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- Volume 20, Issue 4, 2024
Current Nanoscience - Volume 20, Issue 4, 2024
Volume 20, Issue 4, 2024
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Recent Development and Advancement in Quantum Dots in Pharmaceutical and Biomedical Fields for the Delivery of Drugs
Authors: Pranjal K. Singh, Smita Singh, Kapil Sachan, Vikrant Verma and Sakshi GargNanoscale semiconductors known as quantum dots (QDs) are essential for drug testing because they bridge the gap between nanotechnology and the testing of drugs. QDs are a valuable tool in theranostics and treatment because of their unique physicochemical features. Due to their photoluminescence and electronic properties, including broad and continuous absorption spectra, narrow emission spectra from visible to near-infrared wavelengths, and long-lasting and high brightness, they are suitable probe materials for use in (bio)sensing (immunological) platforms. Several studies use QDs due to their optical, magnetic, electrical, photochemical, and biological features that allow them to be employed in various scientific domains. When utilized in drug delivery systems, fluorescent markers, such as QDs, can track the metabolism of drugs in the human body. Many medicinal applications, such as disease diagnosis and medication research, can benefit from these fluorescent tests. In this review article, the application of QD in drug delivery and immunoassay sensing has been described in detail.
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An Insight into Enhanced Roles of Plant and Microbial Nanobionics
Authors: Theivasanthi Thirugnanasambandan and Subash C.B. GopinathPlant nanobionics is an interdisciplinary field of science with the concepts of plant biology and nanotechnology applied. The field is in the developing stage with various applications, including photosynthesis enhancement, light-emitting plants, sensors, and energy harvesting from plant organelles. For instance, advanced nanomaterials like carbon nanotubes are inserted in plant tissues to achieve various functions. The photosynthesis process can be enhanced by improving light absorption using single-walled carbon nanotubes that are impregnated in the leaves of plants. Plants are able to emit light when various nanostructures are encapsulated inside. Plant fuel cells can be constructed by embedding nanomaterials in the plant organelles for energy generation. On the other hand, various sensing devices have been developed for agriculture using plant nanobionics, which detect pollutants, toxic chemicals, and soil moisture. These devices are expected to be superior to the conventional sensors used in agriculture. Apart from that, microorganisms can be used as catalysts for energy generation and wastewater treatment in microbial fuel cells. In this study, microbial nanobionics are discussed for the nanomaterials coated on the electrodes of a microbial fuel cell to improve electron transfer and biofilm formation.
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An Extensive Review of MR Sensors with Design and Characteristic Evaluation of Three-layered TMR Sensor
Authors: Subramanian V. Gayathri and Durairaj SubbulekshmiThe reliability and efficacy of sensor-based automated systems have improved due to the proliferation of electric vehicles, renewable sources, and integrated systems in power industries extensively. This has been accomplished by increasing the power density and decreasing the volume of the system. Background: Mathematical estimation and comparative analysis of the physical factors result in massive usage of operational matrices measured using sensors. Magnetic field sensors, used in industries and biomedical applications, have a high level of precision in the evaluation of measurements. In order to extract the measured parameters such as sensitivity, accuracy, operating cost, the linear range of operation, and power utilisation, these sensors adhere to the physical constraints during their nominal working conditions. The characteristics of the aforementioned sensors are enumerated in detail in this article. Objective: This objective is highly focused on providing a comprehensive overview of classification and the properties of Hall-Effect, anisotropic magnetoresistive (AMR), giant magnetoresistive (GMR), and tunnelling magnetoresistive (TMR) sensors. The dissertation on its properties concludes that TMR is more reliable and sensitive in variable operating conditions. Methods: The methods for selecting the sensors for an application are confined to voltage fluctuations and sensitivity. A three-layered TMR sensor with two magnetic layers and an insulator in between is proposed as a significant advancement compared to the literature. The micromagnetic simulation is carried out at room temperature for a three-layered TMR made up of neodymium alloy, magnesium oxide, and cobalt platinum alloy. Conclusion: Based on the studies executed, it is determined that TMR is more sensitive than both conventional and MR sensors. The proposed schematic claims that the higher free layer thickness offers maximum sensitivity with 77% negative magnetoresistance. The reduced coercivity of 1.9Oe is achieved in this combination at a specified temperature range.
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Review of Carbon Nanotube Field Effect Transistor for Nanoscale Regime
Authors: Mehwish Maqbool and Vijay K. SharmaBackground: The need for high performance, small size, low delay, low power consumption, and long battery backup of portable systems is increasing with the advancement of technology. Many features of portable systems can be improved using scaling methods. In the scaling process, reducing the size of devices causes serious difficulties, including the short channel effect (SCE) and leakage current, which degenerates the characteristics of the systems. Objectives: In this review paper, a trending carbon nanotube field effect transistor (CNTFET) technology is discussed in detail. CNTFET can replace the conventional metal oxide semiconductor field effect transistor (MOSFET) technology to overcome the SCE problems in the nanoscale regime and also meet the requirements of portable systems. Methods: The CNTFET is an extremely good nanoscale technology due to its one-dimension band structure, high transconductance, high electron mobility, superior control over channel formation, and better threshold voltage. This technology is used to construct high-performance and low-power circuits by replacing the MOSFET technology. CNTFET in comparison to MOSFET takes the carbon nanotube (CNT) as a channel region. Results: The value of threshold voltage in CNTFET changes with the diameter of CNT. The threshold voltage of the devices controls many parameters at the circuit-level design. Hence, the detailed operation and the characteristics of CNTFET devices are presented in this review paper. The existing CNTFET-based ternary full adder (TFA) circuits are also described in this review paper for the performance evaluation of different parameters. Conclusion: CNTFET technology is the possible solution for the SCE in the nanoscale regime and is capable to design efficient logic circuits. The circuits using the CNTFET technology can provide better performance and various advantages, including fast speed, small area, and low power consumption, in comparison to the MOSFET circuits. Thus, CNTFET technology is the best choice for circuit designs at the nanoscale.
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The Pharmaceutical Role of Silver Nanoparticles in Treating Multidrug- Resistant Bacteria and Biofilms
Background: According to the WHO, antimicrobial resistance has recently become worrisome and constitutes an international public health crisis. The advent of multidrug-resistant bacteria has been implicated in the rise in morbidity and death caused by microbial diseases. However, the lack of new and effective antibiotics has been associated with the emergence of drug resistance. This has resulted in worldwide endeavors to advance innovative drugs with higher efficiency and more sophisticated drug delivery technologies. In addition, the utilization of nanoparticles as innovative biological substances is considered a worldwide issue of interest. Nanoparticles have the potential to become a vital and viable treatment alternative for treating drug-resistant illnesses. Nanoparticles contain metallic substances and their oxides, which have the highest possibility among all nanoparticles and have piqued the curiosity of numerous experts. Furthermore, using silver nanoparticles in photothermal treatment has attracted much interest. Purpose: This review includes knowledge about the problems of drug resistance and the mechanism of action of silver nanoparticles. Results: This review comprehensively assesses the current discoveries for using silver nanoparticles as antimicrobial medicines in infections caused by resistant microorganisms. Also being explored as nanomaterials that can react with light (photothermal treatment) to destroy bacteria and promote improved medication administration and release. Furthermore, it focuses on the synergy between nanoparticles with antimicrobial action and other nanoparticles, microbial adaptation mechanisms to nanoparticles, and existing obstacles and future possibilities that were thoroughly examined.
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Recent Trends in Application of Memristor in Neuromorphic Computing: A Review
Authors: Saswat Panda, Chandra Sekhar Dash and Chinmayee DoraRecently memristors have emerged as a form of nonvolatile memory that is based on the principle of ion transport in solid electrolytes under the impact of an external electric field. It is perceived as one of the key elements to building next-generation computing systems owing to its peculiar resistive switching characteristics. The switching mechanism in a memristor is mainly governed by filamentary conduction. Further, it can be employed as a memory as well as a logic element, which makes it an ideal candidate for building innovative computer architecture. Moreover, it is capable of mimicking the characteristics of biological synapses, which makes it an ideal candidate for developing a Neuromorphic system. In this review to begin with the switching mechanism of the memristor, primarily focusing on filamentary conduction, is discussed. Few SPICE models of memristor are reviewed, and their critical comparison is performed, which are widely used to build computing systems. An in-depth study on the various crossbar memory architecture augmented with memristors is reviewed. Finally, the application of memristors in neuromorphic computing and hardware implementation of Artificial Neural Networks (ANN) employing memristors is discussed.
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Metal and Metal Oxide Nanoparticles as Agents Against Human Infectious Viruses
Viral infections remain to be a serious threat to public health on a global scale. Recent outbreaks of viral infections have highlighted the urgent need for novel antiviral treatments. The recent development of metal/metal oxide nanoparticles for the treatment of various pathogenic viruses has received significant attention. There are established mechanisms of action for metal/ metal oxide nanoparticles that can occur inside and outside host cells. These mechanisms include the interaction of nanoparticles with viral receptors, interference with viral attachment, interaction with the viral genome, inactivating virus particles prior to cellular entry, and interaction with viral replication factors. In this article, we attempted to present a comprehensive review of all published research on using metal/metal oxide nanoparticles against human infectious viruses and their antiviral modes of action.
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Nano-drug-based Targeted Therapy Alleviates Ferroptosis-induced Liver Toxicity
Iron is an essential inorganic element for an organism, with several metabolic activities. The glycoproteins ferritin and transferrin, which assist in carrying iron to various body parts, are used to store iron. In terms of iron uptake, storage, and excretion, equilibrium should be preserved. Ferroptosis is an iron-dependent form of cell death with traits like lipid peroxidation buildup and ROS generation. It is distinct from other forms of cell death visually and biochemically. Many cancer cells block ferroptosis by controlling different cell survival pathways. Compared to healthy, normal cells, cancer cells are more dependent on iron. A subgroup of tumor cells known as cancer stem cells has stem-like characteristics. These are in charge of metastasis and recurrence. The liver plays a significant part in the body's detoxifying process and is the primary iron storage organ. Numerous liver disorders are frequently accompanied by excessive iron accumulation. Due to excessive iron deposits, the liver is more vulnerable to oxidative damage, which can occasionally result in liver failure. Chemotherapy, which involves administering several medications to treat cancer, may be hazardous to the body's other cells. The ferroptosis condition and high iron accumulation can potentially impair liver function. A tailored drug delivery method may ameliorate the impact of excessive iron accumulation and favorably correlate with liver damage, consequently enhancing liver function.
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Effect of Nanostructure Morphology and Concentration on the Piezoelectric Performance of Flexible Pressure Sensor based on PVDFTrFE/ Nano-ZnO Composite Thin Film
Authors: Yurong Liu, Xiaolong Zeng, Lin Zhu, Cong Wang, Kuiwei Geng and Ruohe YaoBackground: The development of high-performance piezoelectric pressure sensors with outstanding sensitivity, good linearity, flexibility, durability, and biocompatibility is of great significance for smart robotics, human healthcare devices, smart sensors, and electronic skin. Thus, considerable progress has been achieved in enhancing the piezoelectric property of PVDF-TrFEbased composite pressure sensors by adding various ZnO nanostructures in PVDF-TrFE polymer acting as a nucleating agent and dielectric material. Aims: In this work, flexible pressure sensors with a sandwich structure based on PVDFTrFE/ nano-ZnO composite sensing film were fabricated using a simple spin-coating method and post-annealing process, while electrospinning and high-voltage polarization processes were not adopted. Methods: Poly (vinylidene fluoride-trifluoroethylene) (PVDF-TrFE)/nano-ZnO composite films were prepared via spin coating to fabricate flexible piezoelectric pressure sensors. ZnO nanoparticles (ZnO NPs), tetrapod ZnO (T-ZnO) and ZnO nanorods (ZnO NRs) were used as nano-fillers for piezoelectric PVDF-TrFE, to enhance the beta-crystal ratio as well as the crystallinity of PVDF-TrFE. The structural and surface morphologies of the composite films were investigated using Fourier transform infrared spectroscopy (FT-IR), X-ray diffraction (XRD) and scanning electron microscopy (SEM). Results: Among three different types of ZnO nanostructures with a concentration range (0-7.5 wt%), the sensor with 0.75 wt% ZnO NRs nanofiller exhibits a maximum output voltage of 1.73 V under an external pressure of 3 N and a maximum sensitivity of 586.3 mV/N at the range of 0-3 N. Further, the sensor can generate a clear piezoelectric voltage under bending and twisting deformation as well as compression and tensile deformation. Conclusion: To summarize, the addition of different concentrations of nano-ZnO can remarkably improve the piezoelectric performance of the composite sensor, and ZnO NRs can achieve better piezoelectric properties of the sensor as compared to ZnO NPs and T-ZnO. In addition, the sensor with 0.75 wt% ZnO NRs as nanofiller has the highest piezoelectric response, which is about 2.4 times that of the pure PVDF-TrFE sensor. It is demonstrated that the sensor has great potential applications in wearable health monitoring systems and mechanical stress measurement electronics.
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Self-nano-emulsifying Drug Delivery Systems of Atorvastatin Calcium Liquid Filled in Hard Shell Capsules for Improved Oral Bioavailability in Rabbits
Authors: Khushwant S. Yadav, Shivani Arora, P. S. Yasaswi, Prabhuti Nirale, Anita Solanki and Jnanadeva BhatAims and Objectives: Atorvastatin calcium (ATR) is a BCS class II drug showing poor bioavailability due to limited aqueous solubility. In the present study, a self-nano-emulsifying drug delivery system (SNEDDS) was developed and formulated as a liquid filled in a hard shell capsule to improve the bioavailability of ATR. Methods: Different oils were screened through the saturated stability method, and the amount of ATR solubilized in the respective oils was analysed through HPLC at 245nm. A ternary phase diagram was plotted to obtain the optimized ratio of oil, surfactant, and co-surfactant to formulate SNEDDS. The prepared ATR SNEDDS was filled into hard shell capsules, band sealed, and subjected to various evaluations like disintegration time, self-emulsification time, precipitation time assessment, globule size analysis and zeta potential. Then the in vitro dissolution studies were carried out. The optimized SNEDDS formulation was filled in a hard shell capsule, and in vivo studies were performed on rabbits to compare the pharmacokinetic parameters with the marketed formulation and pure ATR. Results: Capmul MCM as the oil component showed five-fold solubility of ATR and was selected for the preparation of ATR-SNEDDS. The SNEDDS formulation showed an entrapment efficiency of 89.76±4.1% ATR with a globule size of 385±1.9 nm and an emulsification time of 5 seconds. It was established from the study that liquid ATR-SNEDDS had relative bioavailability enhanced by 1.7 times in comparison to the marketed formulations (Lipvas) and 4.8 times with respect to pure ATR. Conclusion: From the study, it was concluded that the bioavailability of ATR was enhanced by formulating ATR as Liquid SNEDDS filled in hard shell capsules.
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Monocomponent Biosorption of Copper Ions (II) onto Nanocrystalline Cellulose from Coconut Husk Fibers
Introduction: Nanocrystalline cellulose (NCC) is one of the most suitable cellulose derivatives for the treatment of wastewater. Various agricultural wastes have been used for the extraction of NCC. Coconut wastes have been widely studied as potential adsorbents for the removal of pollutants, including dyes and heavy metals. Methods: In this work, nanocrystalline cellulose (NCC) was successfully isolated from coconut husk fibers through alkaline pretreatment accompanied by sulfuric acid hydrolysis. Then, the ability of NCC to adsorb Cu2+ from aqueous solution in batch studies was investigated. Results: Results indicated that the optimal hydrolysis parameters were achieved at 50° C for 45 min with 64% sulfuric acid to extract NCC as rod-like particles with diameters between 4-10 nm. The potential of NCC as a biosorbent to remove copper ions (Cu2+) from aqueous solution was investigated in terms of batch mode and maximum adsorption capacity (qm) of 79.491 mg/g of Cu2+. The adsorption efficiency of Cu2+ions increased with an increase in the adsorbent dosage, decreased with an increase in the initial concentration of contaminant, and increased with the contact time. Under optimal conditions, adsorption kinetic followed a pseudo-second-order kinetic model and the adsorption isotherm fitted most closely with the Langmuir model. Conclusion: According to a literature review, NCC from coconut husk fibers has not been used for the adsorption of heavy metals, mainly copper ions. This study shows that NCC from coconut husk fibers can be used as a low-cost and environmentally friendly adsorbent for the removal of Cu2+ from aqueous solutions.
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Volumes & issues
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Volume 20 (2024)
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Volume 19 (2023)
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Volume 18 (2022)
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Volume 17 (2021)
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Volume 16 (2020)
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Volume 15 (2019)
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Volume 14 (2018)
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Volume 13 (2017)
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Volume 12 (2016)
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Volume 11 (2015)
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Volume 10 (2014)
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Volume 9 (2013)
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Volume 8 (2012)
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Volume 7 (2011)
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Volume 6 (2010)
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Volume 5 (2009)
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Volume 4 (2008)
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Volume 3 (2007)
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Volume 2 (2006)
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Volume 1 (2005)