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      Biocompatible Carbon Nanotube–Chitosan Scaffold Matching the Electrical Conductivity of the Heart

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          Abstract

          The major limitation of current engineered myocardial patches for the repair of heart defects is that insulating polymeric scaffold walls hinder the transfer of electrical signals between cardiomyocytes. This loss in signal transduction results in arrhythmias when the scaffolds are implanted. We report that small, subtoxic concentrations of single-walled carbon nanotubes, on the order of tens of parts per million, incorporated in a gelatin–chitosan hydrogel act as electrical nanobridges between cardiomyocytes, resulting in enhanced electrical coupling, synchronous beating, and cardiomyocyte function. These engineered tissues achieve excitation conduction velocities similar to native myocardial tissue (22 ± 9 cm/s) and could function as a full-thickness patch for several cardiovascular defect repair procedures, such as right ventricular outflow track repair for Tetralogy of Fallot, atrial and ventricular septal defect repair, and other cardiac defects, without the risk of inducing cardiac arrhythmias.

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          Most cited references42

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          Carbon nanotubes: present and future commercial applications.

          Worldwide commercial interest in carbon nanotubes (CNTs) is reflected in a production capacity that presently exceeds several thousand tons per year. Currently, bulk CNT powders are incorporated in diverse commercial products ranging from rechargeable batteries, automotive parts, and sporting goods to boat hulls and water filters. Advances in CNT synthesis, purification, and chemical modification are enabling integration of CNTs in thin-film electronics and large-area coatings. Although not yet providing compelling mechanical strength or electrical or thermal conductivities for many applications, CNT yarns and sheets already have promising performance for applications including supercapacitors, actuators, and lightweight electromagnetic shields.
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            Band gap fluorescence from individual single-walled carbon nanotubes.

            Fluorescence has been observed directly across the band gap of semiconducting carbon nanotubes. We obtained individual nanotubes, each encased in a cylindrical micelle, by ultrasonically agitating an aqueous dispersion of raw single-walled carbon nanotubes in sodium dodecyl sulfate and then centrifuging to remove tube bundles, ropes, and residual catalyst. Aggregation of nanotubes into bundles otherwise quenches the fluorescence through interactions with metallic tubes and substantially broadens the absorption spectra. At pH less than 5, the absorption and emission spectra of individual nanotubes show evidence of band gap-selective protonation of the side walls of the tube. This protonation is readily reversed by treatment with base or ultraviolet light.
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              Strong, light, multifunctional fibers of carbon nanotubes with ultrahigh conductivity.

              Broader applications of carbon nanotubes to real-world problems have largely gone unfulfilled because of difficult material synthesis and laborious processing. We report high-performance multifunctional carbon nanotube (CNT) fibers that combine the specific strength, stiffness, and thermal conductivity of carbon fibers with the specific electrical conductivity of metals. These fibers consist of bulk-grown CNTs and are produced by high-throughput wet spinning, the same process used to produce high-performance industrial fibers. These scalable CNT fibers are positioned for high-value applications, such as aerospace electronics and field emission, and can evolve into engineered materials with broad long-term impact, from consumer electronics to long-range power transmission.
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                Author and article information

                Journal
                ACS Nano
                ACS Nano
                nn
                ancac3
                ACS Nano
                American Chemical Society
                1936-0851
                1936-086X
                18 September 2015
                18 September 2014
                28 October 2014
                : 8
                : 10
                : 9822-9832
                Affiliations
                [a] Department of Bioengineering and Department of Chemical & Biomolecular Engineering, Department of Chemistry, Department of Materials Science & NanoEngineering, and The Smalley Institute for Nanoscale Science & Technology, Rice University , Houston, Texas 77005, United States
                [§ ]Division of Congenital Heart Surgery, Texas Children’s Hospital , Houston, Texas 77030, United States
                Author notes
                [* ]Address correspondence to jeff.jacot@ 123456rice.edu .
                Article
                10.1021/nn503693h
                4212726
                25233037
                88f7ce27-7111-4de7-b1e1-4218c9ad1ab6
                Copyright © 2014 American Chemical Society

                Terms of Use

                History
                : 07 July 2014
                : 18 September 2014
                Funding
                National Institutes of Health, United States
                Categories
                Article
                Custom metadata
                nn503693h
                nn-2014-03693h

                Nanotechnology
                carbon nanotubes,tissue engineering,cardiomyocytes,heart defects,conduction velocity,action potential

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