DEVELOPMENT AND VALIDATION OF HIGH-PERFORMANCE THIN LAYERCHROMATOGRAPHIC METHOD FOR CIPROFLOXACIN BY QUALITY BY DESIGN APPROACH

Objective: The aim of this paper is to create a new, systematic high-performance thin-layer chromatography (HPTLC) method for ciprofloxacin that is based on quality by design (QbD). Methods: The mobile phase was chloroform: IPA: H2O: Formic Acid (2:7:0.5:0.5V/V), and the chromatographic separation was performed on aluminum-backed silica gel 60 F254 plates. Ciprofloxacin was detected using UV light at 278nm. In factor screening studies, a 3-factor 17-run standard 3-level factorial design was used, and a Box-Behnken design was used to optimize HPTLC experimental parameters for obtaining anticipated chromatographic conditions. The basic method parameters were tested to understand risk assessment. Three independent parameters, such as saturation time, band duration, and migration distance, were chosen and analyzed based on the risk assessment to see if these three parameters influenced the responses. For ciprofloxacin, the method produces a compact and well-resolved band at Rf = 0.40 0.02. In the linear regression analysis performed on ciprofloxacin, the regression coefficient was found to be r2 = 0.996. Results: According to the International Council on Harmonization (ICH) guidelines, it was validated for validation parameters such as accuracy, precision, robustness, the limit of detection, and the limit of quantification. The proposed method for ciprofloxacin determination was found to be straightforward, precise, reliable, stable, and sensitive. Conclusion: The QbD method produced a more robust method that can generate accurate, high-quality, and reliable data during the process, and it can be effectively used in the routine inspection of Ciprofloxacin in the tablets dosage form

Stable Field Emission from Layered MoS2 Nanosheets in High Vacuum and Observation of 1/f Noise

Field emission and current noise of hydrothermally synthesized MoS2 nanosheets are investigated in ultra-high-vacuum and industrially suited high-vacuum conditions. The study reveals that the emission turn-on field is pressure dependent. Moreover, the MoS2 nano‐sheets exhibit more stable field-electron emission in high- vacuum than in ultra-high-vacuum conditions. The investigations on field-emission current fluctuations show features of 1/f-type noise in ultra-high-vacuum and high-vacuum conditions, attributed to adsorption and desorption processes. The post-field-emission results indicate the MoS2 nanosheets are a robust field emitter in high-vacuum conditions

A overview: non-steroidal anti-inflammatory drugs and mechanisms

The inflammatory response represents a generalized response to infection or tissue damage and is designed to remove cellular debris, to localize invading organisms and arrest the spread of infection. NSAIDS are metabolized primarily in the liver. They vary in their half-lives and bioavailability. Given the multitude of available NSAIDs, the variability of their half-lives allows for different dosing regimens. The fluid in the inflamed area is known as inflammatory exudates, commonly called as pus. These exudates contain dead cells and debris in addition to body fluids. The inflammatory response is characterized by the following symptoms: Reddening of the localized area, swelling, pain and elevated temperature. Reddening results from capillary dialation that allows more blood to flow to the damaged tissue. Elevated temperature results from capillary dialation which permits increased blood flow through these vessels, with associated high metabolic activities of neutrophils and macrophages. The release of histamine from mast cells during antigen antibody reactions is well known, as is its involvement in the inflammatory response to skin injury. The present review focused on list and precautions of NSAID with its typed and classification, Analgesic activity study, histamine

Microcalorimetric studies to determine the enthalpy of solution of diclofenac sodium, paracetamol and their binary mixtures at 310.15 K

A sensitive and selective microcalorimetric technique has been used to determine the enthalpy of solution of diclofenac sodium (DS), paracetamol (PC) and their binary mixtures over a wide range of composition in the pH range 4-12. The systems showed endothermic behavior. The molar enthalpies of solutions of DS vary between 42.26± 0.16 and 50.48± 0.03 kJ mol-1 at pH 4-9 and for PC from 24.28± 0.05 to 36.03± 0.01 kJ mol-1 at pH 5-12. The excess molar enthalpy of their mixtures has also been determined. The values of excess molar enthalpy of solutions are negative and very low in magnitude indicating no specific interaction between DS and PC in solution

Characterization and quantification of amorphous content in some selected parenteral cephalosporins by calorimetric method

Amorphous content of a crystalline drug affects its physical and chemical properties as well as its performance. Consequently it is important to assess the extent of amorphous contents in pharmaceuticals. The present study utilizes the technique of solution calorimetry to quantify the percentage of crystallinity in samples of varying amorphous content in cefazolin sodium monohydrate, ceftriaxone sodium, cefotaxime sodium and cefoperazone sodium. Enthalpy of solution of 100% crystalline and amorphous drugs as well as their physical mixtures over the range 0-100 mass/mass% amorphous content were determined. As expected it has been found that amorphous forms have significantly higher energy than the corresponding crystalline form for all the drugs. Enthalpy of solution (ΔsolH), an extensive thermodynamic property can provide a precise and unambiguous measure of the relative crystallinity provided amorphous and crystalline standards are appropriately chosen. A good correlation has been found between ?solH and the amorphous contents of the drugs

Improving the Reliability of Three Phase Inverter Base on Cuk Converter for Pv Application

This paper present three phase inverter base on the cuk converter. The prime foredeal of this proposed theory is energy storage element like as inductors and capacitors can be reduced in order to reforms the system reliability and reduced total size alike total cost of system. The uncommon characteristics of cuk converter, when required ac voltage is depress or greater than dc side voltage but this quality is not found in conventional Current source inverter as well as voltage source inverter. Traditional method required any mathematical model but the fuzzy controller does not require any mathematical model and it's very simple to implement. The cuk converter is simulated for grid and their output voltage is settling at desired voltage. The performance of cuk converter simulated by using MATLAB/SIMULINK and contrast study is performed