A Carbon Nanotube Optical Sensor Reports Nuclear Entry <i>via</i> a Noncanonical Pathway

Abstract:The combination of radioisotopes and nanomaterials is creating a new library of tracers for molecular imaging, exploiting the sensitivity of nuclear imaging techniques and the size-dependent properties of nanomaterials. This new approach is expanding the range of applications, including the possibility of theranostics. Among the many different combinations, the use of 68 Ga as the radioisotope in the radio-nanomaterial is particularly convenient. The physicochemical properties of this isotope allow incorporating it into many materials with great chemical flexibility. Furthermore, its production from a benchtop generator eases the preparation of the tracer. Here, we review main results from the last years in which a nanomaterial has been radiolabeled with 68 Ga. In thus process, we pay attention to the use of nanomaterials for biomedical imaging in general and main properties of this radioisotope. We study the main methods to carry out such radiolabeling and the most important applications for molecular imaging.

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“…Examples of these include Au nanoparticles [149,150], dendrimers [151,152], carbon nanotubes [153,154], or silica nanoparticles [155,156].…”

Section: Other Nanoparticlesmentioning

confidence: 99%

Molecular Imaging with 68Ga Radio-Nanomaterials: Shedding Light on Nanoparticles

et al. 2018

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“…[30] With the development of nanomaterials, different types of NIR light absorbing nanomaterials were reported and exhibited high photothermal energy conversion efficiencies. [31][32][33][34][35][36][37] Although diverse NIR photo thermal responsive nanomaterials have performed as promising photothermal nanotransducers in biological studies and biomedical applications, their applications in the remote and precise control of transgene expression of therapeutic agents in vivo remain to be explored. [38][39][40][41][42][43][44][45][46] Herein, we developed a bioengineered cell system with an artificial signaling circuit to remotely and precisely control the production of uPA for antithrombotic therapy in response to NIR light-caused photothermal effects with the help of nanotransducers (Scheme 1).…”

Section: Introductionmentioning

confidence: 99%

Near‐Infrared Light Activated Thermosensitive Ion Channel to Remotely Control Transgene System for Thrombolysis Therapy

Zhang

Lan

et al. 2019

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Current antithrombotic therapeutic strategies often suffer from severe post‐thrombotic syndromes (PTS), inconvenient daily subcutaneous injections for a long time and short circulation times accompanied by a dose‐dependent risk of intracranial hemorrhage. Aiming at noninvasive, on‐demand, and sustained antithrombotic therapy, a new thrombolysis approach based on the transgene system has been developed to remotely and precisely control the expression of urokinase plasminogen activator (uPA) by bioengineered cells for antithrombotic therapy both in vitro and in vivo. In this design, the near‐infrared (NIR) light could activate the expression of the thermosensitive TRPV1 channel in response to photothermal responsive nanotransducers to trigger the synthetic signaling pathway to secret uPA. By encapsulating bioengineered cells in injectable hydrogel to ensure long‐term survival and convenience for injection, the engineered cells could noninvasively and precisely control the production of uPA protein in situ via an NIR laser to significantly enhance the thrombolysis therapeutic effects by spatiotemporally controlling the local temperature, in both the microfluidic blood circulation mimic and the murine tail thrombus model. This novel thrombolysis approach could overcome some key limitations that are associated with conventional antithrombotic therapy, thus opening a new direction for developing remotely and precisely controllable continuous thrombolysis through artificially designed signaling.

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“…Polymers are attractive dispersing agents for SWNTs because they can wrap around the SWNT backbones attaching different functional moieties onto their sidewalls . The well‐established polymer wrapping method benefits from the tight and uniform enclosure of the SWNTs by the polymer, which endures filtration processes, modification of pH, and other environmental changes .…”

Section: Introductionmentioning

confidence: 99%

Fluorescent Polymer—Single‐Walled Carbon Nanotube Complexes with Charged and Noncharged Dendronized Perylene Bisimides for Bioimaging Studies

Huth

Glaeske

Achazi

et al. 2018

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Fluorescent nanomaterials are expected to revolutionize medical diagnostic, imaging, and therapeutic tools due to their superior optical and structural properties. Their inefficient water solubility, cell permeability, biodistribution, and high toxicity, however, limit the full potential of their application. To overcome these obstacles, a water-soluble, fluorescent, cytocompatible polymer-single-walled carbon nanotube (SWNT) complex is introduced for bioimaging applications. The supramolecular complex consists of an alkylated polymer conjugated with neutral hydroxylated or charged sulfated dendronized perylene bisimides (PBIs) and SWNTs as a general immobilization platform. The polymer backbone solubilizes the SWNTs, decorates them with fluorescent PBIs, and strongly improves their cytocompatibility by wrapping around the SWNT scaffold. In photophysical measurements and biological in vitro studies, sulfated complexes exhibit superior optical properties, cellular uptake, and intracellular staining over their hydroxylated analogs. A toxicity assay confirms the highly improved cytocompatibility of the polymer-wrapped SWNTs toward surfactant-solubilized SWNTs. In microscopy studies the complexes allow for the direct imaging of the SWNTs' cellular uptake via the PBI and SWNT emission using the 1st and 2nd optical window for bioimaging. These findings render the polymer-SWNT complexes with nanometer size, dual fluorescence, multiple charges, and high cytocompatibility as valuable systems for a broad range of fluorescence bioimaging studies.

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A Carbon Nanotube Optical Sensor Reports Nuclear Entry via a Noncanonical Pathway

Cited by 59 publications

References 46 publications

Molecular Imaging with 68Ga Radio-Nanomaterials: Shedding Light on Nanoparticles

Molecular Imaging with 68Ga Radio-Nanomaterials: Shedding Light on Nanoparticles

Near‐Infrared Light Activated Thermosensitive Ion Channel to Remotely Control Transgene System for Thrombolysis Therapy

Fluorescent Polymer—Single‐Walled Carbon Nanotube Complexes with Charged and Noncharged Dendronized Perylene Bisimides for Bioimaging Studies

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