2023
DOI: 10.1002/viw.20220059
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Optical biosensing systems for a biological living body

Abstract: With the development of technology, biosensors are increasingly used in the biomedical field. Due to the high sensitivity of optical signals, good stability, high signal‐to‐noise ratio, and different spectral characteristics of different analytes, optical biosensors can achieve direct and real‐time detection of analytes with high specificity compared with traditional analytical techniques. In view of the rapid development of optical biosensors for in vivo applications and their promising future, we have attemp… Show more

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Cited by 9 publications
(5 citation statements)
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“…Light can be precisely manipulated with high spatial and temporal accuracy, prompting researchers to extensively explore various photoresponsive compounds for applications in life sciences research. [ 41 ] Among these, azobenzene is one of the most popular and reliable photoisomerizing molecular functional group. Azobenzene derivatives undergo a clean photoisomerization reaction when irradiated with UV light at 340 nm, converting the stable rod‐like trans‐ isomer into the globular, metastable cis isomer, and vice versa.…”
Section: Trans–cis Isomerization and Functionalities Of Azobenzenementioning
confidence: 99%
“…Light can be precisely manipulated with high spatial and temporal accuracy, prompting researchers to extensively explore various photoresponsive compounds for applications in life sciences research. [ 41 ] Among these, azobenzene is one of the most popular and reliable photoisomerizing molecular functional group. Azobenzene derivatives undergo a clean photoisomerization reaction when irradiated with UV light at 340 nm, converting the stable rod‐like trans‐ isomer into the globular, metastable cis isomer, and vice versa.…”
Section: Trans–cis Isomerization and Functionalities Of Azobenzenementioning
confidence: 99%
“…Optical signals are insensitive to noise interference, have good stability, and the spectral properties of different molecules to be tested are differentiated with high specificity. Therefore, optical biosensors can directly detect the molecules to be detected [65]. In addition, optical biosensors are easily miniaturized and have the potential to facilitate chip-level integration [66].…”
Section: Optical Biosensorsmentioning
confidence: 99%
“…Colorimetric biosensors have the advantages of naked eye determination, low cost, fast response, and ease of fabrication [68]. Colorimetric biosensors can change color in response to external physical or chemical factors, as well as through an enzyme-catalyzed chromogenic reaction inside the sensor, or with the help of metallic nanomaterials [65].…”
Section: Colorimetrymentioning
confidence: 99%
“…Here, we fabricated a brain-on-a-chip platform integrating cortical networks and 60-channel electrodeposited platinum/iridium (Pt/Ir) modified MEAs with triple chambers. The application of nanomaterials in the modification of biosensors has become ubiquitous, , enhancing electrochemical performance through organic nanoparticles including nanozymes and conductive polymers , as well as inorganic nanoparticles such as metallic, semiconducting, and carbon-based nanoparticles . The formation of nanocomposites facilitates synergistic interactions among different nanomaterials, which enhances charge transfer kinetics, modulates surface reactivity, and optimizes electron distribution. , Pt/Ir nanocomposites, in particular, are favored in brain–computer interfaces due to their exceptional biocompatibility and stability .…”
Section: Introductionmentioning
confidence: 99%