Recent advances in materials and applications for bioelectronic and biorobotic systems

Phillips, Jacob W.; Promiński, Aleksander; Tian, Bozhi

doi:10.1002/viw.20200157

Cited by 22 publications

(16 citation statements)

References 71 publications

(175 reference statements)

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“…As can be seen, the proposed biosensor exhibited a lower limit-of-detection within a wider linear range, compared with other techniques (e.g., fluorescence, surface plasmon resonance, and electrochemiluminescence) [58][59][60]. We attributed the superior sensitivity of the proposed biosensor to the ratiometric strategy and aptamer-facilitated HCR for signal amplification [61,62]. In addition to the sensitivity performance, the proposed biosensor also displayed an improved specificity by introducing a DNA OR logic gate for the simultaneous detection of two surface protein targets, which provides more comprehensive information for cancer diagnosis [63][64][65].…”

Section: Ultrasensitive Detection Of Exosomementioning

confidence: 81%

Ratiometric electrochemical OR gate assay for NSCLC-derived exosomes

Meng

Niu

et al. 2023

J Nanobiotechnol

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Non-small cell lung cancer (NSCLC) is the most common pathological type of LC and ranks as the leading cause of cancer deaths. Circulating exosomes have emerged as a valuable biomarker for the diagnosis of NSCLC, while the performance of current electrochemical assays for exosome detection is constrained by unsatisfactory sensitivity and specificity. Here we integrated a ratiometric biosensor with an OR logic gate to form an assay for surface protein profiling of exosomes from clinical serum samples. By using the specific aptamers for recognition of clinically validated biomarkers (EpCAM and CEA), the assay enabled ultrasensitive detection of trace levels of NSCLC-derived exosomes in complex serum samples (15.1 particles μL−1 within a linear range of 102–108 particles μL−1). The assay outperformed the analysis of six serum biomarkers for the accurate diagnosis, staging, and prognosis of NSCLC, displaying a diagnostic sensitivity of 93.3% even at an early stage (Stage I). The assay provides an advanced tool for exosome quantification and facilitates exosome-based liquid biopsies for cancer management in clinics. Graphical Abstract

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Section: Ultrasensitive Detection Of Exosomementioning

confidence: 81%

Ratiometric electrochemical OR gate assay for NSCLC-derived exosomes

Meng

Niu

et al. 2023

J Nanobiotechnol

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“…S13B). Then, bonding the precursor with a proof mass (PDMS/ Cu composite; length by width by height, 1 mm by 1 mm by 1 mm; density, 4.5 g/cm 3 ) and transferring it onto a predesigned folding host prepared the system for 3D transformation. A mechanical stage allowed controlled folding of the host base to a welldefined angle and completed the 3D assembly process.…”

Section: Fabrication and Measurement Of 3d Vibration Sensor And Dynam...mentioning

confidence: 99%

“…The lower surface of the proof mass was tied to the upper surface of the composite layer. The elastic modulus (E), Poisson's ratio (υ), and density (ρ) in the simulations were E Si = 179 GPa, υ Si = 0.28, and ρ Si = 2.33 g/cm 3 for Si; E PLGA = 4.5 GPa, υ PLGA = 0.34, and ρ PLGA = 1.38 g/cm 3 for PLGA; and E = 1.2 GPa, υ = 0.48, and ρ = 4.5 g/cm 3 for the proof mass.…”

Section: Dynamic Fea For 3d Vibration Sensormentioning

confidence: 99%

“…Structural engineering that overcomes intrinsic limits of bulk materials pivots a cascading collection of previously unidentified opportunities in biomedical devices ( 1 , 2 ), robotic systems ( 3 , 4 ), microelectronics ( 5 , 6 ), microelectromechanical systems (MEMSs) ( 7 , 8 ), and metamaterials ( 9 , 10 ). In particular, morphing mesostructures in three dimensions (3D) not only offers multidimensional control to precisely tune material functions on demand ( 6 , 11 , 12 ) but also breaks the repulsive barriers for heterogeneous materials to coherently integrate ( 13 , 14 ), for a leveraged combination of properties beyond those of the individual components ( 14 , 15 ).…”

Section: Introductionmentioning

confidence: 99%

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3D morphable systems via deterministic microfolding for vibrational sensing, robotic implants, and reconfigurable telecommunication

Zhang

Weisbecker

et al. 2022

Sci. Adv.

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DNA and proteins fold in three dimensions (3D) to enable functions that sustain life. Emulation of such folding schemes for functional materials can unleash enormous potential in advancing a wide range of technologies, especially in robotics, medicine, and telecommunication. Here, we report a microfolding strategy that enables formation of 3D morphable microelectronic systems integrated with various functional materials, including monocrystalline silicon, metallic nanomembranes, and polymers. By predesigning folding hosts and configuring folding pathways, 3D microelectronic systems in freestanding forms can transform across various complex configurations with modulated functionalities. Nearly all transitional states of 3D microelectronic systems achieved via the microfolding assembly can be easily accessed and modulated in situ, offering functional versatility and adaptability. Advanced morphable microelectronic systems including a reconfigurable microantenna for customizable telecommunication, a 3D vibration sensor for hand-tremor monitoring, and a bloomable robot for cardiac mapping demonstrate broad utility of these assembly schemes to realize advanced functionalities.

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“…Fortunately, thanks to the rapid development of flexible electronics and nanomaterials, wearable skin-like devices with ultrahigh flexibility and compliant features of skin were reported and regarded as an essential candidate for healthcare. [8][9][10][11][12][13][14][15][16][17] At present, various ingenious healthcare devices have been explored for detecting body temperature, blood pressure, heart rate and glucose based on thermoelectric effect, piezoelectric/piezoresistive mechanism, capacitive effect, or electrocatalytic/electrochemical principles. [18][19][20][21][22][23][24] Significantly, these monitoring devices can be integrated into wearable clothes or watches for continuous healthcare, which makes home-based telehealth monitoring available.…”

Section: Introductionmentioning

confidence: 99%

Flexible wearable devices for intelligent health monitoring

Dai

Gao

Xie

2022

VIEW

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Profited from the rapid development of flexible skin-like electronic materials and artificial intelligent technology, remarkable achievements have been witnessed in wearable health monitoring devices in recent years. The wearable intelligent systems featured with tailored structures and compositions as well as enriched functions enable human beings to access to next-generation closed-loop platform for early disease prevention and diagnosis. In this context, this mini-review focuses on the recent progress and applications of flexible wearable intelligent health monitoring devices. Specifically, the basic sensing mechanisms and corresponding property requirements for wearable healthcare devices are examined firstly. Secondly, the versatile applications of advanced wearable devices for detecting temperature, heart rate, blood pressure and glucose are scrutinized exclusively. Finally, a brief summary is presented accompanying with future outlook in terms of material preparation, mechanism development and integration design of monitoring systems. This manuscript is expected to provide critical guidelines to those working in skin-like electronics, flexible sensors, wearable intelligent devices, health monitoring and other related disciplines, especially for the beginners.

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Recent advances in materials and applications for bioelectronic and biorobotic systems

Cited by 22 publications

References 71 publications

Ratiometric electrochemical OR gate assay for NSCLC-derived exosomes

Ratiometric electrochemical OR gate assay for NSCLC-derived exosomes

3D morphable systems via deterministic microfolding for vibrational sensing, robotic implants, and reconfigurable telecommunication

Flexible wearable devices for intelligent health monitoring

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