Carbon
dots (CDs) are relatively new and one of the most propitious
nanomaterials ever known to humanity, primarily consisting of a carbonized
carbon core with heteroatoms in organic functional groups attached.
CDs show various fascinating properties, such as tunable excitation/emission,
chemical inertness, photostability, low toxicity, good biocompatibility,
ease of handling, and eco-friendliness. Due to the anomalous optical
and chemical properties of the CDs, they have a wide range of applications
in the fields of bioimaging, biosensing, photocatalysis, optoelectronics,
etc. In this Review, we intend to cover the many strides in CDs chemistry,
which is an emerging paradigm, in conjunction with the most recent
discoveries of CDs with near-infrared fluorescence, phosphorescence,
electroluminescence, chirality, and antibacterial activity. Our main
emphasis will be on the contemporary evolution in synthetic strategies,
optical properties, and biomedical applications of CDs in nanomedicine
and nanotheranostics.
Carbon dots (CDs), with excellent optical property and cytocompatibility, are an ideal class of nanomaterials applied in the field of biomedicine. However, the weak response of CDs in the near‐infrared (NIR) region impedes their practical applications. Here, UV–vis–NIR full‐range responsive fluorine and nitrogen doped CDs (N‐CDs‐F) are designed and synthesized that own a favorable donor‐π‐acceptor (D‐π‐A) configuration and exhibit excellent two‐photon (λex = 1060 nm), three‐photon (λex = 1600 nm), and four‐photon (λex = 2000 nm) excitation upconversion fluorescence. D‐π‐A‐conjugated CDs prepared by solvothermal synthesis under the assistance of ammonia fluoride are reported and are endowed with larger multiphoton absorption (MPA) cross sections (3PA: 9.55 × 10−80 cm6 s2 photon−2, 4PA: 6.32 × 10−80 cm8 s3 photon−3) than conventional organic compounds. Furthermore, the N‐CDs‐F show bright deep‐red to NIR fluorescence both in vitro and in vivo, and can even stain the nucleoli of tumor cells. A plausible mechanism is proposed on the basis of the strong inter‐dot and intra‐dot hydrogen bonds through NH···F that can facilitate the expanding of conjugated sp2 domains, and thus not only result in lower highest occupied molecular orbital‐lowest unoccupied molecular orbital energy level but also larger MPA cross sections than those of undoped CDs.
Diabetic wounds, one of the most enervating complications of diabetes mellitus, affect millions of people worldwide annually. Vascular insufficiency, caused by hyperglycemia, is one of the primary causes and categories of diabetic impaired wound healing. Recently, long noncoding RNA (LncRNA)-H19, which is significantly decreased in diabetes and may be crucial in triggering angiogenesis, has attracted increasing interest. The possible relationship between the decrease of LncRNA-H19 and the impairment of angiogenesis in diabetes could involve impairment of the insulin–phosphatidylinositol 3-kinase (PI3K)–Akt pathway via the interdiction of LncRNA-H19. Thus, a therapeutic strategy utilizing LncRNA-H19 delivery is feasible. In this study, we investigated the possibility of using high-yield extracellular vesicle-mimetic nanovesicles (EMNVs) as an effective nano-drug delivery system for LncRNA, and studied the function of EMNVs with a high content of LncRNA-H19 (H19EMNVs). The results, which were exciting, showed that H19EMNVs had a strong ability to neutralize the regeneration-inhibiting effect of hyperglycemia, and could remarkably accelerate the healing processes of chronic wounds. Our results suggest that bioengineered EMNVs can serve as a powerful instrument to effectively deliver LncRNA and will be an extremely promising multifunctional drug delivery system in the immediate future.
Mitochondrial transfer plays a crucial role in the regulation of tissue homeostasis and resistance to cancer chemotherapy. Osteocytes have interconnecting dendritic networks and are a model to investigate its mechanism. We have demonstrated, in primary murine osteocytes with photoactivatable mitochondria (PhAM)floxed and in MLO-Y4 cells, mitochondrial transfer in the dendritic networks visualized by high-resolution confocal imaging. Normal osteocytes transferred mitochondria to adjacent metabolically stressed osteocytes and restored their metabolic function. The coordinated movement and transfer of mitochondria within the dendritic network rely on contact between the endoplasmic reticulum (ER) and mitochondria. Mitofusin 2 (Mfn2), a GTPase that tethers ER to mitochondria, predominantly mediates the transfer. A decline in Mfn2 expression with age occurs concomitantly with both impaired mitochondrial distribution and transfer in the osteocyte dendritic network. These data show a previously unknown function of ER-mitochondrial contact in mediating mitochondrial transfer and provide a mechanism to explain the homeostasis of osteocytes.
For the first time, portable visible-light photocatalysts were fabricated by in situ synthesizing Cu 2 O in the micropores of regenerated cellulose (RC)/graphene oxide (GO) composite films, in which the porous matrix was used as a microreactor for the formation of Cu 2 O nanoparticles. Cu 2 O nanoparticles were immobilized and evenly distributed in the RC matrix to excite and generate free photoelectrons and electron holes, leading to the high photodegradation efficiency against methyl orange dye under visible-light irradiation. Moreover, the introduction of GO has dramatically improved the photocatalytic activities of Cu 2 O nanoparticles in the Cu 2 O/GO/RC nanocomposite films, leading to a significant enhancement of the photodegradation rate from 2.0 to 6.5 mg h −1 g cat −1. In the Cu 2 O/GO/RC photocatalysts, Cu 2 O nanoparticles inside the matrix tended to generate on the GO sheets, which transferred the yielded photoelectrons to prevent local high potential zone generation and to induce the chain degradation reaction at more points, leading to the improvement of the photocatalyst activity. Moreover, the portable photocatalysts could be easily recycled and reused, showing great potential applications for wastewater purification by utilizing solar energy.
Summary
In this work, the binary N‐CDs@PANI hybrids were fabricated by introducing zero‐dimensional nitrogen‐doped carbon dots (N‐CDs) into reticulated PANI. Firstly, N‐CDs were prepared by one‐pot microwave method, and then, the N‐CDs were introduced into in situ oxidative polymerization of aniline (ANI) monomer. The N‐CDs with abundant functional groups and high electronic cloud density played a significant role in guiding the polyaniline‐ordered growth into intriguing morphologies. Moreover, morphology‐dependent electrochemical performances of N‐CDs@PANI hybrids were investigated and N‐CDs improve static interaction and enhance the special capacitances in the N‐CDs@PANI hybrids. Especially, the specific capacitance of PC4 hybrid can reach 785 F g−1, which exceed that of pure PANI (274 F g−1) at current density of 0.5 A g−1 according to three‐electrode measurement. And the capacitance retention of the PC4 hybrid still keeps 70% after 2000 cycles of charge and discharge. The N‐CDs@PANI hybrids can have potential applications in electrode materials, supercapacitors, nonlinear optics, and microwave absorption.
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