Antibacterial Defective‐ZIF‐8/PPY/BC‐Based Flexible Electronics as Stress‐Strain and NO<sub>2</sub> Gas Sensors

Men, Ying; Qin, Ziyu; Yang, Zhou; Zhang, Pengcheng; Li, Mengting; Wang, Qingji; Zeng, Dawen; Yin, Xueqiong; Ji, Hongbing

doi:10.1002/adfm.202316633

Cited by 14 publications

(1 citation statement)

References 51 publications

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“…In this study, Zn-MOF and Eu-MOF showed synergistic antibacterial properties. Zn-MOF exhibits antibacterial properties by releasing Zn 2+ ions (Figures c, S3), which can generate reactive oxygen species (ROS) that interact with bacterial cell membrane proteins, leading to bacterial structure damage, internalization, and eventual death of microorganisms. − While Eu-MOF exerts its antibacterial activity through the formation of a complex between rare earth ion Eu 3+ and ligand BBDC. The positive charge of the rare earth ion is transferred to the organic ligand, resulting in a positively charged ligand that interacts with the negatively charged bacterial cell membrane to achieve antibacterial effects …”

Section: Resultsmentioning

confidence: 99%

Multifunctional Janus Membrane for Diabetic Wound Healing and Intelligent Monitoring

Liu,

Xi,

Yang

et al. 2024

ACS Appl. Mater. Interfaces

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The complex microenvironment of diabetic wounds often hinders the healing process, ultimately leading to the formation of diabetic foot ulcers and even death. Dual monitoring and treatment of wounds can significantly reduce the incidence of such cases. Herein, a multifunctional Janus membrane (3D chitosan sponge-ZE/polycaprolactone nanofibers-ZP) was developed by incorporating the zinc metal−organic framework, europium metal−organic framework, and phenol red into nanofibers for diabetic wound monitoring and treatment. The directional water transport capacity of the resulting Janus membrane allows for unidirectional and irreversible drainage of wound exudate, and the multifunctional Janus membrane creates up to a 99% antibacterial environment, both of which can treat wounds. Moreover, the pH (5−8) and H 2 O 2 (0.00−0.80 μM) levels of the wound can be monitored using the color-changing property of phenol red and the fluorescence characteristic of Eu-MOF on the obtained membrane, respectively. The healing stages of the wound can also be monitored by analyzing the RGB values of the targeted membrane images. This design can more accurately reflect the wound state and treat the wound to reduce bacterial infection and accelerate wound healing, which has been demonstrated in in vivo experiments. The results provide an important basis for early intervention in diabetic patients.

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Section: Resultsmentioning

confidence: 99%

Multifunctional Janus Membrane for Diabetic Wound Healing and Intelligent Monitoring

Liu,

Xi,

Yang

et al. 2024

ACS Appl. Mater. Interfaces

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Sweat‐Permeable, Microbiota‐Preserving, Mechanically Antibacterial Patch for Long‐Term Interfacing with Perspiring Skin

Wu,

Li,

et al. 2024

Adv Funct Materials

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The prolonged health monitoring using wearable technology faces challenges stemming from perspiration, including bacterial proliferation, compromised adhesion, signal quality deterioration, and user discomfort. Notably, excessive sweat fosters bacterial colonization, escalating infection risks, and compromising biomarker analysis. Existing antibacterial approaches, unfortunately, risk disrupting the delicate balance of skin microbiota. To address this, a Janus patch featuring Zn‐Al layered double hydroxide (LDH) modification is developed, which exhibits sustained antibacterial properties while preserving the epidermal microecology. It integrates a hydrophobic LDH fabric that mechanically eradicates bacteria via a nanoknife effect, and a laser‐engraved medical adhesive with microholes for unidirectional sweat transport. This innovative design not only enhances adhesion stability but also safeguards the skin microbiome by preventing direct contact with Zn‐Al LDH. Moreover, the patch seamlessly interfaces with sweat‐monitoring technologies like microfluidic paper‐based analytical devices (uPADs) sensors, ensuring 100% antibacterial efficacy and efficient sweat redirection for reliable detection while prioritizing user comfort. It can serve as a durable bridge between perspiring skin and epidermal sensors, revolutionizing the realm of long‐term health monitoring.

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Multilayer Bionic Tunable Strain Sensor with Mutually Non‐Interfering Conductive Networks for Machine Learning‐Assisted Gesture Recognition

Gao,

Yang,

Zhao

et al. 2024

Adv Funct Materials

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Flexible strain sensors capable of acquiring tiny mechanical signals and attaching to various irregular surfaces are becoming prevalent in physiological measurement, soft robotics, and human‐machine interaction. However, the advancement of flexible strain sensors is substantially impeded by the intrinsic compromise between sensitivity and the range of detectable signals. Inspired by the multilayer structure of nacre in nature, a carbon nanotubes (CNTs)/graphene (GR)/graphene (GR)/thermoplastic polyurethane (TPU) mat (CGGTM) is prepared by electrospinning and high‐pressure spraying technology. By designing a multilayer structure with mutually non‐interfering conductive networks, the resulting CGGTM possesses a low detection limit (0.05% strain), high sensitivity (gauge factor, GF > 152537), large detection range (up to 364% strain), fast response/recovery time (80 ms/100 ms), and excellent cyclic durability (up to 1000 cycles). Furthermore, the CGGTM also exhibits satisfactory triboelectric performances when assembled into a triboelectric nanogenerator (TENG, 3 × 3 cm2), including high triboelectric output (open‐circuit voltage Voc = 135.4 V, short‐circuit current Isc = 1.25 µA) and power density (88 mW m−2), enabling reliable power supply, self‐powered sensing, and pulse monitoring capability. Finally, CGGTM is successfully applied to the collection of biological signals and multi‐gesture motion recognition assisted by machine learning algorithms, which holds promise for intelligent interaction with gestures in the future.

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Antibacterial Defective‐ZIF‐8/PPY/BC‐Based Flexible Electronics as Stress‐Strain and NO₂ Gas Sensors

Cited by 14 publications

References 51 publications

Multifunctional Janus Membrane for Diabetic Wound Healing and Intelligent Monitoring

Multifunctional Janus Membrane for Diabetic Wound Healing and Intelligent Monitoring

Sweat‐Permeable, Microbiota‐Preserving, Mechanically Antibacterial Patch for Long‐Term Interfacing with Perspiring Skin

Multilayer Bionic Tunable Strain Sensor with Mutually Non‐Interfering Conductive Networks for Machine Learning‐Assisted Gesture Recognition

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Antibacterial Defective‐ZIF‐8/PPY/BC‐Based Flexible Electronics as Stress‐Strain and NO2 Gas Sensors

Cited by 14 publications

References 51 publications

Multifunctional Janus Membrane for Diabetic Wound Healing and Intelligent Monitoring

Multifunctional Janus Membrane for Diabetic Wound Healing and Intelligent Monitoring

Sweat‐Permeable, Microbiota‐Preserving, Mechanically Antibacterial Patch for Long‐Term Interfacing with Perspiring Skin

Multilayer Bionic Tunable Strain Sensor with Mutually Non‐Interfering Conductive Networks for Machine Learning‐Assisted Gesture Recognition

Contact Info

Product

Resources

About

Antibacterial Defective‐ZIF‐8/PPY/BC‐Based Flexible Electronics as Stress‐Strain and NO₂ Gas Sensors