Multiple-Language-Responsive Conductive Hydrogel Composites for Flexible Strain and Epidermis Sensors

Khan, Mansoor; Shah, Luqman Ali; Rahman, Tanzil Ur; Ara, Latafat; Yoo, Hyeong-Min

doi:10.1021/acsapm.4c00327

Cited by 10 publications

(4 citation statements)

References 69 publications

(87 reference statements)

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“…Hydrophobic associations and electrostatic interactions were utilized to maintain the integrity of the LM, Amm, and DMAEAMC hydrogels. Pluronic 123 (P123) served as the micelle agent, with LM hydrophobic monomer diffusing into the micelles. , After polymerization with Amm and DMAEAMC, these micelles acted as cross-linking points for the hydrogel network. The wrinkled texture was generated by the hydrophobic photoinitiator, where micelles reduced the interfacial (surface) energy, resulting in wrinkled micro- or macro surfaces.…”

Section: Introductionmentioning

confidence: 99%

Flexible Ionic Conductive Hydrogels with Wrinkled Texture for Flexible Strain Transducer with Language Identifying Diversity

Khan,

Rahman,

Sher

et al. 2024

Chem. Mater.

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Conductive hydrogels have garnered significant attention in the realm of flexible electronic strain transducers (FESTs). However, the development of such FEST hydrogels has been hindered by weak mechanical performance and low conductivity, sensitivity, and stability. In this study, we introduce a novel FEST hydrogel with a wrinkled surface possessing a unique ability to differentiate between different spoken and written languages. Our approach involved fabricating a robust, tough, and ionic conductive hydrogel with a wrinkled texture through a simple strategy utilizing the hydrophobic initiator benzophenone (BP). BP was incorporated into hydrophobically cross-linked hydrogels composed of hydrophobic lauryl methacrylate (LMA), acrylamide (Amm), and the cationic monomer 2-(dimethylamino) ethyl acrylate methochloride (DMAEAMC), reinforced with trimesic acid (TMA). Pluronic 123 (P123) served as a source of micelles, dynamically connecting polymer chains and facilitating the diffusion of BP to produce wrinkled textured hydrogels. Furthermore, LiCl salt induced ionic conductivity (0.18 S/m), while the synergistic effect of TMA enhanced the mechanical performance through electrostatic interactions with DMAEAMC chains. The combination of hydrophobic and electrostatic interactions enabled the hydrogels to stretch up to 1611% with high conductivity, remarkable sensitivity (GF = 4.98 at 500%), and a wide strain range (0.1 to 500%). These hydrogels are valuable candidates for integration into epidermal FEST devices. Moreover, the epidermal FEST has the capability to monitor various large joint movements as well as different physiological activities. Additionally, FEST can identify different spoken and written languages, including English, Urdu, and Pashto, and can respond to other handwriting styles such as alphabets, numbers, and signatures. This approach provides a promising roadmap for engineering wrinkled texture hydrogels for diverse applications, especially in the fields of flexible sensors, electronic skin, and biomedical devices.

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Section: Introductionmentioning

confidence: 99%

Flexible Ionic Conductive Hydrogels with Wrinkled Texture for Flexible Strain Transducer with Language Identifying Diversity

Khan,

Rahman,

Sher

et al. 2024

Chem. Mater.

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“…Nevertheless, the practical use of hydrogel-based wearable sensors has been hindered by their weak mechanical properties such as low stretchability, toughness, and insufficient resistance to fatigue. , These shortcomings translate into a limited sensing range and reduced durability. Recent efforts have focused on designing highly stretchable and robust hydrogels by leveraging reversible noncovalent interactions, such as ionic bonding, , hydrogen bonding, electrostatic interaction, and hydrophobic interactions, , in conjunction with well-designed network structures like macromolecular microparticles . Various types of hydrogels have been discovered to address these issues, including double-network hydrogels, hydrophobic association hydrogels, , ionically cross-linked hydrogels, , and composite hydrogels. , Among these, composite hydrogels stand out due to their exceptional elongation properties, and the incorporation of conductive nanoparticles further enhances their conductivity.…”

Section: Introductionmentioning

confidence: 99%

Bimetallic-MOF Tunable Conductive Hydrogels to Unleash High Stretchability and Sensitivity for Highly Responsive Flexible Sensors and Artificial Skin Applications

Khan,

Shah,

Hifsa.

et al. 2024

ACS Appl. Polym. Mater.

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Metal−organic frameworks (MOFs) are widely applied in various fields, including energy storage, drug delivery, wastewater treatment, and much more. However, their use in hydrogels is limited due to their low dispersion which causes agglomeration in the hydrogel network and many properties of hydrogels are sacrifices. Similarly, conductive hydrogels have emerged as a promising material for skin-like sensors due to their excellent biocompatibility and mechanical flexibility. However, like MOFs, hydrogels also face challenges such as limited stretchability, low toughness, and susceptibility to fatigue, resulting in a low sensing range and large response time-reduced durability of the sensors. In this study, a highly stretchable, tough, and antifatigue conductive composite poly(dodecyl methacrylateacrylamide-2-(acryloyloxy)ethyl trimethylammonium chloride) bimetallic metal−organic framework [p(DA-AM-AETAC)BM-MOF] hydrogel was developed by integrating BM-MOFs into it. To achieve uniform dispersion of BM-MOFs within the hydrogel network, a positively charged surfactant, ethyl hexadecyl dimethylammonium bromide, was used. It facilitates the formation of hydrophobic interactions between the hydrogel matrix and the surface of the BM-MOFs. Furthermore, it can also interact with surfactant and polymer chains through physical interactions, significantly enhancing the mechanical properties of the hydrogel. The resulting BM-MOF-based hydrogels exhibited impressive stretchability (1588%) and toughness (537 kJ m −3 ), along with exceptional antifatigue properties. Moreover, it demonstrated a high conductivity of 1.3 S/m and high tensile strain sensitivity ranging from 0.5 to 700% with a gauge factor of 14.8 at 700% strain and response−recovery of 195−145 ms. The p(DA-AM-AETAC)BM-MOF hydrogel sensors displayed sensitive, reliable, and repetitive detection of a wide range of human activities, including wrist elbow rotation, finger bending, swallowing motion, speaking, as well as handwriting and drawing. Furthermore, the hydrogels also monitor the pressure and can mimic human skin. This highlights the potential of hydrogels as wearable strain, pressure, and artificial skin sensors for flexible devices.

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“…Designing and developing smart hydrogels for soft actuators with controllable stimuli-responsive shape deformations have aroused tremendous research interests in recent years. − Taking advantage of delicate design of internal structure and precise control of external stimuli, , smart hydrogels can easily and programmatically change the shapes through controllable uneven swelling/deswelling. Following this principle, smart hydrogels with complex deformations such as bending, − folding, − and bucking and twisting − have been successfully explored as soft actuators for a wide range of applications. − Particularly, magnetism or near-infrared light stimuli-response contributes to the rapid and noncontact control ,,,, and superior mechanical properties serve to build the reusability and durability, , which enable the shape-deformable hydrogels to play a more important role in serving as actuators for extended promising applications.…”

Section: Introductionmentioning

confidence: 99%

Controllable Shape Morphing Nanocomposite Hydrogels for Robust Multi-Stimuli-Responsive Actuators

Yao,

Yang,

Huang

et al. 2024

ACS Appl. Polym. Mater.

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Amazing anisotropic hydrogel actuators with outstanding mechanical properties, multistimuli-responsive properties, and diverse architectures have been simply achieved by hydrogen bonding-directed assembly of two or more homogeneous nanocomposite (NC) hydrogel blocks. The NC hydrogels using clay nanosheets as the efficient cross-linker become strong enough to bear high levels of elongation and compression and exhibit a sensitive near-infrared (NIR) light response with the matrix embedding of graphene oxide (GO) nanosheets or ferroferric oxide (Fe 3 O 4 ) nanoparticles, as well as a magnetism response with embedded Fe 3 O 4 nanoparticles. Those homogeneous NC hydrogels with tunable composition, tailorable shape, and controllable state offer a versatile toolbox and complex shape deformation capacity for the anisotropic actuators. We demonstrate the reliability and practicability of our approach for fabricating various actuators including crawler, circuit switch, and targeted cargo-delivery vehicle, attributing to the rapid, reversible, and repeatable temperature/NIR light-triggered shape morphing. Overall, this work provides a facile and universal strategy for developing the application of the homogeneous NC hydrogels to construct robust multiresponsive actuators with sophisticated structures as well as controllable shape deformation behaviors.

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Multiple-Language-Responsive Conductive Hydrogel Composites for Flexible Strain and Epidermis Sensors

Cited by 10 publications

References 69 publications

Flexible Ionic Conductive Hydrogels with Wrinkled Texture for Flexible Strain Transducer with Language Identifying Diversity

Flexible Ionic Conductive Hydrogels with Wrinkled Texture for Flexible Strain Transducer with Language Identifying Diversity

Bimetallic-MOF Tunable Conductive Hydrogels to Unleash High Stretchability and Sensitivity for Highly Responsive Flexible Sensors and Artificial Skin Applications

Controllable Shape Morphing Nanocomposite Hydrogels for Robust Multi-Stimuli-Responsive Actuators

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