Your search keyword '"H. Tunuguntla"' showing total 25 results

1. Decoupling copolymer, lipid and carbon nanotube interactions in hybrid, biomimetic vesicles

Author

Jeremy Sanborn, Jonathan R. I. Lee, Aleksandr Noy, Helgi I. Ingólfsson, Tony van Buuren, Thomas M. Weiss, Timothy S. Carpenter, Ramya H. Tunuguntla, Joshua A. Hammons, and Yun Chiao Yao

Subjects

Materials science, Nanotubes, Carbon, Small-angle X-ray scattering, Bilayer, Vesicle, Lipid Bilayers, Porins, Carbon nanotube, Molecular Dynamics Simulation, law.invention, Molecular dynamics, Membrane, X-Ray Diffraction, Chemical engineering, law, Amphiphile, Copolymer, General Materials Science

Abstract

Bilayer vesicles that mimic a real biological cell can be tailored to carry out a specific function by manipulating the molecular composition of the amphiphiles. These bio-inspired and bio-mimetic structures are increasingly being employed for a number of applications from drug delivery to water purification and beyond. Complex hybrid bilayers are the key building blocks for fully synthetic vesicles that can mimic biological cell membranes, which often contain a wide variety of molecular species. While the assembly and morpholgy of pure phospholid bilayer vesicles is well understood, the functionality and structure dramaticlly changes when copolymer and/or carbon nanotube porins (CNTP) are added. The aim of this study is to understand how the collective molecular interactions within hybrid vesicles affect their nanoscale structure and properties. In situ small and wide angle X-ray scattering (SAXS/WAXS) and molecular dynamics simulations (MD) are used to investigate the morphological effect of molecular interactions between polybutadiene polyethylene oxide, lipids and carbon nanotubes (CNT) within the hybrid vesicle bilayer. Within the lipid/copolymer system, the hybrid bilayer morphology transitions from phase separated lipid and compressed copolymer at low copolymer loadings to a mixed bilayer where opposing lipids are mostly separated from the inner region. This transition begins between 60 wt% and 70 wt%, with full homogenization observed by 80 wt% copolymer. The incorporation of CNT into the hybrid vesicles increases the bilayer thickness and enhances the bilayer symmetry. Analysis of the WAXS and MD indicate that the CNT-dioleoyl interactions are much stronger than the CNT-polybutadiene.

Published

2020

2. Enhanced water permeability and tunable ion selectivity in subnanometer carbon nanotube porins

Author

Aleksandr Noy, Robert Y. Henley, Tuan Anh Pham, Ramya H. Tunuguntla, Meni Wanunu, and Yun Chiao Yao

Subjects

Nanotube, Multidisciplinary, Water transport, Materials science, Ionic bonding, Portable water purification, Nanotechnology, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Ion, law.invention, Membrane technology, Chemical engineering, law, Water treatment, 0210 nano-technology

Abstract

Fast water transport through carbon nanotube pores has raised the possibility to use them in the next generation of water treatment technologies. We report that water permeability in 0.8-nanometer-diameter carbon nanotube porins (CNTPs), which confine water down to a single-file chain, exceeds that of biological water transporters and of wider CNT pores by an order of magnitude. Intermolecular hydrogen-bond rearrangement, required for entry into the nanotube, dominates the energy barrier and can be manipulated to enhance water transport rates. CNTPs block anion transport, even at salinities that exceed seawater levels, and their ion selectivity can be tuned to configure them into switchable ionic diodes. These properties make CNTPs a promising material for developing membrane separation technologies.

Published

2017

3. High-Yield Synthesis and Optical Properties of Carbon Nanotube Porins

Author

Frances I. Allen, Ramya H. Tunuguntla, Xi Chen, Aleksandr Noy, and Allison Belliveau

Subjects

Materials science, Sonication, Nanotechnology, Biological membrane, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, law.invention, Nanopore, symbols.namesake, General Energy, Membrane, law, Yield (chemistry), symbols, Molecule, Physical and Theoretical Chemistry, 0210 nano-technology, Raman spectroscopy

Abstract

Carbon nanotube porins (CNTPs) are a convenient membrane-based model system for studying nanofluidic transport that replicates a number of key structural features of biological membrane channels. We present a generalized approach for CNTP synthesis using sonochemistry-assisted segmenting of carbon nanotubes. Prolonged tip sonication in the presence of lipid molecules debundles and fragments long carbon nanotube aggregates into stable and water-soluble individual CNTPs with lengths in the range 5–20 nm. We discuss the main parameters that determine the efficiency and the yield of this process, describe the optimized conditions for high-yield CNTP synthesis, and demonstrate that this methodology can be adapted for synthesis of CNTPs of different diameters. We also present the optical properties of CNTPs and show that a combination of Raman and UV–vis–NIR spectroscopy can be used to monitor the quality of the CNTP synthesis. Overall, CNTPs represent a versatile nanopore building block for creating higher-ord...

Published

2017

4. Electronic control of H+ current in a bioprotonic device with carbon nanotube porins

Author

Zahra Hemmatian, Ramya H. Tunuguntla, Aleksandr Noy, Marco Rolandi, and Wanunu, Meni

Subjects

Cell Membranes, Lipid Bilayers, Biochemistry, law.invention, Cell membrane, Electricity, law, Nanotechnology, Lipid bilayer, Materials, Liposome, Multidisciplinary, Nanotubes, Physics, Lipids, Chemistry, medicine.anatomical_structure, Physical Sciences, Medicine, Engineering and Technology, Charge carrier, Carbon Nanotubes, Fullerenes, Cellular Structures and Organelles, Protons, Research Article, Chemical Elements, Materials science, Silicon, General Science & Technology, Science, Materials Science, chemistry.chemical_element, Porins, Electrons, Bioengineering, Carbon nanotube, Ion, medicine, Vesicles, Ion channel, Nanomaterials, Nuclear Physics, Nucleons, Electric Conductivity, Biology and Life Sciences, Cell Biology, Carbon, chemistry, Liposomes, Lipid Bilayer, Electronics

Abstract

Hybrid biotic abiotic devices can be used to interface electronics with biological systems for novel therapies or to increase device functionality beyond silicon. Many strategies exist to merge the electronic and biological worlds, one dominated by electrons and holes as charge carriers, the other by ions. In the biological world, lipid bilayers and ion channels are essential to compartmentalize the cell machinery and regulate ionic fluxes across the cell membrane. Here, we demonstrate a bioelectronic device in which a lipid bilayer supported on H+-conducting Pd/PdHx contacts contains carbon nanotubes porin (CNTP) channels. This bioelectronic device uses CNTPs to control of H+ flow across the lipid bilayer with a voltage applied to the Pd/PdHx contacts. Potential applications of these devices include local pH sensing and control.

Published

2019

5. Silicon Nanoribbon pH Sensors Protected by a Barrier Membrane with Carbon Nanotube Porins

Author

Aleksandr Noy, Huanan Zhang, Ramya H. Tunuguntla, and Xi Chen

Subjects

Materials science, Silicon, Biocompatibility, Mechanical Engineering, chemistry.chemical_element, Bioengineering, Nanotechnology, 02 engineering and technology, General Chemistry, Carbon nanotube, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, law.invention, Biofouling, chemistry, Coating, law, Porin, engineering, General Materials Science, 0210 nano-technology, Lipid bilayer, Biosensor

Abstract

Limited biocompatibility and fouling propensity can restrict real-world applications of a large variety of biosensors. Biological systems are adept at protecting and separating vital components of biological machinery with semipermeable membranes that often contain defined pores and gates to restrict transmembrane transport only to specific species. Here we use a similar approach for creating fouling-resistant pH sensors. We integrate silicon nanoribbon transistor sensors with an antifouling lipid bilayer coating that contains proton-permeable carbon nanotube porin (CNTP) channels and demonstrate robust pH detection in a variety of complex biological fluids.

Published

2018

6. Impact of PEG additives and pore rim functionalization on water transport through sub-1 nm carbon nanotube porins

Author

Ramya H. Tunuguntla, Aleksandr Noy, Yuliang Zhang, and Andrew Y. Hu

Subjects

Arrhenius equation, Water transport, Materials science, 02 engineering and technology, Activation energy, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, law.invention, Chaotropic agent, symbols.namesake, Chemical engineering, law, PEG ratio, symbols, Surface modification, Physical and Theoretical Chemistry, 0210 nano-technology, Lipid bilayer

Abstract

Carbon nanotubes represent one of the most interesting examples of a nanofluidic channel that combines extremely small diameters with atomically smooth walls and well-defined chemical functionalities at the pore entrance. In the past, sub-1 nm diameter carbon nanotube porins (CNTPs) embedded in a lipid membrane matrix demonstrated extremely high water permeabilities and strong ion selectivities. In this work, we explore additional factors that can influence transport in these channels. Specifically, we use stopped-flow transport measurements to focus on the effect of chemical modifications of the CNT rims and chaotropic polyethyleneglycol (PEG) additives on CNTP water permeability and Arrhenius activation energy barriers for water transport. We show that PEG, especially in its more chaotropic coiled configuration, enhances the water transport and reduces the associated activation energy. Removal of the static charges on the CNTP rim by converting –COOH groups to neutral methylamide groups also reduces the activation energy barriers and enhances water transport rates.

Published

2018

7. Carbon Nanotube Porins in Amphiphilic Block Copolymers as Fully Synthetic Mimics of Biological Membranes

Author

Aleksandr Noy, Christina C. Newcomb, Jeremy Sanborn, Anthony van Buuren, James J. De Yoreo, Joshua A. Hammons, Atul N. Parikh, Ramya H. Tunuguntla, Xi Chen, Jennifer A. Soltis, Yun Chiao Yao, and Yuliang Zhang

Subjects

Materials science, Polymers, Porins, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 01 natural sciences, law.invention, law, Amphiphile, General Materials Science, Nanotubes, Carbon, Mechanical Engineering, Biological membrane, Membranes, Artificial, 021001 nanoscience & nanotechnology, Small molecule, 0104 chemical sciences, Membrane, Mechanics of Materials, Permeability (electromagnetism), Porin, Polymersome, Biophysics, 0210 nano-technology, Hydrophobic and Hydrophilic Interactions

Abstract

Biological membranes provide a fascinating example of a separation system that is multifunctional, tunable, precise, and efficient. Biomimetic membranes, which mimic the architecture of cellular membranes, have the potential to deliver significant improvements in specificity and permeability. Here, a fully synthetic biomimetic membrane is reported that incorporates ultra-efficient 1.5 nm diameter carbon nanotube porin (CNTPs) channels in a block-copolymer matrix. It is demonstrated that CNTPs maintain high proton and water permeability in these membranes. CNTPs can also mimic the behavior of biological gap junctions by forming bridges between vesicular compartments that allow transport of small molecules.

Published

2018

8. Response to Comment on 'Enhanced water permeability and tunable ion selectivity in subnanometer carbon nanotube porins'

Author

Ramya H. Tunuguntla, Yuliang Zhang, Meni Wanunu, T. Anh Pham, Aleksandr Noy, Robert Y. Henley, and Yun Chiao Yao

Subjects

Arrhenius equation, Nanotube, Multidisciplinary, Materials science, Water transport, Ion selectivity, Nanotubes, Carbon, Porins, Water, Biological Transport, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Permeability, 0104 chemical sciences, law.invention, Permeability (earth sciences), symbols.namesake, Chemical physics, law, symbols, 0210 nano-technology, Leakage (electronics)

Abstract

Horner and Pohl argue that high water transport rates reported for carbon nanotube porins (CNTPs) originate from leakage at the nanotube-bilayer interface. Our results and new experimental evidence are consistent with transport through the nanotube pores and rule out a defect-mediated transport mechanism. Mechanistic origins of the high Arrhenius factor that we reported for narrow CNTPs at pH 8 require further investigation.

Published

2018

9. Real-time dynamics of carbon nanotube porins in supported lipid membranes visualized by high-speed atomic force microscopy

Author

Ramya H. Tunuguntla, Aleksandr Noy, Yuliang Zhang, and Pyung On Choi

Subjects

0301 basic medicine, Nanotube, Materials science, Lipid Bilayers, Porins, 02 engineering and technology, Carbon nanotube, Microscopy, Atomic Force, General Biochemistry, Genetics and Molecular Biology, law.invention, 03 medical and health sciences, Orientations of Proteins in Membranes database, law, Diffusion (business), Lipid bilayer, Nanotubes, Carbon, Dynamics (mechanics), Cell Membrane, Biological membrane, Articles, 021001 nanoscience & nanotechnology, Cell biology, 030104 developmental biology, Membrane, Biophysics, 0210 nano-technology, General Agricultural and Biological Sciences

Abstract

In-plane mobility of proteins in lipid membranes is one of the fundamental mechanisms supporting biological functionality. Here we use high-speed atomic force microscopy (HS-AFM) to show that a novel type of biomimetic channel—carbon nanotube porins (CNTPs)—is also laterally mobile in supported lipid membranes, mimicking biological protein behaviour. HS-AFM can capture real-time dynamics of CNTP motion in the supported lipid bilayer membrane, build long-term trajectories of the CNTP motion and determine the diffusion coefficients associated with this motion. Our analysis shows that diffusion coefficients of CNTPs fall into the same range as those of proteins in supported lipid membranes. CNTPs in HS-AFM experiments often exhibit ‘directed’ diffusion behaviour, which is common for proteins in live cell membranes. This article is part of the themed issue ‘Membrane pores: from structure and assembly, to medicine and technology’.

Published

2017

10. Osmotically-Driven Transport in Carbon Nanotube Porins

Author

Kyunghoon Kim, Ramya H. Tunuguntla, Luis R. Comolli, Aleksandr Noy, Caroline M. Ajo-Franklin, Costas P. Grigoropoulos, and Jia Geng

Subjects

Chemistry, Mechanical Engineering, Ionic bonding, Bioengineering, Nanotechnology, General Chemistry, Carbon nanotube, Condensed Matter Physics, Electrostatics, Ion, law.invention, Nanopore, Membrane, Chemical physics, law, Permeability (electromagnetism), General Materials Science, Lipid bilayer

Abstract

We report the measurements of transport of ions and uncharged species through carbon nanotube (CNT) porins--short segments of CNTs inserted into a lipid bilayer membrane. Rejection characteristics of the CNT porins are governed by size exclusion for the uncharged species. In contrast, rejection of ionic species is governed by the electrostatic repulsion and Donnan membrane equilibrium. Permeability of monovalent cations follows the general trend in the hydrated ion size, except in the case of Cs(+) ions.

Published

2014

11. Ionic Transport through 1.5 NM Diameter Carbon Nanotube Porins

Author

Aleksandr Noy, Ramya H. Tunuguntla, Meni Wanunu, Yun Chiao Yao, and Robert Y. Henley

Subjects

Materials science, Chemical engineering, law, Biophysics, Ionic bonding, Carbon nanotube, law.invention

Published

2018

12. Membranes: Carbon Nanotube Porins in Amphiphilic Block Copolymers as Fully Synthetic Mimics of Biological Membranes (Adv. Mater. 51/2018)

Author

Jeremy Sanborn, Yun Chiao Yao, Jennifer A. Soltis, Xi Chen, Aleksandr Noy, Yuliang Zhang, Christina C. Newcomb, Anthony van Buuren, Atul N. Parikh, James J. De Yoreo, Joshua A. Hammons, and Ramya H. Tunuguntla

Subjects

Membrane, Materials science, Chemical engineering, Mechanics of Materials, law, Mechanical Engineering, Amphiphile, Polymersome, Copolymer, General Materials Science, Biological membrane, Carbon nanotube, law.invention

Published

2018

13. Synthesis, lipid membrane incorporation, and ion permeability testing of carbon nanotube porins

Author

Artur Escalada, Vadim A. Frolov, Ramya H. Tunuguntla, and Aleksandr Noy

Subjects

Ion permeability, Chemistry, Phospholipid, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, 0104 chemical sciences, law.invention, Nanopore, chemistry.chemical_compound, Membrane, law, Biophysics, 0210 nano-technology, Lipid bilayer, Ion transporter, Ion channel

Abstract

Carbon nanotube porins (CNTPs) are 10- to 20-nm-long segments of lipid-stabilized single-walled carbon nanotubes (CNTs) that can be inserted into phospholipid membranes to form nanometer-scale-diameter pores that approximate the geometry and many key transport characteristics of biological membrane channels. We describe protocols for CNTP synthesis by ultrasound-assisted cutting of long CNTs in the presence of lipid amphiphiles, and for validation of CNTP incorporation into a lipid membrane using a proton permeability assay. In addition, we describe protocols for measuring conductance of individual CNTPs in planar lipid bilayers and plasma membranes of live cells. The protocol for the preparation and testing of the CNTPs in vesicle systems takes 3 d, and single CNTP conductance measurements take 2-5 h. The CNTPs produced by this cutting protocol remain stable and active for at least 10-12 weeks.

Published

2016

14. Ultrafast proton transport in sub-1-nm diameter carbon nanotube porins

Author

Kyunghoon Kim, Aleksandr Noy, Frances I. Allen, Allison Belliveau, and Ramya H. Tunuguntla

Subjects

Nanotube, Materials science, Proton, Biomedical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 01 natural sciences, law.invention, Ion, chemistry.chemical_compound, law, Nafion, Proton transport, General Materials Science, Electrical and Electronic Engineering, Proton conductor, Conductance, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, chemistry, Chemical physics, 0210 nano-technology

Abstract

Proton transport plays an important role in many biological processes due to the ability of protons to rapidly translocate along chains of hydrogen-bonded water molecules. Molecular dynamics simulations have predicted that confinement in hydrophobic nanochannels should enhance the rate of proton transport. Here, we show that 0.8-nm-diameter carbon nanotube porins, which promote the formation of one-dimensional water wires, can support proton transport rates exceeding those of bulk water by an order of magnitude. The transport rates in these narrow nanotube pores also exceed those of biological channels and Nafion. With larger 1.5-nm-diameter nanotube porins, proton transport rates comparable to bulk water are observed. We also show that the proton conductance of these channels can be modulated by the presence of Ca(2+) ions. Our results illustrate the potential of small-diameter carbon nanotube porins as a proton conductor material and suggest that strong spatial confinement is a key factor in enabling efficient proton transport.

Published

2015

15. Polymersome Membrane Permeability and Ionic Transport Properties in the Presence of Sub-2nm Carbon Nanotube Porins

Author

Atul N. Parikh, Aleksandr Noy, Ramya H. Tunuguntla, and Jeremy Sanborn

Subjects

chemistry.chemical_classification, Materials science, Membrane permeability, Synthetic membrane, Biophysics, Nanotechnology, Polymer, Carbon nanotube, law.invention, Membrane, Chemical engineering, chemistry, law, Permeability (electromagnetism), Polymersome, Lipid bilayer

Abstract

Synthetic diblock and triblock copolymer membranes are semi-permeable barriers that are capable of self-assembly into tunable membranes, which have contrasting mechanical properties from biologically derived and synthetic lipid bilayers. These thick and “robust” polymer membranes are typically thicker and have significantly reduced water permeability compared to lipid bilayers. These properties make them valuable alternative membranes for applications requiring exposure to physical stresses such as biosensors, drug delivery, and filtration. Previous attempts to engineer the permeability of these membranes included insertion of protein channels to improve permeably, (eg. Aquaporins), changing the polymer constituent to an inherently leaky polymer (eg. polystyrene-b-polyisocyanoalanine(2-thiophene-3-yl-ethyl)amide (PS-PIAT)), and removal of lipids from a mixed lipid-polymer vesicle following cross-linking and hydrolysis. We report a new strategy for improving permeability of polymer-membranes, based on incorporation of carbon nanotube porins into the polymer matrix. These short CNT pores exhibit the excellent transport properties inherent to carbon nanotubes, but are small enough that they can be easily incorporated into the membrane essentially acting as protein channel mimics. Here, we examine the permeability of diblock co-polymer membranes with and without these CNT pores and report the enhancement of permeability and ion transport characteristics of these novel membrane constructs.

Published

2016

16. Tunable Ion Selectivity in Sub-Nanometer Diameter Carbon Nanotube Porins

Author

Robert Y. Henley, Yun Chiao Yao, Aleksandr Noy, Meni Wanunu, Pradeep Waduge, and Ramya H. Tunuguntla

Subjects

chemistry.chemical_classification, Water transport, Materials science, Bilayer, Inorganic chemistry, Biophysics, Ionic bonding, Salt (chemistry), Carbon nanotube, law.invention, Nanopore, Chemical engineering, chemistry, law, Lipid bilayer, Selectivity

Abstract

Carbon nanotube porins (CNTPs), ultra-short carbon nanotubes (5-20nm) that can self-insert into lipid bilayers, allow single-channel planar lipid bilayer measurements of ionic transport through carbon nanotube (CNT) pores. CNTs with sub-nanometer diameters have been predicted to display ultra-fast water transport and high levels of ionic exclusion resulting from one-dimensional water wire transport through their hydrophobic cores. Here, we show that ultra-short 0.8-nm-diameter CNTPs, can spontaneously insert into lipid bilayers to form highly cation selective channels that exhibit low ionic conductance. Using reversal potential in various asymmetric salt conditions, we observe that these CNTPs exhibit large permselectivity values, corresponding to a high selectivity for both potassium and sodium over chloride. We also show evidence that neutralization of charges on the CNTs enhances ion selectivity. We also show that by using a solid-state nanopore to act as a support and form a completely solvent-free bilayer system, we can observe extremely stable ionic currents through these nanotubes, in contrast to previous reports with solvent containing bilayers. These results establish CNTPs as a promising biomimetic platform for developing cell interfaces, creating stochastic sensors, and water desalination.

Published

2017

17. Single-Channel Measurements of Conductance through Sub-Nanometer Carbon Nanotube Porins

Author

Robert Y. Henley, Aleksandr Noy, Ramya H. Tunuguntla, Yun Chiao Yao, and Meni Wanunu

Subjects

Nanotube, Nanopore, Membrane, Materials science, law, Biophysics, Conductance, Nanotechnology, Carbon nanotube, Reversal potential, Ion transporter, Ion, law.invention

Abstract

Carbon nanotubes (CNTs) have narrow hydrophobic inner pores, highly reminiscent of protein channels, that enable fast transport of water and ions. Their rigid structure and chemical robustness allow for diverse ex vivo applications. We have recently reported biomimetic membrane channels cased on carbon nanotubes—carbon nanotube porins (CNTPs). We have shown that CNTPs self-insert into lipid membranes and form stable pores. In this study, we used electrophysiological single-channel measurements to quantify ion conductance and selectivity of 0.8 nm diameter CNTPs. We report the conductance of single CNTP channels, as well as the scaling of the conductance with the ion concentration. We also used the reversal potential measurements to characterize the selectivity of the ion transport and found that CNTPs are highly selective to cations over anions. We will discuss the mechanism of this selectivity, and demonstrate ways to control it. These findings are important and relevant for developing CNTPs into a potential candidate nanopore for water treatment applications. Our studies on intrinsic characterization of CNTP transport properties will also enable researchers to consider this new material for a variety of biophysical applications.

Published

2017

18. Bioelectronic light-gated transistors with biologically tunable performance

Author

Caroline M. Ajo-Franklin, Costas P. Grigoropoulos, Aleksandr Noy, Mangesh Bangar, Ramya H. Tunuguntla, Kyunghoon Kim, and Pieter Stroeve

Subjects

Models, Molecular, Silicon, Materials science, Light, Transistors, Electronic, Lipid Bilayers, Nanowire, Molecular Conformation, Nanotechnology, law.invention, Ion, law, General Materials Science, chemistry.chemical_classification, Bioelectronics, biology, Nanowires, Mechanical Engineering, Biomolecule, Bilayer, Transistor, Membrane Proteins, Bacteriorhodopsin, Kinetics, chemistry, Mechanics of Materials, biology.protein, Protons, Biological regulation

Abstract

Light-activated bioelectronic silicon nanowire transistor devices are made by fusing proteoliposomes containing a bacteriorhodopsin (bR) proton pump onto the nanowire surface. Under green-light illumination, bR pumps protons toward the nanowire, and the pH gradient developed by the pump changes the transistor output. Furthermore, co-assembly of small biomolecules that alter the bilayer permeability to other ions can upregulate and downregulate the response of field-effect transistor devices.

Published

2014

19. Carbon nanotube sizing and quantification

Author

Allison Belliveau, Aleksandr Noy, and Ramya H. Tunuguntla

Subjects

Materials science, law, Nanotechnology, Carbon nanotube, Sizing, law.invention

Published

2014

20. Light-Powered Bionanoelectronic Devices with Biologically-Tunable Performance Characteristics

Author

Kyunghoon Kim, Aleksandr Noy, Mangesh Bangar, Ramya H. Tunuguntla, Pieter Stroeve, and Caroline M. Ajo-Franklin

Subjects

Materials science, biology, Bilayer, Transistor, Nanowire, Biophysics, Nanotechnology, Bacteriorhodopsin, law.invention, law, biology.protein, Overall performance, Lipid bilayer, Electrochemical gradient, Ion channel

Abstract

Bacteriorhodopsin (bR) is a well-characterized photoactivated proton pump capable of creating a proton gradient using the energy of absorbed light. We are developing a bioelectronic platform that couples bacteriorhodopsin activity with the electronic response of a nanowire field-effect transistor. To accomplish this task we use hierarchical assembly of lipids and membrane proteins into a 1-D lipid bilayer structure covering the channel region of the transistor device. This presentation discusses the device preparation, characterization, and overall performance. In addition, we present results showing how other ion channels and ionophores, co-assembled with the protein embedded bilayer, can be used to change various performance characteristics of the device, independent of one-another. The ability to use components of the biological "toolkit" to fine-tune bioelectronic devices could have important implications for design of next generation biointerfaces.

Published

2014

21. Stochastic transport through carbon nanotubes in lipid bilayers and live cell membranes

Author

Artur Escalada, Ramya H. Tunuguntla, Aleksandr Noy, Kang Rae Cho, Jianfei Zhang, Vadim A. Frolov, Frances I. Allen, Y. Morris Wang, Anna V. Shnyrova, Luis R. Comolli, Kyunghoon Kim, Dayannara Munoz, Caroline M. Ajo-Franklin, Costas P. Grigoropoulos, and Jia Geng

Subjects

Materials science, Cell Survival, Lipid Bilayers, Porins, Nanotechnology, Carbon nanotube, CHO Cells, Ion Channels, law.invention, Cricetulus, law, Animals, Humans, Lipid bilayer, Liposome, Stochastic Processes, Multidisciplinary, Nanotubes, Carbon, Cell Membrane, Biological membrane, Biological Transport, DNA, Membrane transport, Nanopore, Membrane, HEK293 Cells, Liposomes, Membrane channel

Abstract

Short carbon nanotubes spontaneously insert into lipid bilayers and live cell membranes to form channels with useful and tunable transport properties that make them a promising biomimetic nanopore platform for developing cell interfaces, studying nanofluidic transport in biological channels, and creating stochastic sensors. Synthetic analogues of biological membrane channels that match the latter's high efficiency and exquisite selectivity for transporting ions and molecules could find many applications. Although it is possible to produce nanopores of a size comparable to that of protein channels, replicating their affinity and transport properties remains challenging. Jia Geng et al. now show that short (10-nm-long) single-wall carbon nanotubes spontaneously insert into lipid bilayers and live cell membranes to form channels with useful and tuneable transport properties. These carbon-nanotube channel-forming molecules or porins offer a promising biomimetic nanopore platform for developing cell interfaces, studying transport in biological channels, and creating stochastic sensors. There is much interest in developing synthetic analogues of biological membrane channels1 with high efficiency and exquisite selectivity for transporting ions and molecules. Bottom-up2 and top-down3 methods can produce nanopores of a size comparable to that of endogenous protein channels, but replicating their affinity and transport properties remains challenging. In principle, carbon nanotubes (CNTs) should be an ideal membrane channel platform: they exhibit excellent transport properties4,5,6,7,8 and their narrow hydrophobic inner pores mimic structural motifs typical of biological channels1. Moreover, simulations predict that CNTs with a length comparable to the thickness of a lipid bilayer membrane can self-insert into the membrane9,10. Functionalized CNTs have indeed been found to penetrate lipid membranes and cell walls11,12, and short tubes have been forced into membranes to create sensors13, yet membrane transport applications of short CNTs remain underexplored. Here we show that short CNTs spontaneously insert into lipid bilayers and live cell membranes to form channels that exhibit a unitary conductance of 70–100 picosiemens under physiological conditions. Despite their structural simplicity, these ‘CNT porins’ transport water, protons, small ions and DNA, stochastically switch between metastable conductance substates, and display characteristic macromolecule-induced ionic current blockades. We also show that local channel and membrane charges can control the conductance and ion selectivity of the CNT porins, thereby establishing these nanopores as a promising biomimetic platform for developing cell interfaces, studying transport in biological channels, and creating stochastic sensors.

Published

2013

22. pH Sensing with Silicon Nanoribbon Devices Modified with Carbon Nanotube Porins

Author

Aleksandr Noy, Ramya H. Tunuguntla, Huanan Zhang, and Scott Dhuey

Subjects

Materials science, Silicon, Biocompatibility, Biophysics, chemistry.chemical_element, Nanotechnology, Carbon nanotube, law.invention, chemistry, law, Nanometre, Field-effect transistor, Lipid bilayer, Biosensor, Electrical conductor

Abstract

Acidity of the local microenvironments is an important parameter for detection of pathological conditions and understanding of cellular mechanisms. Silicon nanoribbon field effect transistor (FET) has been proved to be a high-throughput and sensitive platform for pH sensing. However, the efficiency of these sensors is limited by the biocompatibility of silicon material and its tendency for bio-fouling. Recent studies have demonstrated sub-2nm diameter carbon nanotube (CNT) porins embedded in lipid bilayers are fast and efficient proton conductors. In this research, we focus on a bioelectronic approach toward designing pH-sensing devices. We will describe an organic/inorganic hybrid device that combines nanoribbon FET with self-assembled CNT/lipid bilayer for pH sensing in physiological conditions. Finally, we will also discuss its potential application in nanometer spatial resolution intracellular biosensing.

Published

2016

23. Transistors: Bioelectronic Light-Gated Transistors with Biologically Tunable Performance (Adv. Mater. 5/2015)

Author

Mangesh Bangar, Pieter Stroeve, Kyunghoon Kim, Ramya H. Tunuguntla, Caroline M. Ajo-Franklin, Costas P. Grigoropoulos, and Aleksandr Noy

Subjects

Bioelectronics, Materials science, Mechanics of Materials, law, business.industry, Mechanical Engineering, Transistor, Optoelectronics, General Materials Science, Nanotechnology, Biological regulation, business, law.invention

Abstract

Author(s): Tunuguntla, Ramya H; Bangar, Mangesh A; Kim, Kyunghoon; Stroeve, Pieter; Grigoropoulos, Costas; Ajo-Franklin, Caroline M; Noy, Aleksandr

Published

2015

24. Osmotically-Driven Transport through Carbon Nanotube Pores

Author

Aleksandr Noy, Caroline M. Ajo-Franklin, Ramya H. Tunuguntla, Costas P. Grigoropoulos, Jia Geng, and Kyunghoon Kim

Subjects

Quantitative Biology::Biomolecules, Physics::Biological Physics, Nanotube, Water transport, Materials science, Biophysics, Nanotechnology, Carbon nanotube, Ion, law.invention, Quantitative Biology::Subcellular Processes, Chemical species, Dynamic light scattering, Chemical engineering, law, Ion transporter, Ion channel

Abstract

Ion and water transport through biological membranes by osmosis is essential in many biological processes and the complex nature of biological pores and channels involved in these processes is not fully understood. We are developing simplified robust models of ion channels based on smooth, narrow and hydrophobic pores of carbon nanotubes. Incorporation of these pores into liposomes gives us a convenient system to study osmotically-induced transport using dynamic light scattering. We will present our measurements of the transport of charged and uncharged chemical species through the carbon nanotube pores and also discuss the role of the charges at the nanotube pore ends in regulating the ion transport selectivity.

25. Stochastic Gating and Molecular Transport in Carbon Nanotube Ion Channels

Author

Kyunghoon Kim, Aleksandr Noy, Ramya H. Tunuguntla, Jia Geng, and Caroline M. Ajo-Franklin

Subjects

Nanopore, Membrane, Materials science, law, Biophysics, Nanotechnology, Biological membrane, Gating, Carbon nanotube, Lipid bilayer, Ion channel, Ion, law.invention

Abstract

Living systems control transport of ions or small molecules across biological membranes using ion channels that form highly efficient and selective pores in lipid bilayers. Although bottom-up synthesis and top-down fabrication could produce pores of comparable size, an unresolved challenge remains to build nanopore scaffolds that fully replicate transport properties of membrane channels. We will show that pores in lipid membranes formed by ultra-short carbon nanotubes (CNTs) have transport properties that come remarkably close to that goal. These carbon nanotube channels can transport water, protons, small ions, and DNA and their ion-rejection properties can be controlled by the charge at the pore mouth. Interestingly, these pores also display the stochastic "gating" behavior common for biological ion channels. We attribute this effect to a spontaneous reversible ionic "penetration-exclusion" transition, suggesting that it represents a general feature of nanofluidic transport in sub-2-nm pores. Overall, transmembrane CNT ion channels represent a robust and versatile biomimetic scaffold for studying fundamentals of transport in biological channels, artificial cell design, and stochastic sensing.