Estudio preliminar de la obtención de compuestos híbridos de quitosano y polifenoles derivados de lignina a partir de subproductos agropecuarios y pesquería de camarón

En este estudio se prepararon y caracterizaron microcápsulas híbridas del conjugado de polifenolesderivados de la lignina proveniente de la cáscara de piña, y el quitosano obtenido a partir de laquitina de la cáscara del camarón; ambos materiales fueron obtenidos como residuos de la industriaagropecuaria y pesquería de camarón de Costa Rica. Con el objetivo de preparar compuestosfenólicos derivados de la lignina, y utilizarlos en la síntesis de las microcápsulas, se realizó lahidrólisis enzimática de la misma en un reactor a presión atmosférica a un pH de 6.8, en bufferde citrato 1 M, durante 6 h a 37ºC. Las enzimas utilizadas fueron extraídas de los cultivos dehongos de Gloeophyllum trabeum (Pers.) Murrill y Phanerochae chrysosporiumin Burdsall.Para la obtención del quitosano se realizó la desacetilación alcalina a partir de exoesqueletosdel camarón Heterocarpus vicarius Fazon. Para la preparación de las microcápsulas se empleóuna disolución de quitosano en ácido acético, el cual fue mezclado con una disolución acuosadel producto obtenido de la hidrólisis de la lignina y luego añadido a una disolución de vaselinapara microemulsionar. Posteriormente, se agregó el glutaraldehído como agente entrecruzante.Se obtuvieron microcápsulas con tamaños entre 5 y 10 μm. Estas microcápsulas son un materialpromisorio ya que, mediante la formación del complejo, se puede aumentar la solubilidad delquitosano y estabilizar los polifenoles, manteniendo así sus propiedades antioxidantes. Losresultados preliminares obtenidos en esta investigación, muestran el potencial de este material parael encapsulamiento de fármacos y pesticidas

Preliminary study of the production of hybrid compounds of chitosan and polyphenols derived from lignin from agroindustry and shrimp fishery

En este estudio se prepararon y caracterizaron microcápsulas híbridas del conjugado de polifenoles derivados de la lignina proveniente de la cáscara de piña, y el quitosano obtenido a partir de la quitina de la cáscara del camarón; ambos materiales fueron obtenidos como residuos de la industria agropecuaria y pesquería de camarón de Costa Rica. Con el objetivo de preparar compuestos fenólicos derivados de la lignina, y utilizarlos en la síntesis de las microcápsulas, se realizó la hidrólisis enzimática de la misma en un reactor a presión atmosférica a un pH de 6.8, en buffer de citrato 1 M, durante 6 h a 37ºC. Las enzimas utilizadas fueron extraídas de los cultivos de hongos de Gloeophyllum trabeum (Pers.) Murrill y Phanerochae chrysosporiumin Burdsall. Para la obtención del quitosano se realizó la desacetilación alcalina a partir de exoesqueletos del camarón Heterocarpus vicarius Fazon. Para la preparación de las microcápsulas se empleó una disolución de quitosano en ácido acético, el cual fue mezclado con una disolución acuosa del producto obtenido de la hidrólisis de la lignina y luego añadido a una disolución de vaselina para microemulsionar. Posteriormente, se agregó el glutaraldehído como agente entrecruzante. Se obtuvieron microcápsulas con tamaños entre 5 y 10 μm. Estas microcápsulas son un material promisorio ya que, mediante la formación del complejo, se puede aumentar la solubilidad del quitosano y estabilizar los polifenoles, manteniendo así sus propiedades antioxidantes. Los resultados preliminares obtenidos en esta investigación, muestran el potencial de este material para el encapsulamiento de fármacos y pesticidas.Hybrid microcapsules of the conjugate of polyphenols derived from lignin were prepared and characterized. They were obtained from pineapple peel and chitin from shrimp shell from agroindustry or shrimp fishery of Costa Rica. The phenolic compounds were obtained by hydrolysis of lignin, using the enzyme derivatives from the fungus culture of Gloeophyllum trabeum (Pers.) Murrill and Phanerochaete chrysosporium Burdsall. The reaction was carried out in a reactor with atmospheric pressure, pH 6.8, with a citrate buffer of 1M, for 6 hours at 37°C. The chitosan was obtained by alkaline deacetylation of the Heterocarpus vicarious Fazon, shrimp exoskeletons. Microcapsules were prepared mixing a solution of chitosan dissolved in acetic acid and a solution of polyphenol derivatives from lignin. Afterwards, they were added to a vaseline aqueous solution for the microemulsion formation and glutaraldehyde was added as a crosslinking agent. Microcapsules with sizes between 5 to 10 μm were obtained. These microcapsules are a promising material to increase chitosan solubility and for preventing the oxidation of polyphenols. The preliminary results obtained in this research show the potential of this material for the encapsulation of drugs and pesticides

Pineapple agro-industrial biomass to produce biomedical applications in a circular economy context in Costa Rica

Pineapple is a highly demanded fruit in international markets due to its unique appearance and flavor, high fiber content, vitamins, folic acid, and minerals. It makes pineapple production and processing a significant source of income for producing countries, such as Costa Rica. This review collects bibliographic information dating back to the beginnings of pineapple production in Costa Rica to the state of the market today. It details the impacts of its production chain and proposes a biorefinery as a solution to environmental problems. Besides the potentiality of new sustainable markets to contribute to the post-COVID-19 economy in Costa Rica is highlighted. The general characteristics of pineapple by-products -cellulose, hemicellulose, lignin, and other high-value products like bromelain y saponin- are described, as well as the primary processes for their ex-traction via biorefinery and main applications in the medical field. Finally, a brief description of the main works in the literature involving modeling and simulation studies of pineapple by-products properties is included

Functionalization of breast implants by cyclodextrin in-situ polymerization: a local drug delivery system for augmentation mammaplasty

Mammaplasty is a widely performed surgical procedure worldwide, utilized for breast reconstruction, in the context of breast cancer treatment, and aesthetic purposes. To enhance post-operative outcomes and reduce risks (hematoma with required evacuation, capsular contracture, implant-associated infection and others), the controlled release of medicaments can be achieved using drug delivery systems based on cyclodextrins (CDs). In this study, our objective was to functionalize commercially available silicone breast implants with smooth and textured surfaces through in-situ polymerization of two CDs: β-CD/citric acid and 2-hydroxypropyl-β-CD/citric acid. This functionalization serves as a local drug delivery system for the controlled release of therapeutic molecules that potentially can be a preventive treatment for post-operative complications in mammaplasty interventions. Initially, we evaluated the pre-treatment of sample surfaces with O2 plasma, followed by chitosan grafting. Subsequently, in-situ polymerization using both types of CDs was performed on implants. The results demonstrated that the proposed pre-treatment significantly increased the polymerization yield. The functionalized samples were characterized using microscopic and physicochemical techniques. To evaluate the efficacy of the proposed system for controlled drug delivery in augmentation mammaplasty, three different molecules were utilized: pirfenidone (PFD) for capsular contracture prevention, Rose Bengal (RB) as anticancer agent, and KR-12 peptide (KR-12) to prevent bacterial infection. The release kinetics of PFD, RB, and KR-12 were analyzed using the Korsmeyer-Peppas and monolithic solution mathematical models to identify the respective delivery mechanisms. The antibacterial effect of KR-12 was assessed against Staphylococcus epidermidis and Pseudomonas aeruginosa, revealing that the antibacterial rate of functionalized samples loaded with KR-12 was dependent on the diffusion coefficients. Finally, due to the immunomodulatory properties of KR-12 peptide on epithelial cells, this type of cells was employed to investigate the cytotoxicity of the functionalized samples. These assays confirmed the superior properties of functionalized samples compared to unprotected implants

Análisis de agua para consumo humano en Playa Rey

informe de proyecto de voluntariado -- Universidad de Costa Rica, Programa de Voluntariado. 2005Análisis microbiológico y físico-químico de la calidad y potabilidad del agua en el sector Playa Rey del Parque Nacional Manuel Antonio - Costa Rica, recientemente incorporadas al área de protección.Universidad de Costa RicaUCR::Vicerrectoría de Vida Estudianti

Estudio preliminar de la obtención de compuestos híbridos de quitosano y polifenoles derivados de lignina a partir de subproductos agropecuarios y pesquería de camarón

Hybrid microcapsules of the conjugate of polyphenols derived from lignin were prepared and characterized. They were obtained from pineapple peel and chitin from shrimp shell from agroindustry or shrimp fishery of Costa Rica. The phenolic compounds were obtained by hydrolysis of lignin, using the enzyme derivatives from the fungus culture of Gloeophyllum trabeum (Pers.) Murrill and Phanerochaete chrysosporium Burdsall. The reaction was carried out in a reactor with atmospheric pressure, pH 6.8, with a citrate buffer of 1M, for 6 hours at 37°C. The chitosan was obtained by alkaline deacetylation of the Heterocarpus vicarious Fazon, shrimp exoskeletons. Microcapsules were prepared mixing a solution of chitosan dissolved in acetic acid and a solution of polyphenol derivatives from lignin. Afterwards, they were added to a vaseline aqueous solution for the microemulsion formation and glutaraldehyde was added as a crosslinking agent. Microcapsules with sizes between 5 to 10 μm were obtained. These microcapsules are a promising material to increase chitosan solubility and for preventing the oxidation of polyphenols. The preliminary results obtained in this research show the potential of this material for the encapsulation of drugs and pesticides.En este estudio se prepararon y caracterizaron microcápsulas híbridas del conjugado de polifenolesderivados de la lignina proveniente de la cáscara de piña, y el quitosano obtenido a partir de laquitina de la cáscara del camarón; ambos materiales fueron obtenidos como residuos de la industriaagropecuaria y pesquería de camarón de Costa Rica. Con el objetivo de preparar compuestosfenólicos derivados de la lignina, y utilizarlos en la síntesis de las microcápsulas, se realizó lahidrólisis enzimática de la misma en un reactor a presión atmosférica a un pH de 6.8, en bufferde citrato 1 M, durante 6 h a 37ºC. Las enzimas utilizadas fueron extraídas de los cultivos dehongos de Gloeophyllum trabeum (Pers.) Murrill y Phanerochae chrysosporiumin Burdsall.Para la obtención del quitosano se realizó la desacetilación alcalina a partir de exoesqueletosdel camarón Heterocarpus vicarius Fazon. Para la preparación de las microcápsulas se empleóuna disolución de quitosano en ácido acético, el cual fue mezclado con una disolución acuosadel producto obtenido de la hidrólisis de la lignina y luego añadido a una disolución de vaselinapara microemulsionar. Posteriormente, se agregó el glutaraldehído como agente entrecruzante.Se obtuvieron microcápsulas con tamaños entre 5 y 10 μm. Estas microcápsulas son un materialpromisorio ya que, mediante la formación del complejo, se puede aumentar la solubilidad delquitosano y estabilizar los polifenoles, manteniendo así sus propiedades antioxidantes. Losresultados preliminares obtenidos en esta investigación, muestran el potencial de este material parael encapsulamiento de fármacos y pesticidas

Extracellular micro and nanostructures forming the velvet worm solidified adhesive secretion

The onycophoran Epiperipatus hilkae secrets a sticky slime that solidifies almost immediately upon contact with air and under high humidy environmental condition forming a glassy like material. The general adhesive biochemical composition, the releasing and hardening mechanism have been partially described. In this study, the structural characterization of the extracellular microstructures and nanostructures forming the solid adhesive of the secretion from Epiperipatus hilkae velvet worm is presented. The adhesive secretion is formed by macro-threads, which, in their solid state, are composed of globular particles approximately 700 nm in diameter that are distributed homogeneously throughout the matrix surface, and nanoparticles approximately 70 nm in diameter that self-assemble forming fiber-like structures. Nanoparticles with non roundish forms are also observed. These 70 nm particles could be associated to proteins that form high density coverage films with low roughness; suggesting the formation of two dimensional ordered films. A crystalline and an amorphous phase composes the solidified secretion. The glassy or viscoelastic properties depend on the time in contact with air before being adhered to a solid surface and/or the mechanical stimulus; suggesting a key role of the drying on the hardening process

Bio-Inspired Proanthocyanidins from Blueberries’ Surface Coating Prevents Red Blood Cell Agglutination on Urinary Silicon-Based Catheters

Thrombosis can cause the occlusion of implantable medical devices, leading to the rejection of the device and subsequent mortality. Thrombosis is primarily induced by red blood aggregation and coagulation. The administration of anticoagulant drugs is generally used as a treatment to avoid these processes. Adverse effects such as bleeding in the event of an anticoagulant overdose, osteoporosis associated with prolonged use, hypersensitivity, and hives have been reported. New strategies such as biomolecule surface functionalization have recently been studied to overcome these problems. In this study, we report a novel coating composed of polydopamine (PDA) and proanthocyanidins (PACs) from blueberry extract to avoid red blood aggregation in short-term use medical devices such as silicone catheters. We showed that PDA formed stable films on silicone surfaces and PACs could be immobilized on PDA layers using laccase as a catalyst. The PDA–PACs films decreased surface hydrophilicity, increased surface roughness, and decreased plasma protein adsorption. The films were stable in phosphate buffer saline (PBS) and cell culture media. Furthermore, red blood cell adsorption and aggregation decreased. These effects are attributed to changes in the membrane fluidity that influences adhesion, the steric hindrance of the layers, and the low adsorption of plasma proteins on the PAC layer

Influences of the pH on the adsorption properties of an antimicrobial peptide on titanium surfaces

The adsorption behavior of the Tet-124 antimicrobial peptide and the Tet-124peptide modified at the C- and N-terminus with the sequence glycine-3,4-dihydroxyphenylalanine-glycine (G-DOPA-G) on titanium surfaces was studied using quartz crystal micro balance with dissipation (QCM-D). At a low pH level(4.75) Tet-124 and Tet-124-G-DOPA-G form rigid layers. This is attributed to the electrostatic interactions of the positively charged lysine and arginine residues in the peptide sequence with the negatively charged titanium oxide layer. At an elevated pH level (6.9) Tet-124 shows a lower mass adsorption at the surface than Tet-124-G-DOPA-G. This is attributed to the interaction of the catechol due to the formation of complexes with the titanium oxide and titanium surface layer. The C terminal and N terminal modification with the sequence G-DOPA-G shows similar adsorption rate and mass adsorption coverage at saturation; however it is presented a more loosely layers on the G-DOPA-G-TeT-124. Fibroblast adhesion and the biocompatibility test of both the surfaces following modification withTet-124-G-DOPA-G and the titanium alloy control showed similar results. In addition, no changes in the adhesion of E. colibacteria due to the modification of the surface were detected

Biogenic silica-based microparticles obtained as a sub-product of the nanocellulose extraction process from pineapple peels

Vega-Baudrit, Jose R. ( Jose Roberto Vega Baudrit)Silica in plant tissues has been suggested as a component for enhancing mechanical properties, and as a physical barrier. Pineapples present in their shell and bracts rosette-like microparticles that could be associated to biogenic silica. In this study, we show for the first time that silica-based microparticles are co-purified during the extraction process of nanocellulose from pineapple (Ananas comosus). This shows that vegetable biomass could be an underappreciated source, not only for nanocellulose, but also for a highly valuable sub-product, like 10 µm biogenic rosette-like silica-based microparticles. The recovery yield obtained was 7.2 wt.%; based on the dried initial solid. Due to their size and morphology, the microparticles have potential applications as reinforcement in adhesives, polymer composites, in the biomedical field, and even as a source of silica for fertilizers