Your search keyword '"González del Campo, María del Mar"' showing total 6 results

1. Boosting the sensitivity of paper-based biosensors with polymeric water-soluble reservoirs

Author

González del Campo, María del Mar, Alba-Patiño, Alejandra, Palomino, Carlos, Bauzá, Marta, Rojo-Molinero, Estrella, Oliver, Antonio, Turnes, Gemma, and de la Rica, Roberto

Published

2022

2. Paper biosensors for detecting elevated IL-6 levels in blood and respiratory samples from COVID-19 patients

Author

Adrover-Jaume, Cristina, Alba-Patiño, Alejandra, Clemente, Antonio, Santopolo, Giulia, Vaquer, Andreu, Russell, Steven M., Barón, Enrique, González del Campo, María del Mar, Ferrer, Joana M., Berman-Riu, María, García-Gasalla, Mercedes, Aranda, María, Borges, Marcio, and de la Rica, Roberto

Published

2021

3. Cellulose nanofibers-sepiolite biohybrid materials

Author

González del Campo, María del Mar, Darder, Margarita, Aranda, Pilar, Huttel, Yves, Ruiz-Hitzky, Eduardo, and Ministerio de Economía y Competitividad (España)

Abstract

Oral presentation given at the XVI International Clay Conference, held in Granada (Spain) on July 17-21, 2017., Bionanocomposites are a type of nanostructured biohybrid materials resulting from the assembly of naturally occurring polymers and inorganic solids with particle size in the nanometer scale [1], as for instance diverse clay minerals with layered or fibrous morphology [2,3]. Amongst biopolymers, there is a special interest in the use of polysaccharides for the preparation of bionanocomposites due to their abundancy in nature and their renewable and biodegradable character. In the recent years, many works are focusing on the use of cellulose, the most abundant polysaccharide on Earth, to develop new hybrid materials involving clay minerals [4-7]. Cellulose chains consisting of β(1→4) linked D-glucose units are arranged in crystalline and amorphous regions forming elementary fibrils, which are in turn assembled forming the cellulose fibers present in the cell wall of plants [8]. In this context, the current work explores the development of biohybrids based on the assembly of cellulose nanofibers (CNF) to the fibrous clay sepiolite. For this purpose, Pangel® S9, sepiolite from Vallecas-Vicálvaro of rheological grade commercialized by Tolsa SA, was used together with CNF (dimensions around 0.5-2 μm in length and 4-20 nm in diameter), which was prepared following a reported procedure [9] and gently provided by Prof. P. Mutjé (LEPAMAP group, Univ. of Girona, Spain). Aqueous suspensions of CNF and sepiolite were combined by means of shear force and ultrasounds energy in order to produce homogenous and stable gels, which can be dried by solvent casting or vacuum filtration leading to self-standing films [7]. The sonication treatment seems to be compulsory in order to obtain uniform films with a considerable degree of transparency. The characterization of these materials reveals the good interaction between both types of fibers of biological and inorganic nature. The decrease in intensity of the IR vibration band at 3720 cm-1, related to the O-H stretching vibration of silanol groups in sepiolite, suggests a perturbation due to their hydrogen bonding interaction with hydroxyl groups in CNF. Accordingly, XPS results show a large perturbation in the C1s signal from CNF as a consequence of its interaction with sepiolite. Tensile modulus values of hybrid films show slightly higher values than those of the individual components, reaching a maximum value of 3.4 GPa for the material containing 20% sepiolite. The thermal stability was also improved as the sepiolite content increased, showing a shift in the thermal decomposition temperature towards higher values. The degree of hydrophobicity can be also controlled with the sepiolite content, and thus, water adsorption was reduced in hybrid films containing a small percentage of inorganic fibers in comparison to pristine CNF. The possibility of incorporating other nanoparticles allows the preparation of multifunctional materials [10]. For instance, multi-walled carbon nanotubes (MWCNTs) can be included in the CNF-sepiolite hybrids in order to provide them with electrical conductivity, allowing their application as active phase in sensor devices., MINECO (Spain), projects MAT2012-31759 & MAT2015-71117-R, and PhD fellowship BES-2013-064677 (MMGC).

Published

2017

4. Composite material of nanocellulose and fibrous clays, method of production and use thereof

Author

Ruiz-Hitzky, Eduardo, Aranda, Pilar, Darder, Margarita, and González del Campo, María del Mar

Abstract

[EN] The invention relates to a stable composite material comprising defibrated cellulose and particles having a fibrous morphology or fibres of silicates belonging to the family of fibrous clays, interwoven nanometrically. Furthermore, the invention relates to a method for producing said composite material and the uses thereof as adsorbents, absorbents, thickening agents, food additives, catalyst supports, enzyme supports, drug supports, flame retardants and self-extinguishing materials, cement additives, special papers, elements of sensor materials, inter alia. [ES] La invención se refiere a un material composite estable que comprende celulosa desfibrada y partículas de morfología fibrosa o fibras de silicatos pertenecientes a la familia de las arcillas fibrosas, entrelazadas nanométricamente. Además, la invención se refiere a un procedimiento de preparación de dicho material composite y sus usos como adsorbentes, absorbentes agentes espesantes, aditivos en alimentación, soportes de catalizadores, soportes de enzimas, soportes de fármacos, retardantes de llama y materiales autoextinguibles, aditivos de cementos, papeles especiales, elementos de materiales sensores, entre otros. Peer reviewed Consejo Superior de Investigaciones Científicas (España) A1 Solicitud de patente con informe sobre el estado de la técnica

Published

2015

5. Composite material of nanocellulose and fibrous clays, method of production and use thereof

Author

Ruiz-Hitzky, Eduardo, Aranda, Pilar, Darder, Margarita, and González del Campo, María del Mar

Subjects

humanities

Abstract

[EN] The invention relates to a stable composite material comprising defibrated cellulose and particles having a fibrous morphology or fibres of silicates belonging to the family of fibrous clays, interwoven nanometrically. Furthermore, the invention relates to a method for producing said composite material and the uses thereof as adsorbents, absorbents, thickening agents, food additives, catalyst supports, enzyme supports, drug supports, flame retardants and self-extinguishing materials, cement additives, special papers, elements of sensor materials, inter alia., [ES] La invención se refiere a un material composite estable que comprende celulosa desfibrada y partículas de morfología fibrosa o fibras de silicatos pertenecientes a la familia de las arcillas fibrosas, entrelazadas nanométricamente. Además, la invención se refiere a un procedimiento de preparación de dicho material composite y sus usos como adsorbentes, absorbentes agentes espesantes, aditivos en alimentación, soportes de catalizadores, soportes de enzimas, soportes de fármacos, retardantes de llama y materiales autoextinguibles, aditivos de cementos, papeles especiales, elementos de materiales sensores, entre otros., Consejo Superior de Investigaciones Científicas (España), A1 Solicitud de patente con informe sobre el estado de la técnica

Published

2014

6. Bionanocomposites basados en arcillas fibrosas y celulosa desfibrada

Author

González del Campo, María del Mar, Darder, Margarita, Prieto, Pilar, Ruiz-Hitzky, Eduardo, Comisión Interministerial de Ciencia y Tecnología, CICYT (España), Ministerio de Economía y Competitividad (España), and European Cooperation in Science and Technology

Subjects

Bionanocomposites, Fibrous clays, Palygorskite, Palygorskita, Sepiolite, Arcillas fibrosas, Microcrystalline cellulose, Sepiolita, Celulosa microcristalina

Abstract

Comunicación oral dada en la XXIII Reunión de la Sociedad Española de Arcillas que tuvo lugar en Toledo (España) del 10 al 12 de septiembre de 2014., Los bionanocomposites son materiales híbridos constituidos por polímeros de origen natural asociados con sólidos inorgánicos, como pueden ser las arcillas, a través de interacciones a escala nanométrica entre ambos componentes (Darder y col., 2007). Al igual que los sistemas polímero-arcilla convencionales, estos nanocomposites de naturaleza biohíbrida (bionanocomposites), presentan interesantes propiedades estructurales y funcionales, incorporando además el carácter biocompatible y biodegradable asociado al biopolímero (Darder y col., 2007; Ruiz-Hitzky y col., 2008, 2013)., Proyectos MAT2012-31759 (CICYT, España) y MP1202 (COST Action, UE). MMGC agradece al MINECO (España) la ayuda BES-2013-064677.

Published

2014