Patrizia Marchetti scite author profile

Can Organic Solvent Nanofiltration (OSN) be considered green? Is OSN greener than other downstream processing technologies? These are the two main questions addressed critically in the present review. Further questions dealt with in the review are as follows: What is the carbon footprint associated with the fabrication and disposal of membrane modules? How much solvent has to be processed by OSN before the environmental burden of OSN is less than the environmental burden of alternative technologies? What are the main challenges for improving the sustainability of OSN? How can the concept of Quality by Design (QbD) improve and assist the progress of the OSN field? Does the scale have an effect on the sustainability of membrane processes? The green aspects of OSN membrane fabrication, processes development and scale-up as well as the supporting concept of QbD, and solvent recovery technologies are critically assessed and future research directions are given, in this review. Gyorgy Szekely Gyorgy received his MSc degree in Chemical Engineering from the Technical University of Budapest, and he earned his PhD degree in Chemistry under Marie Curie Actions from the Technical University of Dortmund. He worked as an Early Stage Researcher in Hovione PharmaScience and an IAESTE Fellow at the University of Tokyo. He is currently a Research Associate in Imperial College London. His multidisciplinary professional background covers supramolecular chemistry, organic and analytical chemistry, molecular recognition, molecular imprinting, process development, nanofiltration and pharmaceutical impurity scavenging. He is the Secretary General of the Marie Curie Fellows Association and a Member of the Royal Society of Chemistry.

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Smart Approach To Evaluate Drug Diffusivity in Injectable Agar−Carbomer Hydrogels for Drug Delivery

Santoro

Marchetti

Rossi

et al. 2011

J. Phys. Chem. B

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Hydrogels are commonly studied for tissue engineering applications and controlled drug delivery. In order to evaluate their reliability as scaffolds and delivery devices, literature describes many release studies performed involving different analytical techniques. However, these experiments can be expensive, time-consuming, and often not reproducible. In this study, two injectable agar-carbomer-based hydrogels were studied, both being loaded with sodium fluorescein, a harmless fluorophore with a steric hindrance similar to many small drugs, such as for example steroids and other neuroprotecting agents. Starting from simple, traditional, and inexpensive release experiments, it was possible to indirectly estimate the self-diffusion coefficient (D) of loaded sodium fluorescein. Such a parameter was also directly measured in the gel matrix by means of high resolution magic angle spinning (HRMAS) diffusion-ordered spectroscopy NMR. Because of the agreement between the calculated values and those measured by HRMAS-NMR spectroscopy, the latter approach can be considered as a simple and fast alternative to long analytic procedures.

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Crosslinked polybenzimidazole membranes for organic solvent nanofiltration (OSN): Analysis of crosslinking reaction mechanism and effects of reaction parameters

Valtcheva

Marchetti

Livingston

2015

Journal of Membrane Science

121

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The Selectivity Challenge in Organic Solvent Nanofiltration: Membrane and Process Solutions

Marchetti

Peeva

Livingston

2017

Annu. Rev. Chem. Biomol. Eng.

108

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Recent development of organic solvent nanofiltration (OSN) materials has been overwhelmingly directed toward tight membranes with ultrahigh permeance. However, emerging research into OSN applications is suggesting that improved separation selectivity is at least as important as further increases in membrane permeance. Membrane solutions are being proposed to improve selectivity, mostly by exploiting solute/solvent/membrane interactions and by fabricating tailored membranes. Because achieving a perfect separation with a single membrane stage is difficult, process engineering solutions, such as membrane cascades, are also being advocated. Here we review these approaches to the selectivity challenge, and to clarify our analysis, we propose a selectivity figure of merit that is based on the permselectivity between the two solutes undergoing separation as well as the ratio of their molecular weights.

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