Smart Contact Lenses as Wearable Ophthalmic Devices for Disease Monitoring and Health Management

Seo, Hunkyu; Chung, Won Gi; Kwon, Yong Won; Kim, Sumin; Hong, Yeon-Mi; Park, Wonjung; Kim, Enji; Lee, Jakyoung; Lee, Sanghoon; Kim, Moohyun; Lim, Kyeonghee; Jeong, Inhea; Song, Hayoung; Park, Jang-Ung

doi:10.1021/acs.chemrev.3c00290

Cited by 17 publications

(4 citation statements)

References 466 publications

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“…Although smart contact lenses for monitoring blood glucose levels have been developed, there are various challenges associated with these devices, including opaque electronic components obstructing the wearer's vision, costly signal detection equipment, and the requirement of a power supply. [74] Moreover, many current glucose sensors are dependent upon enzymes to convert glucose into electrochemical signals. [75] This constitutes several limitations for clinical translation as enzymes often have limited lifespan and their function can easily be deformed by changes in the environment.…”

Section: Iop Monitoringmentioning

confidence: 99%

Smart molecules in ophthalmology: Hydrogels as responsive systems for ophthalmic applications

Kulbay,

Wu,

Truong

et al. 2024

Smart Molecules

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This comprehensive review delves into a unique intersection of hydrogels as smart molecules and their transformative applications in ophthalmology. Beginning with the foundational definition, properties, and classification of hydrogels, the review explores their synthesis and responsive capabilities. Specific applications examined encompass topical drug delivery, contact lenses, intravitreal drug delivery, ocular adhesives, vitreous substitutes, and cell‐based therapy. A methodical analysis, including an overview of relevant ocular structures and a comparative evaluation of hydrogel‐based solutions against traditional treatments, is conducted. Additionally, potential constraints, translation challenges, knowledge gaps, and research areas are identified. Our methodical approach, guided by an extensive literature review from 2017 to 2023, illuminates the unprecedented opportunities offered by hydrogels, along with pinpointing areas for further inquiry to facilitate their transition into clinical practice.

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Section: Iop Monitoringmentioning

confidence: 99%

Smart molecules in ophthalmology: Hydrogels as responsive systems for ophthalmic applications

Kulbay,

Wu,

Truong

et al. 2024

Smart Molecules

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“…With the rapid growth of industries related to the Internet of Things, wearable devices, and intelligent life, there has been an increasing recognition of the significance of development of sensing technologies and relevant devices. − Excited-state-based fluorescence sensing, being a pivotal and cutting-edge technology, is contributing to the flourishing advancement of the domains. − Benefiting from exceptional sensing capabilities, remarkable designability, and strong integration, research on film-based fluorescent sensors (FFSs) has made remarkable strides over the past two decades. − These advances led to their recognition as one of the Top Ten Emerging Technologies in Chemistry for 2022 of the International Union of Pure and Applied Chemistry . Despite the substantial advancements in chemical and physical sensing, currently, only FFSs for concealed explosives and illicit drugs have been deployed in real-life applications. − One of the bottle necks for the delayed applications of the technology is lack of qualified sensing materials, which must satisfy a variety of requirements such as “3S + 1R” (sensitivity, selectivity, speed, and reversibility) and great photochemical stability. − Therefore, the ongoing pursuit of sensing materials with superior performance is of urgent significance.…”

Section: Introductionmentioning

confidence: 99%

Interfacially Confined Dynamic Reaction Resulted to Fluorescent Nanofilms Depicting High-Performance Ammonia Sensing

Liang,

Hu,

et al. 2024

Anal. Chem.

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Sensing materials innovation plays a crucial role in the development of high-performance film-based fluorescent sensors (FFSs). In our current study, we present the innovative fabrication of four fluorescent nanofilms via interfacially confined dynamic reaction of a specially designed fluorescent building block, a new boron-coordinated compound (NI-CHO), with a chosen one, benzene-1,3,5-tricarbohydrazide (BTH). The nanofilms as prepared are robust, uniform, flexible, and thickness tunable, at least from 40 to 1500 nm. The fabricated FFSs based on Film 3, one of the four nanofilms, shows highly selective and fully reversible response to NH3 vapor with an experimental detection limit of <0.1 ppm and a response time of 0.2 s. The unprecedented high performance of the nanofilm is ascribed to the specific quenching of its fluorescence emission owing to formation of an excited-state complex between the sensing unit and the analyte molecule. Efficient mass transfer also contributes to the high performance owing to the porous adlayer structure of the nanofilm. This work provides an example to show how to develop a high-performance sensing film via controlling the film’s structure, especially the thickness.

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“…Biomarker molecules in tears diffuse from the blood through the tear–blood barrier, and exhibit a strong correlation with their concentration in blood. Thus, the physical and chemical signals provided by the eye can be used to develop contact lens biosensors (all these signal-generating phenomena or molecules are physical, chemical, or biological in nature, and are in this review referred to as biomarkers). − For example, based on the relationship between tear glucose and blood glucose, glucose concentration in tears can be monitored to reflect the glucose level in the blood, , and changes in intraocular pressure (IOP) can be monitored to reflect the severity of glaucoma. , These physical and chemical signals reflect the physiological state of the eye and the body, and provide a solution for prediction and early treatment of human eye diseases. Thus, the potential applications of contact lens biosensors in eye disease monitoring and therapy have attracted the interest from scientists. ,, …”

Section: Introductionmentioning

confidence: 99%

Smart Contact Lenses for Healthcare Monitoring and Therapy

Liu,

Ye,

et al. 2024

ACS Nano

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The eye contains a wealth of physiological information and offers a suitable environment for noninvasive monitoring of diseases via smart contact lens sensors. Although extensive research efforts recently have been undertaken to develop smart contact lens sensors, they are still in an early stage of being utilized as an intelligent wearable sensing platform for monitoring various biophysical/chemical conditions. In this review, we provide a general introduction to smart contact lenses that have been developed for disease monitoring and therapy. First, different disease biomarkers available from the ocular environment are summarized, including both physical and chemical biomarkers, followed by the commonly used materials, manufacturing processes, and characteristics of contact lenses. Smart contact lenses for eye-drug delivery with advancing technologies to achieve more efficient treatments are then introduced as well as the latest developments for disease diagnosis. Finally, sensor communication technologies and smart contact lenses for antimicrobial and other emerging bioapplications are also discussed as well as the challenges and prospects of the future development of smart contact lenses.

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Smart Contact Lenses as Wearable Ophthalmic Devices for Disease Monitoring and Health Management

Cited by 17 publications

References 466 publications

Smart molecules in ophthalmology: Hydrogels as responsive systems for ophthalmic applications

Smart molecules in ophthalmology: Hydrogels as responsive systems for ophthalmic applications

Interfacially Confined Dynamic Reaction Resulted to Fluorescent Nanofilms Depicting High-Performance Ammonia Sensing

Smart Contact Lenses for Healthcare Monitoring and Therapy

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