Добірка наукової літератури з теми "NANOMETERIALS"

Fe3O4@β- cyclodextrin magnetic functional nanometerials have been successfullysynthesized and developed as a magnetic solid phase extraction for thedetermination of trace Cu(II) in environmental water samples. The resultsindicate that:adsorption rate is effeceed by pH、temperature、time and capacity .And at pH of 7 and 55°C,the adsorption rate ofβ-cyclodextrin Fe3O4magnetic microspheres to Cu(II) canup to 97%, and static adsorption capacity was 28.51mg/g.Besides,someenvironmrntal samples’s results were satisfacting as recovery is in the rangeof 95.9%-102%.

This study aimed to demonstrate the activity of nanomaterials, the mechanisms of their biosynthesis, methods of measurement, and the factors that roles their biosynthesis by fungi. Moreover, focusing on their impact on host resistance against fungal pathogens. Nanometerials have been considered as one of scientific research priorities due to their new features (melting temperature, binding energy, electronic structure and catalytic activity, magnetic properties, dissolving temperature, and hardness). The performance and efficiency of nanomaterials compared to their normal state has been proven in many fields such as health care, agriculture, transportation, energy, information and communication technology. Many mechanical, chemical and physical methods were implemented to produce nanoparticles, which are considered as unsafe, expensive and environmentally dangerous. Therefore, researchers interested in biosynthesis of nanoparticles using fungi, bacteria or plants systems to make the process environmentally and economically safe. Furthermore, microorganisms such as yeasts, fungi and bacteria efficiency of converting inorganic ions into metallic nanomaterials was well studied. In agriculture, studies have confirmed impact of nanoparticles in improving plant productivity and pathogens resistance in different approaches like direct spraying on plants, soil, and stored fruits in a curative and preventive modes.

A study has been carried out on the Cu doping and PVA capping induced optical property changes in ZnS : Cu nanocrystalline powders and thin film. For this study, ZnS : Cu nanopowders with Cu concentrations of 0.1%, 0.15%, 0.2%, 0.3% and 0.4% are synthesized by the wet chemical method. The polyvinyl alcohol (PVA)-capped ZnS thin film with 0.2% Cu concentration and various PVA concentrations are prepared by the spin-coating method. The microstructures of the samples are investigated by the X-ray diffraction (XRD) patterns and transmission electron microscopy (TEM). The results show that the prepared samples belong to the wurtzite structure with the average particle size of about 3–7 nm. The optical properties of samples are studied by measuring absorption and photoluminescence (PL) spectra in the wavelength range from 300 nm to 900 nm at 300 K. It is shown that the luminescent intensity of ZnS : Cu nanopowders reaches the highest intensity for optimal Cu concentration of 0.2% with the corresponding values of its direct band gap estimated to be about 3.90 eV. While the PVA coating does not affect the microstructure of ZnS nanometerials, the PL spectra of the samples are found to be affected by the PVA concentration as well as the exciting power density. The influence of the polymer coating on the optical properties can be explained by the quantum confinement effect of ZnS nanoparticles in the PVA matrix.

Nanotechnology is the science of designing, producing, and using structures and devices having one or more dimensions of about 100 millionth of a millimetre (100 nanometres) or less. It is going to be a major driving force behind the imminent technological revolution in the 21st century. Private and public sector companies are constantly in synthesizing nanomaterial based products. Nanotechnology has the potential of producing new materials and products that may revolutionize all areas of life. Meanwhile, its opponents believe that nanotechnology may cause serious health and environmental risks and advise that the prophylactic approach should command the blooming and distribution of such products. Nanotechnology pledges for producing novel materials with augmented properties and potential applications (Zeng and Sun, 2008). Nanoparticles and nanomaterials both terms are used interchangeably in scientific literature. However, according to British Standards Institution for the scientific terms: “Nanomaterial is a material with any internal or external structures on the nanoscale dimension, while Nanoparticle a is nano-object with three external nanoscale dimensions. According to the European Commission, nanoparticles can be defined as a natural, incidental or manufactured material containing particles, in an unbound state or as an aggregate or as an agglomerate with one or more external dimensions is in the size range 1 nm – 100nm. The size of nanoparticles is comparable to the size of cell organelles. Nanoparticles can have amorphous or crystalline form and their surfaces can act as carriers for liquid droplets or gases. They have at least one dimension between 1 and 100 nanometers and a narrow size distribution. The nanometric dimensions of these materials make them ideal candidates for surface engineering and functionalization. Due to the development of nanotechnology in recent years, engineered nanoparticles are being used in various fields, particularly in biomedical field. Various physico-chemical properties such as large surface area strength, mechanical, optical activity and chemical reactivity make nanoparticles unique and suitable candidates for various applications. Nanomaterials can be classified into natural and anthropogenic categories based on their origin. Natural sources include volcanic eruptions, forest fires, photochemical reactions, dust storms, etc., while anthropogenic sources include human activities, which can be of two types: Incidental nanomaterials that are generated unintentionally as a result of industrial activities. Combustion from vehicles, cooking, fuel petroleum and coal for power generation (Linak et al., 2000), aeroplanes engines, welding, ore refining and smelting are some of the incidental activities that lead to nanoparticle formation (Rogers et al., 2005). Engineered nanomaterials are designed and created intentionally for producing nanoparticles with specific characteristics. Due to its unusual tunable properties, these materials are widely used in electronics such as semiconductor chips, lighting technologies such as light-emitting diodes (LEDs), lasers, batteries, and fuel electronics etc. Scientists are using nanoparticles to target tumors, in drug delivery systems, and to improve medical imaging. Emerging engineered nanomaterials like quantum dots, nanobranches, nanocages, and nanoshells are presently being used in advance photovoltaic cells, drug delivery nanovehicles, and immunological sensing devices (Kahru and Dubourguier, 2010). Nanomaterials are also classified on the basis of morphology (rod, flower shaped, fiber, sphere and sheet), crystalline mature (amorphous and cristaline), dimension (0D, 1D, 2D, and 3D), and chemical nature (metal, semi-metal and non-metal). There are more than 1800 market products containing nanomaterials, including drugs, food products, food preservatives, clothing, sports items, cosmetics and electronic appliances (Chou et al., 2008; Vance et al., 2015). Nanoparticles are currently being used in biomedicine, bio-imaging, targeted drug delivery, assisted rreproductive technologies (ART), etc. Nanoparticle exposure to humans may be either incidental or accidental or occupational to the natural and manmade nanomaterials. Nanoparticles enter human bodies through inhalation, ingestion and skin, accumulate in the body organs and cause toxic effects on the biological system. The highly activated surfaces of nanoparticles have great potential to induce cytotoxic, genotoxic and carcinogenic activities (Seaton et al., 2010). In-vivo studies specify that the lung, spleen, liver, and kidney are the major distribution sites and target organs for nanomaterial exposure (Wang et al., 2013). They induce localized toxic effects such as cardiotoxicity, hepatotoxicity, nephrotoxicity, etc., in related organs (Du et al., 2013; Yan et al., 2012; Hussain et al., 2005). Several reports have described the adverse effects of nanoparticles on human and animal health, especially in context of reproductive health. The reproductive toxicity of nanoparticles is becoming an important part of nano-science research (Ema et al., 2010). Exposure to nanoparticles adversely affects male reproductive system including both structural and functional aspects. Metallic nanoparticles, generally below 30 nm, owing to their spherical nature and diameter easily cross blood testicular barrier causing considerable toxic changes in the testicular tissue. Hong et al. (2015) reported decreased sperm production in testis accompanied with changes in expression of spermatogenesis regulating genes due to exposure of metallic nanoparticle titanium dioxide (TiO2). A sub-chronic oral exposure of PVP-coated AgNPs to rats resulted in altered testicular histology and sperm morphological abnormalities. In a study, testicular toxicity due to silver nanoparticles was examined in Sprague Dawley rat. The results indicated a significant fall in testosterone level and hike in LH levels. Ultra structural examination revealed vaculations in Sertoli cells and abnormalities in spermatogenic cells, sperm viability and chromatin integrity were also affected adversely (Elsharkawy et al., 2019). Similarly, exposure to zinc oxide nanoparticles resulted in apoptosis in testicular cells and structural changes in seminiferous epithelium and sperm anomalies (Han et al., 2016). Accumulation of copper oxide nanoparticles in testis of mouse may affect sperm morphology (Kadammattil et al., 2018). Spherical shaped nickel nanoparticles of 90 nm size can change motility and decrease FSH and testosterone levels in rats. At higher dose, nickel nanoparticles induced significant structural damage to the testis (Kong et al., 2014). Iron oxide nanoparticles of 20-80 nm size adverse by affected the sperm and Leydig cells in mouse (Nasri et al., 2015). Recent testicular toxicity study conducted by Verma et al. (2022) demonstrated that low, medium and high doses (20, 40 and 80 mg kg-1) of spherically shaped, with an average diameter of 15-20 nm, super paramagnetic IONPs (Fe3O4) injected intra-peritoneally decreased sperm counts and motility in spermatozoa. With respect to the effects due to non-metallic or semi-metallic nanoparticles having different shapes, different outcomes have been reported. A study conducted by Nirmal et al. (2017) on Wistar rat, exposed to 2.0 and 10.0 mg kg-1 bwt doses of OH-f MWCNTs resulted in sperm dysfunction and degeneration in seminiferous tubules (Nirmal et al., 2017). In another study by the same group, Wistar rat exposed to high doses of nanoscale graphene oxide (NGO) intra-peritonially, showed reduced sperm motility and total sperm count and increased sperm abnormalities (Nirmal et al., 2017). It is thus apparent that nanoparticles have a considerable negative impact on testicular tissue including damage to Leydig cells, Sertoli cells, spermatogenesis and sperm quality. Various studies have revealed that the testicular toxicity is caused due to combination factors. Oxidative stress is a key factor responsible for nanoparticle mediated damage. It becomes more harmful, especially to the testes because of high metabolism, continuous sperm production and presence of high amount of unsaturated fatty acids (Aitken and Roman, 2008). With the expansion and production of nanometerials for industrial and medical applications, exposure chances are also increasing. Many research reports have documented the adverse effects of nanoparticles on animals and environment. The major concern with the widespread use of NPs is their toxicity to living cells. Therefore, alleviating or reducing NPs toxicity remains much coveted goal for researchers around the globe. It is the alertness and scientific awareness which can prevent these materials from becoming bane instead of boon for humanity. This editorial is written as a tribute to my beloved teacher Dr. R. C. Dalela who has been my mentor since 1985, when I was student of M.Sc. Zoology (1985-1987) and Ph.D (1987-1993) in D.A.V. P.G. College, Muzaffarnagar. He has played a vital role in moulding my career, from an average post-graduate student to the academician and a researcher I am today. I deeply cherish his guidance, encouragement and support. It was my privilege to meet him last November, so close to his sudden demise. The values inculcated by him continues to inspire me in my onward journey. I have been associated with JEB for the past 25 years as a reviewer and an Associate Editor. The articles published in this journal receive good citations, which reflect the popularity of this open access journal among the researchers of Environmental Biology and Toxicology. I must appreciate the present editorial team headed by Professor Divakar Dalela for their efforts in maintaining the standard of this journal. I wish all success and my sincere co-operation for the same in the coming years.

Determination of particles size is important in pharmaceutical research and manufacturing of drug delivery system in nano scale. This study was carried out to evaluate particles size of nano polymer particles, composed of Eudragit RL 100, and nano liposomes, composed of hydrogenated soy phosphatidylcholine and cholesterol. Dynamic light scaterring was used to determine nano particles size. The results showed that, dilution ratio influenced differently on the determined nanoparticles. Liposomal suspension, which was diluted to count rate less than 170 kcps, had statistically significant larger particle than that, which had greater count rate. Polymer particles, which were diluted to count rate less than 126 had statistically significant larger particles than that, which had greater count rate. Keywords Particle size, nano polymer particle, nano liposomes, dynamic light scattering (DLS). References [1] E.H.M. Sakho, E. Allahyari, O.S. Oluwafemi, S. Thomas, and N. Kalarikkal, Dynamic Light Scattering (DLS) in: Thermal and rheological measurement techniqus for nanometerials characterization, Elsevier, Europe 2017.[2] V.X. Minh, P.T.M. Hue, Applications of nanotechnology and liposomes in Pharmaceuticals and cosmetics, Medical publishing house, Hanoi, 2013 (in Vietnamese).[3] ISO 22412:2017, Particle size analysis - Dynamic light scattering (DLS).[4] J. Panchal, J. Kotarek, E. Marszal, and E.M. Topp, Analyzing Subvisible Particles in Protein Drug Products: a Comparison of Dynamic Light Scattering (DLS) and Resonant Mass Measurement (RMM), AAPS J., 16(3) (2014) 440–451. http://doi.org/ 10.1208/s12248-014-9579-6.[5] A. Chaudhury et al, Lyophilization of cholesterol-free PEGylated liposomes and its impact on drug loading by passive equilibration, Int. J. Pharm., 430(1–2) (2012) 167–175. https://doi.org/10.1016/j.ijpharm.2012.04.036.[6] T. Ishida, H. Harashima, and H. Kiwada, Liposome clearance, Biosci. Rep., 22(2) (2002) 197–224. https://doi.org/10.1023/A:1020134521778.

Introduction The work presented in the thesis focused on zero-dimensional II-VI semiconductor-based luminescent materials, including zinc-based un-doped and transition metals doped/co-doped luminescent nanoparticles. The chapter mainly gives a brief introduction to the nanomaterials and classifications based on the confinement of the system. Also, it introduces 0-D II-VI semiconductor quantum dots, specifically zinc selenide quantum dots (ZnSe QDs) and their properties, as well as focused on important applications of these materials in various sensing areas purposes, like hazardous toxic heavy metals, explosive compounds and temperature sensors. 1.1 Nanomaterials Physics and chemistry have experienced significant development in the nanometer size range, leading to a new interdisciplinary field of nanoscience in the last decade. The attention in nanoscale materials increases because many physical phenomena occur at a length scale between 1 and 100 nm in both organic and inorganic materials. Nanoparticles are microscopic particles having a dimension below 100 nm at least in one direction. A drastic change in the various properties of materials is observed as nanoscale size is achieved and a significantly high number of loosely bonded atoms present at the material surface. Numerous size-dependent properties are detected in nano regime such as super paramagnetism in magnetic substances, quantum confinement in semiconductor particles and surface plasmon resonance in some metal particles [1]. Typically, nanoparticles have possessed excellent and unpredictable optical properties due to the applicability of quantum effects which arises because of 2 sufficiently small confinement of their electrons. When one or more than one dimension of a material is reduced to the nanoscale, its physicochemical properties are remarkably changed from the bulk counterpart. With the size reduction, novel optical, magnetic, chemical, mechanical and electrical properties can be introduced. Then, the resulting size-reduced systems are called low-dimensional systems. In the low-dimensional structures, the confinement of particles, i.e., electrons or holes, leads to the manifestation of size effects and dramatic changes in the properties or behaviour of the materials, which generally comes into the quantum-size effects [2]. Nanostructures play the role of bridge between the molecules and bulk materials. Nanostructures can lead to new technologies and devices by suitable control of the properties and responses.

Recently, carbon dots have gained a prosperous interest due to their versatile applicability in the field of optoelectronics, biomedicine, sensing and catalysis. Low-toxicity, high photostability, high aqueous solubility of carbon dots make it a perfect alternative over traditional quantum dots. The origin of photoluminescence property is not clearly understood yet. It is believed that the conjugated core and the surface groups are responsible for the fluorescence property. These materials are promising for optoelectronic applications because of their electron accepting and donating properties. Therefore, we develop various synthesis methods for luminescent carbon dots and understand the origin and tuning of optical properties by using spectroscopy. Then, various carbon dots based hybrid nano-composites are designed to find out their potential applicability in energy transfer based light harvesting systems and photovoltaics.
Research was conducted under supervision of Prof. Amitava Patra
Research was carried out under the CSIR fellowship and grant