Bioinspired synthesis of optically and thermally responsive nanoporous membranes

Abstract: The development of porous membranes that can rapidly change flow rates in response to external, noninvasive stimuli has broad technological applications for areas ranging from biomedical devices to architecture. Environmentally responsive membranes have a fundamental role in the development of devices used in chemical sensors, biological sorters, sequencing, separations, high-throughput medical devices and labs on a chip. The design and engineering of these responsive porous membranes have been achieved throug… Show more

“…In addition, the PET surface can be etched by high-concentration sodium hydroxide and generates carboxyl groups in situ, which can be used for further modification [79]. PET nanochannels can be used to manufacture various nanodevices in response to various stimuli, such as specific ions and molecules [25,66,[80][81][82][83][84][85][86], pH [65,67,68,[87][88][89][90], temperature [91,92], and multiple stimuli [11,56,60,[93][94][95] (Table 1). For example, inspired by the light/pH-switched The single conical-shaped PET nanochannel was prepared by a common method (Fig.…”

“…However, the lipid bilayer is fragile and sensitive, and it is difficult to artificially adjust working environment to biological systems. Inspired by biological nanochannels, researchers have developed artificial nanochannels functioning like the ion channel or nanopore in biological system membranes [1,6,7], called "bioinspired nanochannels" [8][9][10][11][12]. Bioinspired nanochannels have significant advantages over nanochannels embedded in lipid membranes: chemical and physical stability, flexibility in size and shape, and easy fabrication of high-density arrays [13,14].…”

Bioinspired nanochannels based on polymeric membranes

“…In addition, the PET surface can be etched by high-concentration sodium hydroxide and generates carboxyl groups in situ, which can be used for further modification [79]. PET nanochannels can be used to manufacture various nanodevices in response to various stimuli, such as specific ions and molecules [25,66,[80][81][82][83][84][85][86], pH [65,67,68,[87][88][89][90], temperature [91,92], and multiple stimuli [11,56,60,[93][94][95] (Table 1). For example, inspired by the light/pH-switched The single conical-shaped PET nanochannel was prepared by a common method (Fig.…”

“…However, the lipid bilayer is fragile and sensitive, and it is difficult to artificially adjust working environment to biological systems. Inspired by biological nanochannels, researchers have developed artificial nanochannels functioning like the ion channel or nanopore in biological system membranes [1,6,7], called "bioinspired nanochannels" [8][9][10][11][12]. Bioinspired nanochannels have significant advantages over nanochannels embedded in lipid membranes: chemical and physical stability, flexibility in size and shape, and easy fabrication of high-density arrays [13,14].…”

Bioinspired nanochannels based on polymeric membranes

“…As a result of numerous advantages, wide areas of application, and high efficiency, bio-inspired membranes have the chance to be the next generation of membranes (Morones-Ramırez, 2013;Rawlings, Bramble, & Staniland, 2012). In this method, nature is considered a large database to which its scientific rules might be applied in engineering applications as efficient solutions for difficult problems.…”

Advances in polymeric membranes for water treatment

“…Therefore, different composite membranes capable of changing their effective pore size with environmental triggers such as pH and ionic strength [3,4], temperature [5], and chemical moieties, such as glucose [6], have been developed. However, a recent interest has been the development of porous membranes responsive to light, since these present advantages potentially achieve rapid, remote, noninvasive, and localized flow control [7][8][9][10]. This work describes the development of a synthesis pathway to achieve grafting of optothermally responsive polymer-metal nanoparticle nanocomposites to polycarbonate track-etched porous membranes (PCTEPMs) to build an optothermally responsive porous membrane.…”

Coupling Metallic Nanostructures to Thermally Responsive Polymers Allows the Development of Intelligent Responsive Membranes