E-skin – Based advanced wearable technology for Health Management

“…They can also be employed in remote patient monitoring, enabling healthcare professionals to monitor patients from a distance and detect any abnormalities or changes in their condition. 81,82 With the rapid advancement of intelligent wearable electronics, there is a strong demand for flexible shielding E-skin to monitor physiological signals and safeguard individuals against electromagnetic radiation. 83 In one study, a dual-purpose electrospun nanofiber membrane adorned with MXene nanosheets and Fe 3 O 4 nanoparticles, exhibiting exceptional specific shielding effectiveness of 9212.1 dB cm 2 g −1 across a wide waveband range (8–26.5 GHz).…”

“…However, current devices suffer from complex integration procedures and a lack of intuitive signal display functionality. 82,87 In one study, a bioinspired E-skin was introduced with simple structure, providing digital electrical response and optical visualization when subjected to external mechanical stimuli. 87 It consisted of a conductive layer featuring a carbon nanotube/cellulose nanofiber/MXene nanohybrid network with remarkable electromechanical properties, and a stretchable elastomer layer composed of silicone rubber and thermochromic pigments (Fig.…”

Advancements in MXene-based composites for electronic skins

“…They can also be employed in remote patient monitoring, enabling healthcare professionals to monitor patients from a distance and detect any abnormalities or changes in their condition. 81,82 With the rapid advancement of intelligent wearable electronics, there is a strong demand for flexible shielding E-skin to monitor physiological signals and safeguard individuals against electromagnetic radiation. 83 In one study, a dual-purpose electrospun nanofiber membrane adorned with MXene nanosheets and Fe 3 O 4 nanoparticles, exhibiting exceptional specific shielding effectiveness of 9212.1 dB cm 2 g −1 across a wide waveband range (8–26.5 GHz).…”

“…However, current devices suffer from complex integration procedures and a lack of intuitive signal display functionality. 82,87 In one study, a bioinspired E-skin was introduced with simple structure, providing digital electrical response and optical visualization when subjected to external mechanical stimuli. 87 It consisted of a conductive layer featuring a carbon nanotube/cellulose nanofiber/MXene nanohybrid network with remarkable electromechanical properties, and a stretchable elastomer layer composed of silicone rubber and thermochromic pigments (Fig.…”

Advancements in MXene-based composites for electronic skins

“…With this momentum, it is anticipated that approaches based on AI will be further researched and eventually incorporated into practice. 16 It is vital to anticipate how gradual advancement might lead to the shared objective of genuine precision oncology, even although doing so runs the danger of escalating the years of criticism that have offset the field's usually bold promises. Diverse technologies are included in AI, which has the unifying goal of computationally simulating human intellect.…”

Employing nano-enabled artificial intelligence (AI)-based smart technologies for prediction, screening, and detection of cancer

“…[8][9][10] Controlling the size, shape, functionality, etc. has been a key to the successful implementation of nanomaterials in electronics, 11 optics, 12 biomedicine, 13,14 and advanced technologies. 15 Recent developments in graphene-based biosensors and the existing detection methods optimized for detecting proteins, nucleic acids, carbohydrates, or compounds generated by metabolic processes generally employed sensors based on electric, electrochemical, and photonic approaches for perceiving labeled, or enzyme-assisted, and label-free test structures.…”

“…8–10 Controlling the size, shape, functionality, etc. has been a key to the successful implementation of nanomaterials in electronics, 11 optics, 12 biomedicine, 13,14 and advanced technologies. 15…”

Engineering of graphene-based composites with hexagonal boron nitride and PEDOT:PSS for sensing applications