“…Among various allotropic forms of carbon, CNTs, which were discovered by Iijima in 1991, are another type of widely studied carbon‐based nanomaterials. [ 77,78 ] Arc‐discharge evaporation and chemical vapor deposition techniques are usually used to prepare CNTs. [ 77 ] Lin et al.…”
Section: Types Of Carbon‐based Fluorescent Nanomaterialsmentioning
confidence: 99%
“…[ 77,78 ] Arc‐discharge evaporation and chemical vapor deposition techniques are usually used to prepare CNTs. [ 77 ] Lin et al. prepared multiwalled CNTs by the chemical vapor deposition method.…”
Section: Types Of Carbon‐based Fluorescent Nanomaterialsmentioning
confidence: 99%
“…They show the following advantages: high optical absorptivity, adjustable fluorescent emission, chemical stability, well biocompatibility, and low toxicity. [ 5–99 ] Given these superior properties, they have been extensively discussed in bioimaging devices, biosensors, catalysts, photovoltaic devices, as well as fluorescent nanothermometers for spatially resolved temperature ( Figure ). [ …”
In recent years, carbon‐based fluorescent nanomaterials have been developed rapidly in biology and biomedicine due to their high optical absorptivity, adjustable fluorescent emission, chemical stability, well biocompatibility, and low toxicity. Their applications in temperature sensing have become one of the research hotspots. In this review, the authors summarize and sort out the carbon‐based fluorescent nanothermometers in the following work: 1) the types and temperature‐response mechanism of carbon‐based fluorescent nanomaterials are discussed; 2) the preparation methods of colorimetric fluorescent carbon‐based thermometers are introduced; 3) the applications of single/double emission carbon‐based fluorescent nanothermometers have been focused on. Finally, the authors give their own views on the future development direction of carbon‐based fluorescent nanothermometers. This review can provide guidance for the design and application of novel carbon‐based fluorescent nanothermometers.
“…Among various allotropic forms of carbon, CNTs, which were discovered by Iijima in 1991, are another type of widely studied carbon‐based nanomaterials. [ 77,78 ] Arc‐discharge evaporation and chemical vapor deposition techniques are usually used to prepare CNTs. [ 77 ] Lin et al.…”
Section: Types Of Carbon‐based Fluorescent Nanomaterialsmentioning
confidence: 99%
“…[ 77,78 ] Arc‐discharge evaporation and chemical vapor deposition techniques are usually used to prepare CNTs. [ 77 ] Lin et al. prepared multiwalled CNTs by the chemical vapor deposition method.…”
Section: Types Of Carbon‐based Fluorescent Nanomaterialsmentioning
confidence: 99%
“…They show the following advantages: high optical absorptivity, adjustable fluorescent emission, chemical stability, well biocompatibility, and low toxicity. [ 5–99 ] Given these superior properties, they have been extensively discussed in bioimaging devices, biosensors, catalysts, photovoltaic devices, as well as fluorescent nanothermometers for spatially resolved temperature ( Figure ). [ …”
In recent years, carbon‐based fluorescent nanomaterials have been developed rapidly in biology and biomedicine due to their high optical absorptivity, adjustable fluorescent emission, chemical stability, well biocompatibility, and low toxicity. Their applications in temperature sensing have become one of the research hotspots. In this review, the authors summarize and sort out the carbon‐based fluorescent nanothermometers in the following work: 1) the types and temperature‐response mechanism of carbon‐based fluorescent nanomaterials are discussed; 2) the preparation methods of colorimetric fluorescent carbon‐based thermometers are introduced; 3) the applications of single/double emission carbon‐based fluorescent nanothermometers have been focused on. Finally, the authors give their own views on the future development direction of carbon‐based fluorescent nanothermometers. This review can provide guidance for the design and application of novel carbon‐based fluorescent nanothermometers.
“…It determines the safety and, as a whole, the biocompatibility of NP and the effectiveness of treatment methods based on them, as well as the choice of analytical methods when using NP as a probe (biolabel, biosensor). Understanding of the mechanisms of interaction is important both for fundamental knowledge and for further development of applications [1].…”
The development of the application of nanoparticles for biomedical research and theranostics in many cases involves the injection of nanoparticles into the bloodstream. The interaction of nanoparticles with blood components and the circulatory system is one of the key points of the relevant study or treatment. In this review, the interaction of diamond nanoparticles with blood in vivo and in vitro is considered in terms of the nanodiamonds safety and hematocompatibility and biomedical applications.
“…Among them, Ishii introduced the current research status of nano-carbon-based thyroidectomy in China, analyzed some problems in nano-carbonbased thyroidectomy, proposed related solutions, and pointed out that nano-carbon is used as a tracer in resection; it plays an important role in surgery (6). Singh et al took 89 patients undergoing thyroidectomy under general anesthesia with remifentanil as experimental subjects, and conducted an analysis and research on the anesthesia effect of remifentanil, and found that 15 remifentanil has great potential to induce anesthesia hyperalgesia, among 89 patients, 13 had anesthesia hyperalgesia (7). Jiang et al introduced the relevant principles of the anesthetic effect of remifentanil in the article, pointed out that the analgesic effect of remifentanil disappeared too quickly when used for surgical anesthesia, and easily caused anesthesia hyperalgesia, and analyzed the related technology to overcome this problem (8).…”
Nano-carbon is often used as a tracer in thyroidectomy, to improve the accuracy of the operation. Remifentanil is the most commonly used anesthetic during thyroidectomy, but the use of remifentanil can sometimes cause patients with anesthesia hyperalgesia. Therefore, auxiliary anesthetics are often used in surgery to prevent remifentanil from causing anesthesia hyperalgesia. The purpose of this article is to explore the specific application effect of the fusion agent of hydromorphone and parecoxib sodium after thyroidectomy based on nano-carbon in the prevention of remifentanil-induced anesthesia hyperalgesia. Taking 60 patients who underwent thyroidectomy based on carbon nanotechnology in our hospital as the research object, the patients were divided into the parecoxib sodium group, hydromorphone control group and hydromorphone and parecoxib sodium fusion agent group. All patients were injected with remifentanil before surgery for general paralysis. Ten minutes before the end of the operation, the parecoxib sodium group was injected with quantitative parecoxib sodium, and the hydromorphone control group was injected with quantitative hydromorphone, hydromorphone and the parecoxib sodium fusion medicament group was injected with a quantitative combination of parecoxib sodium and hydromorphone. The patient's comfort, calmness, pain, adverse reactions and recovery time of consciousness were counted. The results of the study showed that the sedation score of the hydromorphone and parecoxib sodium fusion drug group was (15.8±1.5), the pain degree score was (1.9±0.5), lower than the other two groups, and the postoperative recovery time was (38±5.0) )min, lower than the other two groups. It can be seen that the use of a fusion agent of hydromorphone and parecoxib sodium after thyroidectomy based on nano-carbon is effective in preventing and reducing remifentanil-induced anesthesia hyperalgesia.
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