Investigation of the solid state properties of amoxicillin trihydrate and the effect of powder pH

Investigating the Role of Citric Acid as a Natural Acid on the Crystallization of Amoxicillin Trihydrate

This study investigates the use of environmentally friendly citric acid as the main player in the process, rather than as an additive, to remove impurities from amoxicillin trihydrate (AMCT) crystals, aiming to optimize their purity and yield. By manipulating the concentration of citric acid, mixing speed, crystallization time, and pH, the researchers conducted experiments using a full factorial design. The dissolution stage was analyzed in both batch and continuous crystallization processes, emphasizing the significance of citric acid in enhancing crystallization. HPLC analyses were performed on the resulting crystals, and the data were analyzed using the Multi-Vari Chart program. The findings demonstrated that higher citric acid concentrations positively affected the yield, while factors such as crystallization time, mixing speed, and pH also contributed to the increased yield. The crystals obtained exhibited desirable dimensions sought after in the pharmaceutical industry, eliminating the need for additional purification steps. This study showcased the potential of citric acid in AMCT crystallization, offering advantages in product design, purification, and synthesis. The optimized conditions included a citric acid concentration of 2.0 M, mixing speed of 1000 rpm, crystallization time of 120 min, and pH of 5.5. Notably, the developed process proved to be environmentally friendly by avoiding the use of harmful chemicals, serving as a green alternative for crystallization processes, and producing purer AMCT products. Overall, this research contributes to the existing literature by highlighting the efficacy of citric acid in impurity removal and the optimization of AMCT crystal purity and yield.

Comparative Study of Bi2 O3 , MgO and ZrO2 Nanomaterials designed by Polymer Sacrificial Method for Amoxicillin delivery and Bone Regeneration: In-Vitro Studies.. [DOI: 10.21203/rs.3.rs-3146890/v1] [Citation(s) in RCA: 0] [Impact Index Per Article: 0]

Hard tissue scientists face many difficulties, including persistent osteomyelitis and diseased bone abnormalities. Inorganic mesoporous nanomaterials are excellent candidates for the adsorption and loading of bioactive medicinal substances because to their chemical-physical characteristics. Recently, zirconium oxide, magnesium oxide and bismuth oxide nanoparticles are of great surface area and biocompatibility, and they have been described as a new drug delivery carrier. In this study, amoxicillin antibiotic was loaded into the prepared mesoporous nanomaterials (ZrO2, MgO and Bi2O3) to form a local antibiotic delivery system. The prepared mesoporous nanomaterials were investigated by XRD, FTIR, TEM, zeta potential and BET surface area measurements. Amoxicillin antibiotic was released from the prepared mesoporous nanomaterials in PBS. The effectiveness of the antibacterial study against several gram-positive and gram-negative bacterial strains was assessed. The cytotoxicity study of the human osteoblast-like cells (MG-63) was tested for all prepared mesoporous nanomaterials utilizing MTT assay. ZrO2 demonstrated particle diameters in the range of (5.26– 11.47nm), MgO was (70–80nm) and Bi2O3 was (9.79– 13.7nm). The greater surface area was confirmed for Bi2O3 sample (3.99 m2g− 1) by BET surface area. Amoxicillin loaded mesoporous nano powders exhibited impressive antibacterial and antifungal activities. MgO and Bi2O3 mesoporous nanoparticles exhibited better antimicrobial activities compared to ZrO2 sample. The proliferation for all samples gave good results especially for MgO and Bi2O3. As a result, the produced mesoporous nanomaterials have a significant potential for use as medicine delivery systems for bone regeneration and for enhancing the properties of other products in medical applications.

Purification of amoxicillin trihydrate in the presence of degradation products by different washing methods

Repeated crystallization or the use of different chemicals to obtain a pure crystal can cause yield/purity issues.

Design and Formulation of Optimized Microemulsions for Dermal Delivery of Resveratrol

The objective of this study was to formulate optimal formulations of microemulsions (MEs) and evaluate their feasibility for delivery of resveratrol into human skin ex vivo. Oil-in-water MEs were formulated using surfactant (S) PEG-8 caprylic/capric glycerides and cosurfactant (CoS) polyglyceryl-6-isostearate. Ethyl oleate was used as an oily phase. MEs were formulated using 5 : 1, 6 : 1, and 7 : 1 surfactant and cosurfactant (S : CoS) weight ratios. Pseudoternary phase diagrams were constructed and optimal compositions of MEs were obtained using Design Expert software. Mean droplet size for optimized ME formulations was determined to be 68.54 ± 1.18 nm, 66.08 ± 0.16 nm, and 66.66 ± 0.56 nm for systems with S : CoS weight ratios 5 : 1, 6 : 1, and 7 : 1, respectively. Resveratrol loading resulted in mean droplet size increase. The distribution of droplet size between fractions changed during storage of formulated MEs. Results demonstrated the increase of number of droplets and relative surface area when S : CoS weight ratios were 6 : 1 and 7 : 1 and the decrease when S : CoS weight ratio was 5 : 1. The highest penetration of resveratrol into the skin ex vivo was determined from ME with S : CoS weight ratio 5 : 1. It was demonstrated that all MEs were similar in their ability to deliver resveratrol into the skin ex vivo.

Overcoming the cutaneous barrier with microemulsions

Microemulsions are fluid and isotropic formulations that have been widely studied as delivery systems for a variety of routes, including the skin. In spite of what the name suggests, microemulsions are nanocarriers, and their use as topical delivery systems derives from their multiple advantages compared to other dermatological formulations, such as ease of preparation, thermodynamic stability and penetration-enhancing properties. Composition, charge and internal structure have been reported as determinant factors for the modulation of drug release and cutaneous and transdermal transport. This manuscript aims at reviewing how these and other characteristics affect delivery and make microemulsions appealing for topical and transdermal administration, as well as how they can be modulated during the formulation design to improve the potential and efficacy of the final system.

Stability of a cosmetic multiple emulsion loaded with green tea extract

Multiple emulsions are excellent and exciting potential systems for the delivery of useful cosmetic agents. The work describes stability of a multiple emulsion for cosmetic purpose, loaded with extract of Camellia sinensis L. (Theaceae) in concentration of 5%. The formulation constitutes of cetyl dimethicone copolyol and polyoxyethylene (20) cetyl ether as emulsifiers and was characterised and monitored for various physicochemical aspects. Centrifugation has no devastating effect on physical destabilization/phase separation observed for 30 days. Mean globule sizes of multiple droplets were found in the range of 10.29 ± 4.4 μm to 12.77 ± 5.1 μm and of inner droplets were in the range of 0.8 ± 0.4 μm to 1.6 ± 0.8 μm. All samples exhibited shear thinning behavior with increase in shear stress. The results of the present study indicate that multiple emulsions can be used as carrier of 5% Camellia sinensis L. extract to enhance desired effects. The developed physically and chemically stable system is an effective system for targeting skin layers; however, long-term stability at elevated temperatures may be needed with suitable modifications, if required.

Formulation of dacarbazine-loaded cubosomes. Part III. Physicochemical characterization

The purpose of this study was to investigate the physicochemical properties of dacarbazine-loaded cubosomes. The drug-loaded cubosome nanocarriers were prepared by a fragmentation method and then freeze dried. They were then characterized for size, morphology, thermal behavior, and crystallography using dynamic light scattering, transmission electron microscopy (TEM), differential scanning calorimetry (DSC), and powder X-ray diffraction (PXRD), respectively. The drug loading and encapsulation efficiency were determined by UV spectrophotometry. The results showed that the prepared dacarbazine-loaded cubosomes had mean diameters ranging from 86 to 106 nm. In addition to the TEM, the characteristic peaks from PXRD data suggested that the freeze-dried nanoformulations were indeed cubic in nature. DSC and PXRD analysis suggested the 0.06 or 0.28% w/w actual drug loaded inside cubosomes was in the amorphous or molecular state. These physicochemical characteristics would affect the nanoformulation shelf-life, efficacy, and safety.