A soft and ultrasensitive force sensing diaphragm for probing cardiac organoids instantaneously and wirelessly

Lyu, Quanxia; Gong, Shu Ping; Lees, Jarmon G.; Yin, Jialiang; Yap, Lim Wei; Kong, Anne Mandy; Shi, Qianqian; Fu, Runfang; Zhu, Qiaoming; Dyer, Ash; Dyson, Jennifer M; Lim, Shiang Y.; Cheng, Wenlong

doi:10.1038/s41467-022-34860-y

Cited by 25 publications

(27 citation statements)

References 41 publications

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“…The capability of external and remote activating of the sensor was demonstrated, suggesting the potential to construct high-performance NIR-mediated gas sensing platforms which may be extended to detect other targets from human tissues. [43] Adv. Funct.…”

Section: Verification Of the Large Penetration Depth Of Nir Light And...mentioning

confidence: 99%

A Plant‐inspired Light Transducer for High‐performance Near‐infrared Light Mediated Gas Sensing

Liang

Guo

et al. 2023

Adv Funct Materials

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Constructing near‐infrared light (NIR) light‐enhanced room temperature gas sensors is becoming more promising for practical application. In this study, learning from the structure and photosynthetic process of chlorophyll thylakoid membranes in plants, the first “Thylakoid membrane” structural formaldehyde (HCHO) sensor is constructed by matching the upconversion emission of the lanthanide‐doped upconversion nanoparticles (UCNPs) and the UV–vis adsorption of the as‐prepared nanocomposites. The NIR‐mediated sensor exhibits excellent performances, including ultra‐high response (Ra / Rg = 2.22, 1 ppm), low practical limit of detection (50 ppb), reliable repeatability, high selectivity, and broadband spectral response. The practicality of the NIR‐mediated gas sensor is confirmed through the remote and external stimulation test. A study of sensing mechanism demonstrates that it is the UCNPs‐based light transducer produces more light‐induced oxygen species for gas response in the process of non‐radiative/radiative energy transfer, playing a key role in significantly improving the sensing properties of the sensor. The universality of NIR‐mediated gas sensors based on UCNPs is verified using ZnO, In2O3, and SnO2 systems. This work paves a way for fabricating high‐performance NIR‐mediated gas sensors and will expand the application fields of NIR light.

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Section: Verification Of the Large Penetration Depth Of Nir Light And...mentioning

confidence: 99%

A Plant‐inspired Light Transducer for High‐performance Near‐infrared Light Mediated Gas Sensing

Liang

Guo

et al. 2023

Adv Funct Materials

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“…The plasticity of these synapses, meaning their ability to change their strength and connectivity over time, is crucial for learning and memory. − Neuromorphic electronic systems, proposed by Carver Mead in the late 1980s to early 1990s, aim to design electronic systems that mimic the structure, function, and plasticity of biological neural networks (Figure ). While neuromorphic circuits based on silicon complementary metal-oxide-semiconductor (CMOS) technology have been developed to replicate synaptic functionalities, classical computing systems traditionally relied on the von Neumann computing architecture and suffered from limitations due to the separation of memory from processing, leading to issues such as speed latency, high energy consumption, and limited communication bandwidth. ,,, To overcome these drawbacks, researchers have developed novel artificial synapses based on a variety of materials and structures, typically implemented with 2-terminal memristors or 3-terminal transistors. ,,, These devices are capable of achieving neuromorphic functions, such as short-term and long-term plasticity (STP and LTP), similar to the synapses in biological systems. ,, In recent years, there has been growing interest in using flexible electronics for the development of artificial neuron devices. ,, Flexible electronics refer to electronic devices and systems that can bend, stretch, and conform to their surroundings without breaking or losing their functionality. ,− Flexible electronics possess mechanical properties similar to human organs and tissues, showing great advantages for the development of artificial neuron devices. ,,− They can be easily integrated with biological tissues and structures, allowing for seamless interaction with the nervous system and the development of biointerfaces and biohybrid systems. − …”

Section: Introductionmentioning

confidence: 99%

Artificial Neuron Devices

He,

Wang,

et al. 2023

Chem. Rev.

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Efforts to design devices emulating complex cognitive abilities and response processes of biological systems have long been a coveted goal. Recent advancements in flexible electronics, mirroring human tissue’s mechanical properties, hold significant promise. Artificial neuron devices, hinging on flexible artificial synapses, bioinspired sensors, and actuators, are meticulously engineered to mimic the biological systems. However, this field is in its infancy, requiring substantial groundwork to achieve autonomous systems with intelligent feedback, adaptability, and tangible problem-solving capabilities. This review provides a comprehensive overview of recent advancements in artificial neuron devices. It starts with fundamental principles of artificial synaptic devices and explores artificial sensory systems, integrating artificial synapses and bioinspired sensors to replicate all five human senses. A systematic presentation of artificial nervous systems follows, designed to emulate fundamental human nervous system functions. The review also discusses potential applications and outlines existing challenges, offering insights into future prospects. We aim for this review to illuminate the burgeoning field of artificial neuron devices, inspiring further innovation in this captivating area of research.

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Section: Introductionmentioning

confidence: 99%

Organoid assessment technologies

Gu,

Zhang,

et al. 2023

Clinical & Translational Med

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Despite enormous advances in the generation of organoids, robust and stable protocols of organoids are still a major challenge to researchers. Research for assessing structures of organoids and the evaluations of their functions on in vitro or in vivo is often limited by precision strategies. A growing interest in assessing organoids has arisen, aimed at standardizing the process of obtaining organoids to accurately resemble human‐derived tissue. The complex microenvironment of organoids, intricate cellular crosstalk, organ‐specific architectures and further complicate functions urgently quest for high‐through schemes. By utilizing multi‐omics analysis and single‐cell analysis, cell‐cell interaction mechanisms can be deciphered, and their structures can be investigated in a detailed view by histological analysis. In this review, we will conclude the novel approaches to study the molecular mechanism and cell heterogeneity of organoids and discuss the histological and morphological similarity of organoids in comparison to the human body. Future perspectives on functional analysis will be developed and the organoids will become mature models.

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A soft and ultrasensitive force sensing diaphragm for probing cardiac organoids instantaneously and wirelessly

Cited by 25 publications

References 41 publications

A Plant‐inspired Light Transducer for High‐performance Near‐infrared Light Mediated Gas Sensing

A Plant‐inspired Light Transducer for High‐performance Near‐infrared Light Mediated Gas Sensing

Artificial Neuron Devices

Organoid assessment technologies

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