Ultra-conformal epidermal antenna for multifunctional motion artifact-free sensing and point-of-care monitoring.

Accurate acquisition of physiological and physical information from human tissue is essential for health monitoring, disease prevention and treatment. The existing antennas with traditional rigid or flexible substrates are susceptible to motion artifacts in wearable applications due to the miniaturization limitation and lack of proper adhesion and conformal interfaces with the skin. Recent advances in wearable radio frequency (RF) bioelectronics directly drawn on the skin are a promising solution for future skin-interfaced devices. Herein, we present a first-of-its kind epidermal antenna architecture with skin as the antenna substrate, which is ultra-low profile, ultra-conformal, ultra-compact, and simple fabrication without specialized equipment. The radiation unit and ground of antenna are drawn directly on the skin with the strong adhesion and ultra conformality. Therefore, this RF device is highly adaptable to motion. As a proof-of- feasibility, epidermal antenna can be freely drawn on demand at different locations on the skin for the development of temperature sensor, skin hydration sensor, strain sensor, glucose sensor and other devices. An epidermal antenna-based temperature sensor can offer accurate and real-time monitoring of human body temperature changes in the ultra-wideband (UWB) range. The results during the monitoring of hydration level with and without stretching show that the epidermal antenna drawn on the skin is motion artifact-free. We also designed an epidermal antenna array employing a horseshoe-shaped configuration for the precise identification of various gestures. In addition, the non-invasive blood glucose level (BGL) monitoring results during the in-vivo experiments report high correlation between the epidermal antenna responses and BGLs, without any time hysteresis. After the prediction of BGL by BP network, all the predicted BGL values are fallen 100% into the clinically acceptable zones. Together, these results show that epidermal antenna offers a promising new approach for biosensing platform.

Effects of comprehensive nursing with cognitive behavioral therapy in orthodontic osteodilated arch treatment.

BACKGROUND: This work explored the effects of cognitive behavior therapy (CBT)-based comprehensive nursing intervention (CNI) mode in arch expansion to treat patients with orthodontic osteodilated arch (OOA). AIM: To explore the application effect of CBT-based CNI model in orthodontic expansion arch treatment. METHODS: Using convenient sampling method, 81 patients with OOA were selected and rolled into a control group (Ctrl group, 40 cases) and an observation group (Obs group, 41 cases). During the treatment, patients in the Ctrl group received routine nursing intervention mode, and the those in the Obs group received CBT mode on the basis of this. Before and after intervention, the incidence of oral mucositis, the mastery rate of correct arch expansion method, self-rating anxiety scale score, soft scale index, and plaque index were compared for patients in different groups. In addition, satisfaction and complications were comparatively analyzed. RESULTS: Incidence of oral mucositis in the Obs group was lower (14.6% vs 38.5%), and the mastery rate of correct arch expansion method was obviously higher (90.2% vs 55.0%) was obviously higher (all P < 0.05). Meanwhile, the soft scale index and plaque index in the Obs group were much lower (P < 0.05). The compliance (90.24%) and satisfaction (95.12%) in the Obs group were greatly higher (P < 0.05). CONCLUSION: The CBT-based CNI mode greatly improved the mastery rate of correct arch expansion method during arch expansion in treating patients with OOA and enhanced the therapeutic effect of arch expansion and the oral health of patients, improving the patient compliance.

PTEN inhibits proliferation and functions of hypertrophic scar fibroblasts.

Hypertrophic scar (HS) remains a major problem in plastic surgery. In order to explore the regulative effect of phosphatase and tensin homolog (PTEN) on HS, PTEN and AKT expression was detected by reverse transcription PCR, immunohistochemistry and western blot. Adenovirus-mediated PTEN overexpression in cultured hypertrophic scar fibroblasts (HSFBs) and normal skin fibroblasts was also introduced to evaluate its biological function. Our results showed that PTEN expression was significantly decreased in HS whereas p-Akt level was significantly higher in HS compared with normal skin (P < 0.01). Furthermore, we found that adenovirus-mediated PTEN overexpression led to decreased AKT activation, and significantly reduced cell proliferation and collagen synthesis of HSFBs, while increased the apoptosis. Taken together, these data suggest that PTEN inhibits proliferation and function of HSFBs through AKT pathway. Our results reveal a novel biological role for PTEN/AKT pathway in HS and suggest PTEN as a potential therapeutic target for HS treatment.