Background: Alpha-amylases are enzymes capable of degrading polysaccharides, such as starch and glycogen. Found in various organisms, such as fungi and bacteria, these enzymes have great biotechnological potential due to their insertion in several industrial sectors raging from food to biofuels. Objective: The aim of this study was to analyze patents deposited in intellectual property databases on alpha-amylases in the fields of food, beverages, detergents, animal feeds, biofuels, pharmaceuticals and textiles, with the search period being the 5 years. Method: This study targeted the use of alpha-amylases in various industrial sectors, so searches were carried out on the intellectual property database Espacenet website (European Patent Office - EPO) which contains more than 90 million patents deposited in its database. Results: During the search for patents filed in the last 5 years, 186 were found related to the use of alpha-amylases. These were disturbed as follows: 84 (biofuel), 41 (drinks), 16 (pharmaceuticals), 15 (detergents), 11 (food), 10 (animal feed), 9 (textiles). From the total number of patents found, we selected 6 from each area, except pharmaceutical products, to discuss and provide information on the application of this enzyme. Conclusion: This study demonstrated that the sectors of beverages and animal feed have preferences for thermostable alpha-amylases while sectors such as food, biofuels and textiles only regarded the importance of enzymatic efficiency. The detergent sector presented the greatest use of alpha-amylases which had distinct biochemical characteristics as solvent resistance and thermostability. The pharmaceutical sector was the one that presented less patents related to the application of alpha amylases. In addition, this work showed that China is the country with the highest patent registration for the use of alpha-amylases in the analyzed period.
Background: Microorganisms can migrate from the external environment to the patient's organism through the insertion of catheters. Despite being indispensable medical devices, the catheter surface can be colonized by mi-croorganisms and become a starting point for biofilm formation. Therefore, new technologies are being developed in order to modify surfaces to prevent the adhesion and survival of microorganisms.Patents with the use of DMPEI have been filed. Objective: Objective: In the present work, we coated latex catheter surfaces with 2 mg mL-1 DMPEI in different solvents, evaluated the wettability of the surface and the anti-biofilm activity of the coated catheter against Escherichia coli, Staphylococcus aureus, and Candida albicans. Methods: We coated the inner and outer catheter surface with 2 mg mL-1 of DMPEI solubilized in butanol, dime-thylformamide, and cyclohexanone and were analyzed visually. Contact angle measurement allowed the analysis of the wettability of the surfaces. The CFU mL-1 counting evaluated E. coli, S. aureus, and C. albicans adhesion onto the control and treated surfaces. Results: The contact angle decreased from 50.48º to 46.93º on the inner surface and 55.83º to 50.91º on the outer surface of latex catheters coated with DMPEI. The catheter coated with DMPEI showed anti-biofilm activity of 83%, 88%, and 93% on the inner surface and 100%, 92%, and 86% on the outer surface for E. coli, S. aureus, and C. albicans, respectively. Conclusion: Latex catheter coated with DMPEI efficiently impaired the biofilm formation both in the outer and inner surfaces showing a potential antimicrobial with high anti-biofilm activity for medical devices.
Background: Biosurfactants are natural bioactive compounds produced from fungi, bacteria and plants. These molecules have several properties that enable them to be involved in various industrial applications. The surface-active properties of biosurfactants allow their use in various sectors, such as agriculture, health, cosmetics, bioremediation/petroleum, mining, and bioprocess. Objective: The objective of this study was to analyze the patents deposited in intellectual property databases for applications of biosurfactants in the areas of agriculture, health, cosmetics, bioremediation/petroleum, mining, and bioprocesses, with the research period consisting of the last six years. Method: This study targeted the use of biosurfactants in various industrial sectors. The patent search was carried out using the Google Patents platform, a platform that is commonly used for this purpose and freely accessible. Results: During the search for patents related to applications of biosurfactants in industry filed in the last 6 years, results were found to be distributed in the following areas: agriculture (70), cosmetics (2311), bioremediation/petroleum (179), health (1794), mining (5), and bioprocess (133). Six patents were selected from each area, except for health and mining, for which the search resulted in only 5 and 4 patents, respectively, to be discussed and provide information on the biotechnological applications of biosurfactants in the industry. Conclusion: The present study showed a wide area of application of biosurfactants in industry. The interest in the inclusion of biosurfactants in the industry is directly related to the need for more sustainable solutions to solve real market problems. The cosmetics sector presented the most patents that employ the use of biosurfactants.
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