Hany S.M. Ali scite author profile

Ciprofloxacin biodegradable implantable matrices (CPX-IMs) of tailored porous surfaces were fabricated by hot melt injection molding of poly-l-lactic acid (PLLA) followed by coating with PLLA/sodium chloride. CPX-IDs were designed to have a non-porous coat (NPC) or a porous coat of small pore size (SPC; 150-250 µm) or a large pore size (LPC; 250-350 µm). CPX-IMs surface pore size was confirmed by scanning electron microscope. The hardness of NPC, LPC, and SPC CPX-IMs were 58 ± 2.8, 53 ± 1.9, and 50 ± 2.1 N, respectively. The measured porosity values were 41.2 ± 1.53, 65.2 ± 1.1, and 60.7 ± 1.2%, respectively. Differential scanning calorimetry was employed to study the compatibility of ingredients, the effect of injection molding on polymer properties, and implants degradation. Coating of CPX-IMs prolonged drug release to reach a value of 90% release in 40 days. Antibacterial activity tests showed sufficiency of CPX to inhibit pathogens known to cause osteomyelitis. The in vivo study showed tissue compatibilities of the inserted matrices in tested rats with no sign of infection throughout the experiment period. SPC and LPC CPX-IMs demonstrated a better osteointegration, cell adhesion, and infiltration of different types of bone cells within implants structure compared to the non-porous matrix. Furthermore, LPC CPX-IMs showed a superior bone cell attachment and osteointegration relative to SPC CPX-IMs. Findings of this study confirmed the impact of porosity and pore sizes on cell proliferation and fracture healing concurrently with the sustained local antibiotic therapy for treatment or prevention of osteomyelitis.

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<p>Engineering of solidified glyburide nanocrystals for tablet formulation via loading of carriers: downstream processing, characterization, and bioavailability</p>

Ali

Hanafy

Alqurshi

2019

IJN

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Introduction: Presenting poorly water-soluble drugs as nanoparticles has shown to be an effective technique in enhancing drug dissolution rate, intrinsic solubility, and thus oral bioavailability. Nevertheless, working with nanoparticles introduces many challenges, one of which is their physical instability. Formulating nanoparticles into a solid dosage form may overcome such challenges and thus unlock the potential benefits of nanosizing. Methods: The current work investigates the possibility of developing a novel solid dosage form, with enhanced dissolution rate, whereby nanocrystals (~400 nm) of the class II Biopharmaceutical Classification System drug, glyburide (GBD) were fabricated through combined precipitation and homogenization procedures. Using a novel, but scalable, spraying technique, GBD nanocrystals were loaded onto commonly used tablet fillers, water-soluble lactose monohydrate (LAC), and water insoluble microcrystalline cellulose (MCC). Conventional tableting processes were then used to convert the powders generated into a tablet dosage form. Results: Studies of redispersibility showed considerable preservation of size characteristics of GBD nanocrystals during downstream processing with redispersibility indices of 105 and 118 for GBD-LAC and GBD-MCC, respectively. Characterization by differential scanning calorimetry, powder X-ray diffraction, and scanning electron microscopy showed that the powders generated powders contained nanosized crystals of GBD which adhered to carrier surfaces. Powder flowability was characterized using Hausner ratio (HR) and Carr's index (CI). GBD-LAC-loaded particles exhibited poor flowability with CI and HR of 37.5% and 1.60, respectively, whilst GBD-MCC particles showed a slightly improved flowability with CI and HR of 26.47% and 1.36, respectively. The novel tablet dosage form met US Pharmacopeia specifications, including drug content, hardness, and friability. Conclusion: Higher dissolution rates were observed from the nanocrystal-based tablets compared to the microsized and commercial drug formulations. Moreover, the novel nanocrystal tablet dosage forms showed enhanced in vivo performance with area under the plasma concentrationtime curve in the first 24 hours values 1.97 and 2.24 times greater than that of marketed tablets.

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Solubility of salbutamol and salbutamol sulphate in ethanol+water mixtures at 25°C

Ali

York

Blagden

et al. 2012

Journal of Molecular Liquids

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Hany S.M. Ali

Preparation of hydrocortisone nanosuspension through a bottom-up nanoprecipitation technique using microfluidic reactors

Hydrocortisone nanosuspensions for ophthalmic delivery: A comparative study between microfluidic nanoprecipitation and wet milling

Artificial neural networks modelling the prednisolone nanoprecipitation in microfluidic reactors

Solubility of Budesonide, Hydrocortisone, and Prednisolone in Ethanol + Water Mixtures at 298.2 K

Glibenclamide Nanocrystals in a Biodegradable Chitosan Patch for Transdermal Delivery: Engineering, Formulation, and Evaluation

Dual effect biodegradable ciprofloxacin loaded implantable matrices for osteomyelitis: controlled release and osteointegration

<p>Engineering of solidified glyburide nanocrystals for tablet formulation via loading of carriers: downstream processing, characterization, and bioavailability</p>

Solubility of salbutamol and salbutamol sulphate in ethanol+water mixtures at 25°C

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