In einer Umgebung, die reich an protonierenden oder oxidierenden Spezies ist (z. B. in Krebszellen), wird die Hauptabsorptionsbande sphärischer, wasserlöslicher Polyanilin‐Nanopartikel in den Nah‐Infrarot(NIR)‐Bereich verschoben. Verursacht wird dies durch die Bildung des Emeraldinsalzes (siehe Bild). Die dotierten Nanopartikel verursachen eine photothermische Ablation von Krebszellen bei NIR‐Laserbestrahlung in vitro und in vivo.
Well-designed nanoparticle-mediated, image-guided cancer therapy has attracted interest for increasing the efficacy of cancer treatment. A new class of smart theragnostic nanoprobes employing cetuximab (CET)-conjugated polyethylene glycol (PEG)ylated gold nanorods (CET-PGNRs) is presented; these nanoprobes target epithelial cancer cells using near-infrared light. The cetyltrimethylammonium bromide bilayer on GNRs is replaced with heterobifunctional PEG (COOH-PEG-SH) to serve as a biocompatible stabilizer and to increase specificity. The carboxylated GNRs are further functionalized with CET using 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide/N-hydroxysuccinimide (EDC-NHS) chemistry. To assess the potential of such GNRs, their optical properties, biocompatibility, colloidal stability, in vitro/in vivo binding affinities for cancer cells, absorption imaging, and photothermal therapy effects are investigated. CET-PGNRs exhibit excellent tumor targeting ability and strong potential for simultaneous absorption imaging and photothermal ablation of epithelial cancer cells.
Rapid and precise detection of pathogens is a critical
step in
the prevention and identification of emergencies related to health
and biosafety as well as the clinical management of community-acquired
urinary tract infections or sexually transmitted diseases. However,
a conventional culture-based pathogen diagnostic method is time-consuming,
permitting physicians to use antibiotics without ample clinical data.
Here, we present a nanophotonic Light-driven Integrated cell lysis and polymerase chain reaction (PCR)
on a chip with Gravity-driven cell enrichment Health Technology (LIGHT) for
rapid precision detection of pathogens (<20 min). We created the
LIGHT, which has the three functions of (1) selective enrichment of
pathogens, (2) photothermal cell lysis, and (3) photonic PCR on a
chip. We designed the gravity-driven cell enrichment via a nanoporous
membrane on a chip that allows an effective bacterial enrichment of
40 000-fold from a 1 mL sample in 2 min. We established a light-driven
photothermal lysis of preconcentrated bacteria within 1 min by designing
the network of nanoplasmonic optical antenna on a chip for ultrafast
light-to-heat conversion, created the nanoplasmonic optical antenna
network-based ultrafast photonic PCR on a chip, and identified Escherichia coli. Finally, we demonstrated the end-point
detection of up to 103 CFU/mL of E. coli in 10 min. We believe that our nanophotonic LIGHT will provide rapid
and precise identification of pathogens in both developing and developed
countries.
Targeted drug delivery using a microrobot is a promising technique capable of overcoming the limitations of conventional chemotherapy that relies on body circulation. However, most studies of microrobots used for drug delivery have only demonstrated simple mobility rather than precise targeting methods and prove the possibility of biodegradation of implanted microrobots after drug delivery. In this study, magnetically guided self‐rolled microrobot that enables autonomous navigation‐based targeted drug delivery, real‐time X‐ray imaging, and microrobot retrieval is proposed. The microrobot, composed of a self‐rolled body that is printed using focused light and a surface with magnetic nanoparticles attached, demonstrates the loading of doxorubicin and an X‐ray contrast agent for cancer therapy and X‐ray imaging. The microrobot is precisely mobilized to the lesion site through automated targeting using magnetic field control of an electromagnetic actuation system under real‐time X‐ray imaging. The photothermal effect using near‐infrared light reveals rapid drug release of the microrobot located at the lesion site. After drug delivery, the microrobot is recovered without potential toxicity by implantation or degradation using a magnetic‐field‐switchable coiled catheter. This microrobotic approach using automated control method of the therapeutic agents‐loaded microrobot has potential use in precise localized drug delivery systems.
By loading Gd(III) inside NIR-absorbing polyaniline nanostructures, a novel diagnostic and photothermal agent with enhanced MR sensitivity, targeting ability, and photothermal ability to treat epithelial cancer is developed.
Frequency upconversion activated with lanthanide has attracted attention in various real-world applications, because it is far simpler and more efficient than traditional nonlinear susceptibility-based frequency upconversion, such as second harmonic generation. However, the quantum yield of frequency upconversion of lanthanide-based upconversion nanocrystals remains inefficient for practical applications, and spatial control of upconverted emission is not yet developed. Here, we developed an asymmetric nanocrescent antenna on upconversion nanocrystal (ANAU) to deliver excitation light effectively to the core of upconversion nanocrystal by nanofocusing light and generating asymmetric frequency upconverted emission concentrated toward the tip region. ANAUs were fabricated by high-angle deposition (60°) of gold (Au) on the isolated upconversion nanoparticles supported by nanopillars then moved to refractive-index matched substrate for orientation-dependent upconversion luminescence analysis in the single-nanoparticle scale. We studied shape-dependent nanofocusing efficiency of nanocrescent antennae as a function of the tip-to-tip distance by modulating the deposition angle. The generation of asymmetric frequency upconverted emission toward the tip region was simulated by the asymmetric far-field radiation pattern of dipoles in the nanocrescent antenna and experimentally demonstrated by the orientation-dependent photon intensity of frequency upconverted emission of an ANAU. This finding provides a new way to improve frequency upconversion using an antenna, which locally increases the excitation light and generates the radiation power to certain directions for various applications.
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