Abstract
Commercial hollow fiber filters for micro- and ultrafiltration are based on size exclusion and do not allow the removal of small molecules such as antibiotics. Here, we demonstrate that a graphene oxide (GO) layer can be firmly immobilized either inside or outside polyethersulfone-polyvinylpyrrolidone hollow fiber (Versatile PES®, hereafter PES) modules and that the resulting core-shell fibers inherits the microfiltration ability of the pristine PES fibers and the adsorption selectivity of GO. GO nanosheets were deposited on the fiber surface by filtration of a GO suspension through a PES cartridge (cut-off 0.1-0.2 μm), then fixed by thermal annealing at 80 °C, rendering the GO coating stably fixed and unsoluble. The filtration cut-off, retention selectivity and efficiency of the resulting inner and outer modified hollow fibers (HF-GO) were tested by performing filtration on water and bovine plasma spiked with bovine serum albumin (BSA, 66 kDa, ≈15 nm size), monodisperse polystyrene nanoparticles (52 nm and 303 nm sizes), with two quinolonic antibiotics (ciprofloxacin and ofloxacin) and rhodamine B (RhB). These tests showed that the microfiltration capability of PES was retained by HF-GO, and in addition the GO coating can capture the molecular contaminants while letting through BSA and smaller polystyrene nanoparticles. Combined XRD, molecular modelling and adsorption experiments show that the separation mechanism does not rely only on physical size exclusion, but involves intercalation of solute molecules between the GO layers.
Highlights
The development of novel membrane materials for puri cation of uids is of great interest for the fabrication of personalized biomedical treatments (i.e. selective apheresis, dialysis), speci c chemical separation (organic solutes from organic matrices), advanced water puri cation[1] and gas separation technologies.[2]Polymeric membranes are currently exploited at the industrial level for a variety of processes and applications, spanning blood ltration to food/drug puri cation, and drinking and wastewater puri cation.[3]The market trend for polymeric membrane ltration modules is growing, and it is expected to further increase in the few years due to the increasing demand for advanced healthcare treatments and drinkable water
The development of novel membrane materials for puri cation of uids is of great interest for the fabrication of personalized biomedical treatments, speci c chemical separation, advanced water puri cation[1] and gas separation technologies.[2]
We will name samples as HF-graphene oxide (GO) followed by the % of GO loading and the letter e/i, indicating whether the coating is placed on the outer or inner surface of the hollow ber
Summary
The development of novel membrane materials for puri cation of uids is of great interest for the fabrication of personalized biomedical treatments (i.e. selective apheresis, dialysis), speci c chemical separation (organic solutes from organic matrices), advanced water puri cation[1] and gas separation technologies.[2]Polymeric membranes are currently exploited at the industrial level for a variety of processes and applications, spanning blood ltration to food/drug puri cation, and drinking and wastewater puri cation.[3]The market trend for polymeric membrane ltration modules is growing, and it is expected to further increase in the few years due to the increasing demand for advanced healthcare treatments and drinkable water. The cut-off of the PES hollow ber pores used is in the range 0.1–0.2 mm, optimal for micro ltration of biological samples, blocking colloids and microorganisms of size >1.000 kDa (Fig. S7 and S8 ESI†).
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