utilization as a unique niche in industry. In addition, current challenges within synthetic biology approaches are discussed.

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Economic evaluation of M13 bacteriophage production at large‐Scale for therapeutic applications using aqueous Two‐Phase systems

Torres‐Acosta

González‐Mora

Ruiz‐Ruiz

et al. 2020

J of Chemical Tech & Biotech

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BACKGROUND: Bacteriophages are bionanoparticles with several applications in different biotechnology-based products. Among them, vaccines have the potential to treat antibiotic-resistant bacteria and parasitic infections. Traditional methods for their recovery and purification rely on precipitation with polyethylene glycol (PEG) and NaCl. However, the applicability of such an approach is limited, due to large-scale technical constrains. Recently, our research group developed a bacteriophage M13 recovery and purification strategy using Aqueous Two-Phase Systems (ATPS), simplifying the methodology and, potentially, reducing costs. This work aims to develop an economic contrast between ATPS and the traditional PEG precipitation method at different operation scales (10 to 1000 L bioreactor volume) to determine the applicability of the ATPS methodology at large scale. For this, the effect of ATPS volume ratio (V R), sample loading, and materials discount over production cost were analyzed. RESULTS: Results indicate that as the discount on material costs increases, ATPS becomes a more affordable unit operation, from a bioreactor scale of 10 L at 0% discount to 410 L at 90% discount (US$ 52.2 to $1.72 per gram, respectively). Material cost contribution is a parameter that needs attention when working with ATPS, as it is the core for the system construction. Methods for reducing their contribution are highly relevant and should be further investigated. CONCLUSION: Employment of economic analyses help to discover critical parameters for a bioprocess, such as material costs for ATPS. This economic analysis work serves as a platform for new strategies for the recovery of bacteriophage and bacteriophage-like particles using ATPS-based technologies.

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Improved recovery of bacteriophage M13 using an ATPS‐based bioprocess

González‐Mora

Ruiz‐Ruiz

Benavides

et al. 2018

Biotechnology Progress

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Aqueous two-phase systems (ATPS) have been widely exploited for the recovery and partial purification of biological compounds. Recently our research group characterized the primary recovery and partial purification of bacteriophage M13 using polymer-salt and ionic liquid-salt ATPS. From such study, it was concluded that PEG 400-potassium phosphate ATPS with a volume ratio (V ) of 1 and 25% w/w TLL were the best suitable for the primary recovery of bacteriophage M13 from a crude extract, achieving a recovery yield of 83.3%. Although such system parameters were proven to be adequate for the recovery of the product of interest, it was concluded that further optimization was desirable and attainable by studying the effect of additional system parameters such as V , concentration of neutral salt (M) and sample load (% w/w). This research work presents an optimization of a previously reported process for the recovery of bacteriophage M13 directly from a crude extract using ATPS. The increase in V and sample load showed a positive effect in the recovery of M13 indicating an improved performance of the proposed ATPS. According to the results presented here, a system composed of PEG 400 17.2% (w/w), potassium phosphate 15.5% (w/w) and a sample load of 30% (w/w) allowed the recovery of M13 directly from a crude extract with a top phase recovery of 80.1%, representing an increase of 4.8 times in the final concentration and a reduction of 2.65 times in the processing costs. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 2018 © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 34:1177-1184, 2018.

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