Nanotechnology developments have resulted in the emergence of many forms of pharmaceutical products like Nanoemulsions, Nano micelles, Nano sponges and Nano niosomes. In recent years, through nanotechnology, Nano sponges (NS) has acquired remarkable strength in drug delivery. Later, as they effectively overcome the problems like increasing the solubility of water-insoluble drugs, increasing bioavailability, reducing drug toxicity, avoiding drug degradation and targeting the drug to a specific site, which offers controlled drug delivery for topical use. They can also be used as a carrier as biocatalysts for vaccines, enzymes, proteins and antibodies. Nano sponges are better than micro sponges because the diameter of Nano sponge is below 1μm and the diameter of the microsponge is 10-25μm with the void size around 5-300μm, thereby decreases side effect and protect the drug from degradation. This review study to expound the characteristics of β-cyclodextrin based Nano sponges like factors affecting the formation of Nano sponges, applications in topical formulation and comparison of different marketed products of Nano sponges along with cyclodextrin in various drug delivery and offer high drug loading compared to other Nanocarriers
Objective:The aim of the present study was to increase the dissolution rate of glibenclamide (GLIB) by molecular dispersion of drug in the polymeric matrix of Pluronic F-127.Methods: GLIB-loaded solid dispersions were formulated by fusion method. The formulated solid dispersions were characterized for scanning electron microscopy (SEM), X-ray diffractometry (XRD), differential scanning calorimetry (DSC), and evaluated for percentage yield, drug content, solubility, and in vitro dissolution profile, and stability studies were conducted as per International Conference on Harmonisation guidelines Q1A in stability chamber, both at intermediate and accelerated conditions. Results: Both XRD and DSC studies suggested that crystalline GLIB was converted to amorphous form after loading into carrier. SEM studies revealed that the prepared solid dispersions were in the form of irregular particles with the absence of crystalline material. Due to this conversion of crystalline to amorphous state, formulated solid dispersions had shown improved dissolution rate profile of GLIB and stability studies suggested that formulated solid dispersions showed no significant changes in appearance and also in drug content. Conclusion:Thus, from the obtained results, it can be concluded that dissolution profile of GLIB can be improved by formulating as solid dispersion.
Objective: The main objective of the study was to formulate the oral disintegrating films loaded with atenolol by solvent-casting method and to carry out its evaluation studies.Methods: The films were prepared using the film-forming hydrophilic polymer like hydroxypropyl methylcellulose (E-5) and super disintegrant like pectin in various proportions.The formulated oral films were characterized for Fourier transform infrared (FTIR) and morphological evaluations. Various physicochemical parameters such as weight variation, folding endurance, surface pH, in vitro disintegration, and in vitro dissolution studies were carried out.Results: FTIR studies revealed that there was no drug-polymer interaction. The morphological evaluation of films showed that all the films were homogenous and transparent. The folding endurance test ensured that the films had sufficient brittleness and by weight variation test, it was inferred that all the films were within the deviation. The surface pH study showed the pH of the films was around neutral pH. The drug was well distributed in all the films. The films disintegrated within 120 s and the fastest being disintegrated in 30 s. Based on all the evaluation parameters, F6 had shown optimal performance and remarkable increase in drug release of 94.38% in 2 min.Conclusion: Thus, formulated oral disintegrating films can be termed as an alternative approach to deliver atenolol.
Reactive Oxygen Species (ROS) is considered as the main factor of the Free Radical theory of aging over centuries and it indicates the pathophysiology of aging in mammals. ROS causes oxidative stress, which is a major component in the aging process of higher organisms. ROS also leads to many age-related diseases such as cancer, cardiovascular disease, diabetes, etc. ROS causes damage to most of the biological membranes that cause these chronic diseases. Enhanced ROS levels at the cellular level lead to cellular senescence. It is a stage of cells where growth arrest happens associated with the secretion of Senescence-associated secretory phenotype (SASP) factors. Senescence maintains tissue homeostasis, functions in normal development and restricts tumor development. In this regard, recent experimental evidence has shown that the genetic or pharmacological ablation of senescent cells extends the life span and improves the healthspan. Here, we review the cellular and molecular links between cellular senescence and aging and discuss the novel therapeutic avenues that this connection opens.
Wound can be defined as any process which leads to the disruption of the normal architecture of a tissue. They may be closed or open, for example, abrasions, lacerations, avulsions, ballistic and excised, or surgical wounds. Successful wound care includes advancing patient local and systemic conditions in conjunction with a perfect injury healing condition. Numerous wide assortments of dressing materials are accessible both for extreme and persistent non-healing wounds. A wide range of wound healing products have been produced to impact this injury condition to give a non-pathogen, ensured, and clammy region for healing to happen. A perfect injury dressing ought to limit loss of protein, electrolytes, and liquids from twisted and to diminish pain and contamination alongside wound healing. More current products are as of now being utilized to supplant or enlarge different substrates in the injury healing period. There is a sharp complexity to prior routine of wound administration, where the injury is permitted to dry, yet the present advancement was to move forward to the idea of wet injury recovering. This review of the present wounding periphery in wound recovery occurs at the most recent utilizations of silver and the employments of negative pressure wound gadgets, propelled dressings and skin substitutes, and biologic injury items including development of hydrogels and hyperbaric oxygen as an aid in wound mending. With the advancement of accessible dressings, the objective is to locate the most proper methodology or blend of modalities to optimize wound healing.
Objective: The importance of this research work is to design a library of novel coumarin derivatives by docking evaluation of the designed coumarin derivatives as squalene synthase inhibitor.Methods: The three-dimensional structure of designed molecules of squalene synthase inhibitors was collected from Protein Data Bank. The designed molecules were docked onto the enzymes that are squalene synthase inhibitor - 3WCM, 3WCJ, and 3Q2Z protein using SYBYL-X 2.1. Using a standard protocol, the protein was subjected to minimization and protomol generation.Results: By this method, we visualized the possible binding and also estimated the protein interactions with our intended coumarin library, using SYBYL-X 2.1 software. Into the active site of the selected enzymes, all the 20 coumarins were docked and then the docking scores revealed that the compounds possess high affinity toward the selected enzymes.Conclusion: With the help of virtual evaluation, we have elaborated a fast synthetically accessible coumarin-based compounds, and it is an advanced and original scaffold in the area of probable human squalene synthase inhibitors. Some of the developed compounds show better binding property than ligand, and in 3q2Z, the compound 5d shows better binding property than the protein. Furthermore, 6g and 6c have good binding property. In 3 WCM, the compound 6f has better property. In 3 WCJ, the compounds 6g and 6f show better binding property than the protein.
Objective:The objective of the present research was to develop fixed-dose combinations for the treatment of dyslipidemia, associated with type-II diabetes mellitus for improvement of glucose tolerance. Methods:Multiple unit pellet systems (MUPSs) consisting immediate release atorvastatin calcium pellets and sustained release glibenclamide were formulated by spheronization technique. The characterization of formulated pellets was done by Fourier transform infrared (FT-IR) and differential scanning calorimetry (DSC) studies, and formulated pellets were evaluated for solubility, viscosity, pH, and in vitro studies.Results: From FT-IR and DSC studies, it was confirmed that no chemical interaction existed between the drug and the natural polymers used. Solubility of glibenclamide was found to be 4.38 and 18.24 and atorvastatin calcium was found to be 6.84, 214.67, and 287.43 g/L. The viscosity of 1% w/v of locust bean gum, guar gum, and ghatti gum was found to be 169 cP, 124 cP, and 31 cP in distilled water. The pH of locust bean gum, guar gum, and gum ghatti solutions was found to be 5. 6±0.49, 5.2±0.27, and 4.7±0.51. The in vitro studies suggested that glibenclamide pellets had shown a sustained release till 12 h, while atorvastatin calcium had shown immediate release of drug due to rapid disintegration of pellets. Conclusion:Thus, MUPS can be considered as an alternative approach to treat diabetes induced dyslipidemia.
Objective: The present research is to formulate Glimepiride and Atorvastatin Calcium Nanoparticles for the type-2 diabetes mellitus for improvement of glucose tolerance associated with dyslipidemia formulated by liquid antisolvent precipitation technique. Method: Glimepiride nanoparticles and atorvastatin calcium nanoparticles were prepared by using a liquid antisolvent precipitation technique. Solvent to antisolvent ratio used was 3.5:6.5 and 2.5:7.5 and the drug concentration used was 40 mg/ml and 60mg/ml respectively. Result: The XRD was determined, the data of the optimized Glimepiride formulation revealed that the prepared nanosized Glimepiride powder was existed in crystalline form. The percent yield for the formulations of Glimepiride and atorvastatin calcium nanoparticles was found to be 72.8±1.8%, 75.3±2.2% respectively. In-vivo studies in albino wistar rats demonstrated that the Cmax and AUC0−24h of optimized Glimepiride and atorvastatin calcium nanosized formulation was found to be 24451.14±2170.5 ng/ml, 162945.12±241.5 ng/ml and 1385.43±153.3 ng/ml,3636.57±65.2 ng/ml respectively. Dissolution study of optimized formulations shows that marked enhancement of dissolution rate. The stability studies of mixture of Glimepiride and atorvastatin calcium powder when stored at 4±3oC refrigerated temperature has shown no significant changes in physical appearance, drug content, particle size and PDI. Conversely the sample stored at room temperature has shown significant increase in particle size and PDI, with no significant changes in drug content and physical appearance. Conclusion: The Formulation of glimepiride and atorvastatin calcium drug nanoparticles shows increase in the surface-to-volume ratio of API, resulting in better drug solubility and hence increasing the bio-availability when compared to its pure form.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.