Your search keyword '"Materialkemi"' showing total 9 results

1. Mesoporous Silica Particles Retain Their Structure and Function while Passing through the Gastrointestinal Tracts of Mice and Humans

Author

Muhammad Naeem Iqbal, Ghislaine Robert-Nicoud, Marina Ciurans-Oset, Farid Akhtar, Niklas Hedin, and Tore Bengtsson

Subjects

Other Medical Biotechnology, porcine pancreatic α-amylase, Materials Chemistry, Materialkemi, General Materials Science, gastrointestinal tract, biostability, mesoporous silica particles, protein adsorption, Annan medicinsk bioteknologi

Abstract

Mesoporous silica particles (MSPs) can be used as food additives, clinically for therapeutic applications, or as oral delivery vehicles. It has also been discussed to be used for a number of novel applications including treatment for diabetes and obesity. However, a major question for their possible usage has been if these particles persist structurally and retain their effect when passing through the gastrointestinal tract (GIT). A substantial breaking down of the particles could reduce function and be clinically problematic for safety issues. Hence, we investigated the biostability of MSPs of the SBA-15 kind prepared at large scales (100 and 1000 L). The MSPs were orally administered in a murine model and clinically in humans. A joint extraction and calcination method was developed to recover the MSPs from fecal mass, and the MSPs were characterized physically, structurally, morphologically, and functionally before and after GIT passage. Analyses with N2 adsorption, X-ray diffraction, electron microscopy, and as a proxy for general function, adsorption of the enzyme α-amylase, were conducted. The adsorption capacity of α-amylase on extracted MSPs was not reduced as compared to the pristine and control MSPs, and adsorption of up to 17% (w/w) was measured. It was demonstrated that the particles did not break down to any substantial degree and retained their function after passing through the GITs of the murine model and in humans. The fact the particles were not absorbed into the body was ascribed to that they were micron-sized and ingested as agglomerates and too big to pass the intestinal barrier. The results strongly suggest that orally ingested MSPs can be used for a number of clinical applications. Validerad;2023;Nivå 2;2023-03-08 (joosat);Licens fulltext: CC BY License

Published

2023

2. Nanostructurally Controllable Strong Wood Aerogel toward Efficient Thermal Insulation

Author

Jonas Garemark, Jesus E. Perea-Buceta, Daniel Rico del Cerro, Stephen Hall, Barbara Berke, Ilkka Kilpeläinen, Lars A. Berglund, Yuanyuan Li, Department of Chemistry, Helsinki Institute of Sustainability Science (HELSUS), and Synthesis and Analysis

Subjects

116 Chemical sciences, aerogel, NANOFIBRILLATED CELLULOSE, Materialkemi, THERMAL INSULATION, Nanoscience, IONIC LIQUIDS, CHEMISTRY, sustainable materials, KEYWORDS, aerogel wood ionic liquid thermal insulation sustainable materials, Materials Chemistry, NANOCELLULOSE, FOAMS, CHLORIDE, General Materials Science, AEROGELS, CONDUCTIVITY, wood, ionic liquid

Abstract

Eco-friendly materials with superior thermal insulation and mechanical properties are desirable for improved energy- and space-efficiency in buildings. Cellulose aerogels with structural anisotropy could fulfill these requirements, but complex processing and high energy demand are challenges for scaling up. Here we propose a scalable, nonadditive, top-down fabrication of strong anisotropic aerogels directly from wood with excellent, near isotropic thermal insulation functions. The aerogel was obtained through cell wall dissolution and controlled precipitation in lumen, using an ionic liquid (IL) mixture comprising DMSO and a guanidinium phosphorus-based IL [MTBD][MMP]. The wood aerogel shows a unique structure with lumen filled with nanofibrils network. In situ formation of a cellulosic nanofibril network in the lumen results in specific surface areas up to 280 m2/g and high yield strengths >1.2 MPa. The highly mesoporous structure (average pore diameter ∼20 nm) of freeze-dried wood aerogels leads to low thermal conductivities in both the radial (0.037 W/mK) and axial (0.057 W/mK) directions, showing great potential as scalable thermal insulators. This synthesis route is energy efficient with high nanostructural controllability. The unique nanostructure and rare combination of strength and thermal properties set the material apart from comparable bottom-up aerogels. This nonadditive synthesis approach is believed to contribute significantly toward large-scale design and structure control of biobased aerogels. QC 20221019

Published

2022

3. Thiazoline Carbene–Cu(I)–Amide complexes: Efficient White Electroluminescence from Combined Monomer and Excimer Emission

Author

Armands Ruduss, Baiba Turovska, Sergey Belyakov, Kitija A. Stucere, Aivars Vembris, Glib Baryshnikov, Hans Ågren, Jhao-Cheng Lu, Wei-Han Lin, Chih-Hao Chang, and Kaspars Traskovskis

Subjects

thermally activated delayed fluorescence, carbene-metal-amide, Materials Chemistry, organic light-emitting diode, conformational locking, white emission, Materialkemi, excimer, General Materials Science, copper complex, Marcus theory

Abstract

Luminescent carbene-metal-amide complexes bearing group 11 metals (Cu, Ag, Au) have recently attracted great attention due to their exceptional emission efficiency and high radiative decay rates (k(r)). These materials provide a less costly alternative to organic light-emitting diode (OLED) emitters based on more scarce metals, such as Ir and Pt. Herein, a series of eight Cu(I) complexes bearing as yet unexplored 1,3-thiazoline carbenes have been investigated and analyzed with respect to their light emission properties and OLED application. For the first time among the class of copper-based organometallic compounds the formation of efficient electroluminescent excimers is demonstrated. The prevalence of electroluminescence (EL) from either the monomer (bluish green) or the excimer (orange-red) can be adjusted in vacuum-deposited emissive layers by altering the extent of steric encumbrance of the emitter or its concentration. Optimized conditions in terms of the emitter structure and mass fraction allowed a simultaneous EL from the monomer and excimer, which laid the basis for a preparation of a single-emitter white OLED (WOLED) with external quantum efficiency of 16.5% and a maximum luminance of over 40000 cd m(-2). Wide overlapping emission bands of the monomer and excimer ensure a device color rendering index (CRI) of above 80. In such a way the prospects of copper complexes as cost-effective materials for lighting devices are demonstrated, offering expense reduction through a cheaper emissive component and a simplified device architecture.

Published

2022

4. Potentials in Li-Ion Batteries Probed by Operando Ambient Pressure Photoelectron Spectroscopy

Author

Ida Källquist, Tove Ericson, Fredrik Lindgren, Heyin Chen, Andrey Shavorskiy, Julia Maibach, and Maria Hahlin

Subjects

Fysikalisk kemi, Technology, photoelectron spectroscopy, ambient pressure photoelectron spectroscopy, Materialkemi, Physical Chemistry, electrochemistry, operando, solid/liquid interface, Materials Chemistry, Li-ion battery, General Materials Science, electrochemical potential, ddc:600

Abstract

The important electrochemical processes in a battery happen at the solid/liquid interfaces. Operando ambient pressure photoelectron spectroscopy (APPES) is one tool to study these processes with chemical specificity. However, accessing this crucial interface and identifying the interface signal are not trivial. Therefore, we present a measurement setup, together with a suggested model, exemplifying how APPES can be used to probe potential differences over the electrode/electrolyte interface, even without direct access to the interface. Both the change in electron electrochemical potential over the solid/liquid interface, and the change in Li chemical potential of the working electrode (WE) surface at Li-ion equilibrium can be probed. Using a Li4Ti5O12 composite as a WE, our results show that the shifts in kinetic energy of the electrolyte measured by APPES can be correlated to the electrochemical reactions occurring at the WE/electrolyte interface. Different shifts in kinetic energy are seen depending on if a phase transition reaction occurs or if a single phase is lithiated. The developed methodology can be used to evaluate charge transfer over the WE/electrolyte interface as well as the lithiation/delithiation mechanism of the WE.

Published

2022

5. Chemistry of Oxygen Ionosorption on SnO2 Surfaces

Author

Clas Persson, Ping Wu, Oleksandr I. Malyi, and Kostiantyn V. Sopiha

Subjects

Surface (mathematics), Materials science, Tin dioxide, Ab initio, Materialkemi, chemistry.chemical_element, surface chemistry, Conductivity, Oxygen, chemistry.chemical_compound, chemiresistive sensing, Adsorption, chemistry, Chemical physics, charged oxygen species, Ionization, Materials Chemistry, SN2 reaction, tin dioxide, General Materials Science, ionosorption model, Research Article

Abstract

Ionosorbed oxygen is the key player in reactions on metal-oxide surfaces. This is particularly evident for chemiresistive gas sensors, which operate by modulating the conductivity of active materials through the formation/removal of surface O-related acceptors. Strikingly though, the exact type of species behind the sensing response remains obscure even for the most common material systems. The paradigm for ab initio modeling to date has been centered around charge-neutral surface species, ignoring the fact that molecular adsorbates are required to ionize to induce the sensing response. Herein, we resolve this inconsistency by carrying out a careful analysis of all charged O-related species on three naturally occurring surfaces of SnO2. We reveal that two types of surface acceptors can form spontaneously upon the adsorption of atmospheric oxygen: (i) superoxide O2- on the (110) and the (101) surfaces and (ii) doubly ionized O2- on the (100) facet, with the previous experimental evidence pointing to the latter as the source of sensing response. This species has a unique geometry involving a large displacement of surface Sn, forcing it to attain the coordination resembling that of Sn2+ in SnO, which seems necessary to stabilize O2- and activate metal-oxide surfaces for gas sensing.

Published

2021

6. Highly Conducting Nanographite-Filled Paper Fabricated via Standard Papermaking Techniques

Author

Hjalmar Granberg, Magnus Berggren, Emilie Calvie, Göran Gustafsson, Desalegn Alemu Mengistie, Xin Wang, Patrik Isacsson, Andreas Fall, and Isak Engquist

Subjects

Materials science, nanographite, Materialkemi, Nanotechnology, 02 engineering and technology, Conductivity, 010402 general chemistry, 01 natural sciences, electronic paper, printed electronics, electrochromic display, graphene, cellulose, self-assembly, law.invention, law, Materials Chemistry, General Materials Science, Fiber, Electronic paper, Graphene, Papermaking, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Electrochromism, Printed electronics, Self-assembly, 0210 nano-technology, Research Article

Abstract

Eco-friendly and cost-effective materials and processes to manufacture functional substrates are crucial to further advance the area of printed electronics. One potential key component in the printed electronics platform is an electrically functionalized paper, produced by simply mixing common cellulosic pulp fibers with high-performance electroactive materials. Herein, an electronic paper including nanographite has been prepared using a standardized and scalable papermaking technique. No retention aid was needed to achieve a conducting nanographite loading as high as 50 wt %. The spontaneous retention that provides the integrity and stability of the nanographite paper, likely originates partially from an observed water-stable adhesion of nanographite flakes onto the fiber surfaces. The resulting paper exhibits excellent electrical characteristics, such as an in-plane conductivity of 107 S/cm and an areal capacitance of 9.2 mF/cm(2), and was explored as the back-electrode in printed electrochromic displays. Funding Agencies|Digital Cellulose Centre, a competence center set up by the Swedish Innovation Agency VINNOVA; consortium of Swedish forest industries; Wallenberg Wood Science Center (Knut and Alice Wallenberg Foundation); VINNOVA "EPIC" projectVinnova [2017-05413]; Karl-Erik Onnesjo Foundation

Published

2020

7. Redox Dual-Cocatalyst-Modified CdS Double-Heterojunction Photocatalysts for Efficient Hydrogen Production

Author

Jiefang Zhu, Xiaofeng Wei, Yi Zhao, Lu Chen, Yongfeng Lu, and Yuanhui Zheng

Subjects

Materials science, Hydrogen, Phosphide, Materialkemi, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Redox, Catalysis, chemistry.chemical_compound, double heterojunctions, Materials Chemistry, General Materials Science, phosphate, Hydrogen production, Photocurrent, phosphide, 021001 nanoscience & nanotechnology, Cadmium sulfide, 0104 chemical sciences, chemistry, Chemical engineering, Photocatalysis, photocatalytic hydrogen evolution, 0210 nano-technology, cadmium sulfide, Research Article

Abstract

Cadmium sulfide (CdS) as one of the most common visible-light-responsive photocatalysts has been widely investigated for hydrogen generation. However, its low solar-hydrogen conversion efficiency caused by fast carrier recombination and poor catalytic activity hinders its practical applications. To address this issue, we develop a novel and highly efficient nickel-cobalt phosphide and phosphate cocatalyst-modified CdS (NiCoP/CdS/NiCoPi) photocatalyst for hydrogen evolution. The dual-cocatalysts were simultaneously deposited on CdS during one phosphating step by using sodium hypophosphate as the phosphorus source. After the loading of the dual-cocatalysts, the photocurrent of CdS significantly increased, while its electrical impedance and photoluminescence emission dramatically decreased, which indicates the enhancement of charge carrier separation. It was proposed that the NiCoP cocatalyst accepts electrons and promotes hydrogen evolution, while the NiCoPi cocatalyst donates electrons and accelerates the oxidation of sacrificial agents (e.g., lactic acid). Consequently, the visible-light-driven hydrogen evolution of this composite photocatalyst greatly improved. The dual-cocatalyst-modified CdS with a loading content of 5 mol % showed a high hydrogen evolution rate of 80.8 mmol.g(-1).h(-1), which was 202 times higher than that of bare CdS (0.4 mmol.g(-1).h(-1)). This is the highest enhancement factor for metal phosphide-modified CdS photocatalysts. It also exhibited remarkable stability in a continuous photocatalytic test with a total reaction time of 24 h.

Published

2020

8. Biobased Cellulose Nanofibril–Oil Composite Films for Active Edible Barriers

Author

Valencia, Luis, Nomena, Emma M., Mathew, Aji P., and Velikov, Krassimir P.

Subjects

emulsion, edible barrier, active packaging, Materials Chemistry, Materialkemi, nanocellulose, oleofilm

Abstract

Low-concentration oil-in-water emulsions stabilized by cellulose nanofibrils (CNFs) extracted from primary plant cell wall materials are used to prepare thin biobased CNF–oil composite films by solvent casting. Flexible, transparent, and biodegradable composite films are obtained, with increased thermal stability (up to 300 °C) as the oil concentration increases. Examination of the microstructure demonstrates a clear dependency on the oil content, as a multilayered structure where the oil phase trapped between two layers of CNFs is appreciated at high oil concentrations. The embedded oil significantly influences the mechanical and wetting properties of the films, confirming their potential for use in packaging systems. Encapsulation of curcumin in the composite films leads to an increased antioxidant (up to 30% radical scavenging activity) and antimicrobial activity, inhibiting the growth of foodborne bacteria such as Escherichia coli. The resulting composite films show promising results in the field of active packaging for applications in the food, pharmaceutical, and cosmetic industries.

Published

2019

9. Hyperthermia-Induced In Situ Drug Amorphization by Superparamagnetic Nanoparticles in Oral Dosage Forms

Author

Shaquib Rahman Ansari, Nele-Johanna Hempel, Shno Asad, Peter Svedlindh, Christel A. S. Bergström, Korbinian Löbmann, and Alexandra Teleki

Subjects

in situ drug amorphization, oral drug delivery, Materialkemi, Hyperthermia, Induced, Farmaceutiska vetenskaper, superparamagnetic nanoparticles, Excipients, Pharmaceutical Sciences, Solubility, Celecoxib, Materials Chemistry, Humans, Nanoparticles, General Materials Science, Magnetic Iron Oxide Nanoparticles, amorphous solid dispersions, magnetic hyperthermia, Caco-2 Cells, Tablets

Abstract

Superparamagnetic iron oxide nanoparticles (SPIONs) generate heat upon exposure to an alternating magnetic field (AMF), which has been studied for hyperthermia treatment and triggered drug release. This study introduces a novel application of magnetic hyperthermia to induce amorphization of a poorly aqueous soluble drug, celecoxib, in situ in tablets for oral administration. Poor aqueous solubility of many drug candidates is a major hurdle in oral drug development. A novel approach to overcome this challenge is in situ amorphization of crystalline drugs. This method facilitates amorphization by molecular dispersion of the drug in a polymeric network inside a tablet, circumventing the physical instability encountered during the manufacturing and storage of conventional amorphous solid dispersions. However, the current shortcomings of this approach include low drug loading, toxicity of excipients, and drug degradation. Here, doped SPIONs produced by flame spray pyrolysis are compacted with polyvinylpyrrolidone and celecoxib and exposed to an AMF in solid state. A design of experiments approach was used to investigate the effects of SPION composition (Zn0.5Fe2.5O4 and Mn0.5Fe2.5O4), doped SPION content (10-20 wt %), drug load (30-50 wt %), and duration of AMF (3-15 min) on the degree of drug amorphization. The degree of amorphization is strongly linked to the maximum tablet temperature achieved during the AMF exposure (r = 0.96), which depends on the SPION composition and content in the tablets. Complete amorphization is achieved with 20 wt % Mn0.5Fe2.5O4 and 30 wt % celecoxib in the tablets that reached the maximum temperature of 165.2 °C after 15 min of AMF exposure. Furthermore, manganese ferrite exhibits no toxicity in human intestinal Caco-2 cell lines. The resulting maximum solubility of in situ amorphized celecoxib is 5 times higher than that of crystalline celecoxib in biorelevant intestinal fluid. This demonstrates the promising capability of SPIONs as enabling excipients to magnetically induce amorphization in situ in oral dosage forms.