Mohammad A. Khaleel scite author profile

Background: Fungal keratitis (FK) is a serious pathogenic condition usually associated with significant ocular morbidity. Natamycin (NAT) is the first-line and only medication approved by the Food and Drug Administration for the treatment of FK. However, NAT suffers from poor corneal penetration, which limits its efficacy for treating deep keratitis. Purpose: The objective of this work was to prepare NAT solid lipid nanoparticles (NAT-SLNs) to achieve sustained drug release and increased corneal penetration. Methods: NAT-SLNs were prepared using the emulsification-ultrasonication technique. Box-Behnken experimental design was applied to optimize the effects of independent processing variables (lipid concentration [X 1 ], surfactant concentration [X 2 ], and sonication frequency [X 3 ]) on particle size (R 1), zeta potential (ZP; R 2), and drug entrapment efficiency (EE%) (R 3) as responses. Drug release profile, ex vivo corneal permeation, antifungal susceptibility, and cytotoxicity of the optimized formula were evaluated. Results: The optimized formula had a mean particle size of 42 r.nm (radius in nanometers), ZP of 26 mV, and EE% reached ~85%. NAT-SLNs showed an extended drug release profile of 10 hours, with enhanced corneal permeation in which the apparent permeability coefficient (P app) and steady-state flux (J ss) reached 11.59×10-2 cm h-1 and 3.94 mol h-1 , respectively, in comparison with 7.28×10-2 cm h-1 and 2.48 mol h-1 for the unformulated drug, respectively. Antifungal activity was significantly improved, as indicated by increases in the inhibition zone of 8 and 6 mm against Aspergillus fumigatus ATCC 1022 and a Candida albicans clinical isolate, respectively, and minimum inhibitory concentration values that were decreased 2.5-times against both of these pathogenic strains. NAT-SLNs were found to be non-irritating to corneal tissue. NAT-SLNs had a prolonged drug release rate , that improved corneal penetration, and increased antifungal activity without cytotoxic effects on corneal tissues. Conclusion: Thus, NAT-SLNs represent a promising ocular delivery system for treatment of deep corneal keratitis.

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The prevalence of asthma and its related risk factors among the children in Taif area, Kingdom of Saudi Arabia

Hamam

Eldalo

Albarraq

et al. 2015

Saudi J Health Sci

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A Standardized Dataset of a Spontaneous Adverse Event Reporting System

et al. 2022

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One of the largest spontaneous adverse events reporting databases in the world is the Food and Drug Administration (FDA) Adverse Event Reporting System (FAERS). Unfortunately, researchers face many obstacles in analyzing data from the FAERS database. One of the major obstacles is the unstructured entry of drug names into the FAERS, as reporters might use generic names or trade names with different naming structures from all over the world and, in some cases, with typographical errors. Moreover, report duplication is a known problem in spontaneous adverse event-reporting systems, including the FAERS database. Hence, thorough text processing for database entries, especially drug name entries, coupled with a practical case-deduplication logic, is a prerequisite to analyze the database, which is a time- and resource-consuming procedure. In this study, we provide a clean, deduplicated, and ready-to-import dataset into any relational database management software of the FAERS database up to September 2021. Drug names are standardized to the RxNorm vocabulary and normalized to the single active ingredient level. Moreover, a pre-calculated disproportionate analysis is provided, which includes the reporting odds ratio (ROR), proportional reporting ratio (PRR), Chi-squared analysis with Yates correction (x2), and information component (IC) for each drug-adverse event pair in the database.

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Sesame Oil-Based Nanostructured Lipid Carriers of Nicergoline, Intranasal Delivery System for Brain Targeting of Synergistic Cerebrovascular Protection

Abourehab

Khames

Genedy³

et al. 2021

Pharmaceutics

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Nicergoline (NIC) is a semisynthetic ergot alkaloid derivative applied for treatment of dementia and other cerebrovascular disorders. The efficacy of sesame oil to slow and reverse the symptoms of neurodegenerative cognitive disorders has been proven. This work aimed to formulate and optimize sesame oil-based NIC-nanostructured lipid carriers (NIC–NLCs) for intranasal (IN) delivery with expected synergistic and augmented neuroprotective properties. The NIC–NLC were prepared using sesame oil as a liquid lipid. A three-level, three-factor Box–Behnken design was applied to statistically optimize the effect of sesame oil (%) of the total lipid, surfactant concentration, and sonication time on particle size, zeta potential, and entrapment efficacy as responses. Solid-state characterization, release profile, and ex vivo nasal permeation in comparison to NIC solution (NIC–SOL) was studied. In vivo bioavailability from optimized NIC–NLC and NIC–SOL following IN and IV administration was evaluated and compared. The optimized NIC–NLC formula showed an average particle size of 111.18 nm, zeta potential of −15.4 mV, 95.11% entrapment efficacy (%), and 4.6% loading capacity. The NIC–NLC formula showed a biphasic, extended-release profile (72% after 48 h). Permeation of the NIC–NLC formula showed a 2.3 enhancement ratio. Bioavailability studies showed a 1.67 and 4.57 fold increase in plasma and brain following IN administration. The results also indicated efficient direct nose-to-brain targeting properties with the brain-targeting efficiency (BTE%) and direct transport percentage (DTP%) of 187.3% and 56.6%, respectively, after IN administration. Thus, sesame oil-based NIC–NLC can be considered as a promising IN delivery system for direct and efficient brain targeting with improved bioavailability and expected augmented neuroprotective action for the treatment of dementia.

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Utilization of novel self-nanoemulsifying formulations (SNEFs) loaded paclitaxel for the treatment prosperity of bladder cancer

Abdallah

Kazi

Khaleel

et al. 2020

Journal of Drug Delivery Science and Technology

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Background: Limited drug penetration into solid tumors has been one of the potential causes of resistance to chemotherapy for the treatment of bladder cancer. The aim of the study is to develop non-toxic self-nanoemulsifying formulations (SNEFs) of paclitaxel and to evaluate their ability to serve as a tool increasing the stability and solubility of paclitaxel in formulations utilizing the drug intravesical administration. Methods:Various oil-in-water non-toxic self-nanoemulsifying formulations (SNEFs) were developed using Cremercoor MCT, Kollisolv MCT, Miglyol 812, 810, Capmul MCM, Imwitor 988, Imwitor 742 with TO106V, Tween 85, HCO30, Kolliphor EL and Cremophor RH40 at size ranges from approximately 19 to 110 nm that are capable of enhancing the solubility and stability of paclitaxel. Visual assessment and droplet size measurements were taken into initial consideration for optimised SNEFs. Paclitaxel was added with the oil/surfactant mixture before dispersing the mixture in water to form SNEF. The cytotoxicity of the optimal SNEFs was compared with the raw paclitaxel dispersion in vitro. Results: Initial characterisation and solubility studies showed that mixed glycerides of Kollisolv MCT/Imwitor 742 with water-soluble surfactant (high HLB) containing formulations generated highly efficient SNEFs as they are stable and produced lower nanodroplets with higher drug loading. The results have demonstrated that the SNEFs have good ability to retain its characteristics under conditions similar to that found in the urinary bladder up to 48 hours. However, the results also showed that chemosensitivity of cancer cells exposed to paclitaxel was attenuated in the presence of SNEFs. Larger size SNEFs have shown to induce more inhibitory effects on paclitaxel activity. Conclusion: optimised SNEFs have demonstrated the ability to enhance the solubility of paclitaxel with stable construction of SNEFs under variable physiological conditions. The reduction of the efficacy of SNEF-loaded paclitaxel indicates a strong encapsulation of the drug within the nano-carriers causing limitation in drug release. Such drug encapsulation may facilitate the penetration due to reduced cellular metabolism the drug. Further investigations are warranted.

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