A Visible‐Light‐Regulated Chloride Transport Channel Inspired by Rhodopsin

Quan, Jiaxin; Zhu, Fang; Dhinakaran, Manivannan Kalavathi; Yang, Yingying; Johnson, Robert P.; Li, Haibing

doi:10.1002/anie.202012984

Cited by 32 publications

(18 citation statements)

References 46 publications

(5 reference statements)

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“…In order to further illuminate selective adsorption in the nanochannel of the LAP5@SBA-15 membrane, the ratio ( R = [ I – I 0 ]/ I 0 ) was calculated, where I 0 and I are the current at +2 V before and after adding with propranolol enantiomers. The ratio increased below 5 × 10 –4 M and formed a platform at a higher concentration; the trend was similar to the Langmuir absorption isotherm. , As reported in previous literature, a Langmuir linear fit equation is as follows: C / R = 1/ KR max + C / R max . R -PPL had a bigger K value in the nanochannel (Figure a), which illustrates the LAP5@SBA-15 hybrid membrane exhibiting a higher binding affinity for R -PPL entering its nanochannel.…”

Section: Results and Discussionsupporting

confidence: 86%

“…The ratio increased below 5 × 10 −4 M and formed a platform at a higher concentration; the trend was similar to the Langmuir absorption isotherm. 44,45 As reported in previous literature, a Langmuir linear fit equation is as follows: C/R = 1/KR max + C/ R max . R-PPL had a bigger K value in the nanochannel (Figure 6a), which illustrates the LAP5@SBA-15 hybrid membrane exhibiting a higher binding affinity for R-PPL entering its nanochannel.…”

Section: ■ Results and Discussionmentioning

confidence: 94%

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Chiral Nanochannels of Ordered Mesoporous Silica Constructed by a Pillar[5]arene-Based Host–Guest System

Cheng

Zhu

et al. 2021

ACS Appl. Mater. Interfaces

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The separation of racemic compounds by chiral nanochannels has attracted extensive attention. However, the fabrication of high-performance chiral nanochannels is still a challenge owing to the difficulty in magnifying the weak chiral interaction to macroscopic properties of materials. Herein, by introducing a l-alanine-pillar[5]arene host to achiral ordered mesoporous silica (OMS), chiral OMS nanochannels were fabricated, which exhibited excellent selectivity (ee value up to 90.2%) to separate racemic drugs with promising reusability and stability. Besides, it was identified that enantioselective separation took place through a molecular-recognition-adsorbed transport mechanism. This work highlights the great potential of chiral OMS nanochannels as a platform for enantioselective separation.

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Section: Results and Discussionsupporting

confidence: 86%

Section: ■ Results and Discussionmentioning

confidence: 94%

Chiral Nanochannels of Ordered Mesoporous Silica Constructed by a Pillar[5]arene-Based Host–Guest System

Cheng

Zhu

et al. 2021

ACS Appl. Mater. Interfaces

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“…Specific ions can then be conducted or intercepted periodically by nanochannels. [ 27,28,74 ] For instance, a series of single (e.g., pH, [ 75 ] light, [ 76,77 ] electricity, [ 78 ] and magnetism [ 79 ] ) and double (e.g., ion and pH, [ 80 ] light and pH, [ 81 ] and electricity and pH [ 82 ] ) stimulus‐responsive gatings were obtained after decorating stimulus‐responsive molecules on the nanochannel walls. The ionic conductance of these membranes can be directly used to illustrate the closing and opening states of ion gating.…”

Section: Controllability Of Ion Transportmentioning

confidence: 99%

Rational ion transport management mediated through membrane structures

et al. 2021

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Unique membrane structures endow membranes with controlled ion transport properties in both biological and artificial systems, and they have shown broad application prospects from industrial production to biological interfaces. Herein, current advances in nanochannel‐structured membranes for manipulating ion transport are reviewed from the perspective of membrane structures. First, the controllability of ion transport through ion selectivity, ion gating, ion rectification, and ion storage is introduced. Second, nanochannel‐structured membranes are highlighted according to the nanochannel dimensions, including single‐dimensional nanochannels (i.e., 1D, 2D, and 3D) functioning by the controllable geometrical parameters of 1D nanochannels, the adjustable interlayer spacing of 2D nanochannels, and the interconnected ion diffusion pathways of 3D nanochannels, and mixed‐dimensional nanochannels (i.e., 1D/1D, 1D/2D, 1D/3D, 2D/2D, 2D/3D, and 3D/3D) tuned through asymmetric factors (e.g., components, geometric parameters, and interface properties). Then, ultrathin membranes with short ion transport distances and sandwich‐like membranes with more delicate nanochannels and combination structures are reviewed, and stimulus‐responsive nanochannels are discussed. Construction methods for nanochannel‐structured membranes are briefly introduced, and a variety of applications of these membranes are summarized. Finally, future perspectives to developing nanochannel‐structured membranes with unique structures (e.g., combinations of external macro/micro/nanostructures and the internal nanochannel arrangement) for mediating ion transport are presented.

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“…In addition, taking advantage of the high selectivity and reversibility of host–guest systems, Li and co-workers proposed decorating the internal walls of nanochannels with host–guest systems for the construction of artificial ion gates . Recently, they described the visible-light-regulated chloride transport by introducing the ethyl-urea-derived pillararene into the nanochannel . Compared to other external-stimuli-responsive nanochannelssuch as those sensitive to light, − temperature, − and chirality , examples of gas-responsive nanochannels, − particularly CO 2 -responsive, are still rare.…”

Section: Introductionmentioning

confidence: 99%

“…49 Recently, they described the visible-lightregulated chloride transport by introducing the ethyl-ureaderived pillararene into the nanochannel. 50 Compared to other external-stimuli-responsive nanochannelssuch as those sensitive to light, 51−59 temperature, 60−63 and chirality 64,65  examples of gas-responsive nanochannels, 66−68 particularly CO 2 -responsive, are still rare. These results inspired us to design a macrocyclic receptor with CO 2 binding sites to better study CO 2 -activated ion nanochannels.…”

Section: ■ Introductionmentioning

confidence: 99%

Tailoring CO₂-Activated Ion Nanochannels Using Macrocyclic Pillararenes

Cheng

Liu

Han

et al. 2021

ACS Appl. Mater. Interfaces

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Gas-responsive nanochannels have great relevance for applications in many fields. Inspired by CO2-sensitive ion channels, herein we present an approach for designing solid-state nanochannels that allow controlled regulation of ion transport in response to alternate CO2/N2 stimuli. The pillar[5]arene (P5N) bearing diethylamine groups can convert into the water-soluble host P5C, containing cationic tertiary ammonium salt groups after absorbing CO2. Subsequently, the nanochannel walls are tailored using P5N-based host–guest chemistry. The ion transport rate of K+ in the P5N nanochannels under CO2 was 1.66 × 10–4 mol h–1 m–2, whereas that under N2 was 7.98 × 10–4 mol h–1 m–2. Notably, there was no significant change to the ion current after eight cycles, which may indicate the stability and repeatability of CO2-activated ion nanochannels. It is speculated that the difference in ion conductance resulted from the change in wettability and surface charge within the nanochannels in response to the gas stimuli. Achieving CO2-activated ion transport in solid-state nanochannels opens new avenues for biomimetic nanopore systems and advanced separation processes.

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A Visible‐Light‐Regulated Chloride Transport Channel Inspired by Rhodopsin

Cited by 32 publications

References 46 publications

Chiral Nanochannels of Ordered Mesoporous Silica Constructed by a Pillar[5]arene-Based Host–Guest System

Chiral Nanochannels of Ordered Mesoporous Silica Constructed by a Pillar[5]arene-Based Host–Guest System

Rational ion transport management mediated through membrane structures

Tailoring CO₂-Activated Ion Nanochannels Using Macrocyclic Pillararenes

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A Visible‐Light‐Regulated Chloride Transport Channel Inspired by Rhodopsin

Cited by 32 publications

References 46 publications

Chiral Nanochannels of Ordered Mesoporous Silica Constructed by a Pillar[5]arene-Based Host–Guest System

Chiral Nanochannels of Ordered Mesoporous Silica Constructed by a Pillar[5]arene-Based Host–Guest System

Rational ion transport management mediated through membrane structures

Tailoring CO2-Activated Ion Nanochannels Using Macrocyclic Pillararenes

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Product

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Tailoring CO₂-Activated Ion Nanochannels Using Macrocyclic Pillararenes