Prina Mehta scite author profile

A critical survey of the laboratory test methods used to measure wicking is presented, and the four main methods are compared through application to a range of knitted fabrics produced from various fiber types. Correlation of the results indicates which combination of methods provides a meaningful assessment of fabric wicking properties in the context of clothing comfort studies. Observations on the wicking properties of various fiber types shows that wicking is often not inherent to the fiber, but is in part due to surfactants, such as spin finishes, which can be removed by washing.

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Pharmaceutical and biomaterial engineering via electrohydrodynamic atomization technologies

Mehta

Haj‐Ahmad

Rasekh

et al. 2017

Drug Discovery Today

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Complex micro- and nano-structures enable crucial developments in the healthcare remit (e.g., pharmaceutical and biomaterial sciences). In recent times, several technologies have been developed and explored to address key healthcare challenges (e.g., advanced chemotherapy, biomedical diagnostics and tissue regeneration). Electrohydrodynamic atomization (EHDA) technologies are rapidly emerging as promising candidates to address these issues. The fundamental principle driving EHDA engineering relates to the action of an electric force (field) on flowing conducting medium (formulation) giving rise to a stable Taylor cone. Through careful optimization of process parameters, material properties and selection, nozzle and needle design, and collection substrate method, complex active micro- and nano-structures are engineered. This short review focuses on key selected recent and established advances in the field of pharmaceutical and biomaterial applications.

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Development and characterisation of electrospun timolol maleate-loaded polymeric contact lens coatings containing various permeation enhancers

Mehta

Al-Kinani

Arshad

et al. 2017

International Journal of Pharmaceutics

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Despite exponential growth in research relating to sustained and controlled ocular drug delivery, anatomical and chemical barriers of the eye still pose formulation challenges. Nanotechnology integration into the pharmaceutical industry has aided efforts in potential ocular drug device development. Here, the integration and in vitro effect of four different permeation enhancers (PEs) on the release of anti-glaucoma drug timolol maleate (TM) from polymeric nanofiber formulations is explored. Electrohydrodynamic (EHD) engineering, more specifically electrospinning, was used to engineer nanofibers (NFs) which coated the exterior of contact lenses. Parameters used for engineering included flow rates ranging from 8 to 15μL/min and a novel EHD deposition system was used; capable of hosting four lenses, masked template and a ground electrode to direct charged atomised structures. SEM analysis of the electrospun structures confirmed the presence of smooth nano-fibers; whilst thermal analysis confirmed the stability of all formulations. In vitro release studies demonstrated a triphasic release; initial burst release with two subsequent sustained release phases with most of the drug being released after 24h (86.7%) Biological evaluation studies confirmed the tolerability of all formulations tested with release kinetics modelling results showing drug release was via quasi-Fickian or Fickian diffusion. There were evident differences (p<0.05) in TM release dependant on permeation enhancer.

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Application of mesoporous silica nanoparticles as drug delivery carriers for chemotherapeutic agents

Alyassin

Sayed

Mehta

et al. 2020

Drug Discovery Today

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Recently, remarkable efforts have focused on research towards enhancing and delivering efficacious and advanced therapeutic agents. Even though this involves significant challenges, innovative techniques and materials have been explored to overcome these. The advantageous properties of mesoporous silica nanoparticles (MSNs), such as unique morphologies and geometries, makes then favorable for use for various drug delivery targeting purposes, particularly in cancer therapy. As we discuss here, MSNs have been utilized over the past few decades to improve the efficiency of anticancer drugs by enhancing their solubility to render them suitable for application, reducing adverse effects, and improving their anticancer cytotoxic efficiency.

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Transdermal Microneedles—A Materials Perspective

et al. 2019

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Prina Mehta

A Survey and Comparison of Laboratory Test Methods for Measuring Wicking

Pharmaceutical and biomaterial engineering via electrohydrodynamic atomization technologies

Development and characterisation of electrospun timolol maleate-loaded polymeric contact lens coatings containing various permeation enhancers

Application of mesoporous silica nanoparticles as drug delivery carriers for chemotherapeutic agents

Transdermal Microneedles—A Materials Perspective

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