A reusable device for electrochemical applications of hydrogel supported black lipid membranes

Mech-Dorosz, Agnieszka; Heiskanen, Arto; Bäckström, Sania; Perry, Mark; Muhammad, Haseena Bashir; Hélix-Nielsen, Claus; Emnéus, Jenny

doi:10.1007/s10544-015-9936-y

Cited by 8 publications

(19 citation statements)

References 48 publications

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“…Gold is not toxic and easy to handle. Presently, most electrochemical sensors employ thin gold films printed on a nonconductive support since these electrodes are inexpensive, reusable and disposable [63].…”

Section: Supported Lipid Monolayers (Slms)mentioning

confidence: 99%

Electrode-supported biomimetic membranes: An electrochemical and surface science approach for characterizing biological cell membranes

Leitch

Lipkowski

2018

Current Opinion in Electrochemistry

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Section: Supported Lipid Monolayers (Slms)mentioning

confidence: 99%

Electrode-supported biomimetic membranes: An electrochemical and surface science approach for characterizing biological cell membranes

Leitch

Lipkowski

2018

Current Opinion in Electrochemistry

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“…The date also show how the function incorporation values were measured and how M n (which can be quantiied using NMR) is related to M w as PDI = M w / M n . This table does not include the incorporation studies that do not include block copolymerprotein interactions, such as cell-free expression systems [73][74][75], nanopores [76,77], encapsulation in hydrophobic interior [6], hydrogel approaches [78,79], and non-amphiphilic polymers [80]. Due to this restriction on the data, the table showcases the results that were made available by Wolfgang Meier and coworkers implementing PMOXA-PDMS-PMOXA triblock copolymers.…”

Section: Figures 1 and 2)mentioning

confidence: 99%

Interactions between Aquaporin Proteins and Block Copolymer Matrixes

Abdelrasoul¹,

Doan²,

Lohi³

2017

Biomimetic and Bioinspired Membranes for New Frontiers in Sustainable Water Treatment Technology

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This chapter continues to further expand its focus on aquaporins (AQPs) by ofering a general outline on how the AQPs block copolymers, and polymer support structures can interrelate and such connections can be comprehensively classiied and deined. The irst section of the overview will consider the relationship between block copolymers and AQPs. It will also examine the general membrane protein integration into block copolymers, since this can cause AQP-block copolymer complexes in vesicular (proteopolymersomes) as well as in planar forms. The majority of considerations taken into account during AQP incorporation come from the research conducted in relation to the process of incorporating other types of membrane proteins. This chapter includes an overview of the various characterization methodologies needed for the study of proteopolymersomes, as well as freeze-fracture transmission electron microscopy (FF-TEM), luorescence correlation spectroscopy (FCS), small-angle X-ray scatering (SAXS), and stopped-low light scatering (SFLS). The research data presented in this chapter emphasizes the fact that a successful process of membrane fabrication requires the integration of reconstituted AQPs into a suitable supporting matrix formation.Keywords: aquaporin proteins, block copolymer, matrix, vesicular, membrane protein Assessing aquaporin proteins and block copolymer matrixes interactionsMost research performed on membrane protein inclusion has been conducted primarily with lipids as the host matrix components (original proteoliposomes publication on the subject came out in 1971) [1]. Since then, polymer-based incorporation process has received increased atention and the earliest proteopolymersomes publication emerged in 2000 [2]. The initial work stages in this research area concentrated on the inclusion of membranespanning proteins, such as membrane-bound ion channels (ATPases) and bacteriorhodopsin incorporation into polymethyloxazoline-polydimethylsiloxane-polymethyloxazoline (PMOXA-PDMS-PMOXA) triblock copolymer bilayers occurring in planar [3] or vesicular forms [4][5][6]. It is quite fascinating that the membrane proteins may be functionally incorporated into polymeric bilayers (e.g., based on PMOXA-PDMS-PMOXA) that occur up to 10 times thicker than their lipidic counterparts [7]. Moreover, researchers have observed proteopolymersomes with protein density values that drastically surpassed those of proteoliposomes [8]. Research on these phenomena has helped to establish a theoretical approach for generalized membrane protein incorporation into the amphiphilic structures. This methodology is based on the notion that the eiciency of the membrane protein incorporation process relies on its hydrophobicity potential and its coupling capacity to the host membrane is directly connected to the hydrophobic mismatch parameters. In order to reduce this mismatch dynamic, the method calls for the host membrane to be deformed in such a way that it matches the hydrophobic length parameter of the membrane protein's transm...

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“…A later iteration of membrane design examined liquid membrane method with relatively small water flux for Spinach plasma membrane protein 2;1 (SoPIP2;1) proteoliposomes, which was placed between the NF membranes that were capable of providing an AQP fingerprint [14]. Designs such as these [14][15][16][17][18] helped to encourage innovative approaches to membranes and develop membrane-based biosensor projects [19]. In 2010, the hydrogel method created at Aquaporin A/S was introduced.…”

Section: Planar Biomimetic Structures and Membrane Designsmentioning

confidence: 99%

Recent Development in Aquaporin (AQP) Membrane Design

Abdelrasoul¹,

Doan²,

Lohi³

2017

Biomimetic and Bioinspired Membranes for New Frontiers in Sustainable Water Treatment Technology

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Development of Aquaporin Z (AqpZ) proteopolymersome has been substantial enough that it can obtain water separation membranes that feature fluxes of 11,000 L m −2 h −1 , a parameter value that is multiple orders of magnitude greater than the conventional industrial membranes available and possible only if the performance of AqpZ proteopolymersome can be properly scaled up. In fact, densely packed 2D AqpZ crystal arrays can in theory reach flux capacity of up to 16,000 L m −2 h −1. On the other hand, these flux values may likely not be reached in practice, since various upscaling issues would prevent them from occurring. Nonetheless, AqpZ offers immense potentials benefits when it comes to biomimetic membranes. The research in membrane development is continuously ongoing, for example, only a few years ago in 2011, aquaporin-based biomimetic polymeric membranes (ABPMs) were viewed as the radically advanced membrane solution and, at the same time, removed from practical applications and commercial production. After 4 years of innovative thinking, ABPM membranes are produced for commercial consumption and with area dimensions of tens of m 2. Although it will take some time before this membrane technology becomes universally accessible, it has already gone beyond the confines of research theory and into practical application. The following chapter will explicitly outline the development of AQP biomimetic membrane technology.

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A reusable device for electrochemical applications of hydrogel supported black lipid membranes

Cited by 8 publications

References 48 publications

Electrode-supported biomimetic membranes: An electrochemical and surface science approach for characterizing biological cell membranes

Electrode-supported biomimetic membranes: An electrochemical and surface science approach for characterizing biological cell membranes

Interactions between Aquaporin Proteins and Block Copolymer Matrixes

Recent Development in Aquaporin (AQP) Membrane Design

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