Skin Adhesives with Controlled Adhesion by Polymer Chain Mobility

Dec 18, 2018 - Wearable devices have attracted numerous attentions because of their ... This study provides a clue to design durable and skin-friendly...
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Applications of Polymer, Composite, and Coating Materials

Skin Adhesives with Controlled Adhesion by Polymer Chain Mobility Zhen Gu, Xizi Wan, Zheng Lou, Feilong Zhang, Lianxin Shi, Siheng Li, Bing Dai, Guozhen Shen, and Shutao Wang ACS Appl. Mater. Interfaces, Just Accepted Manuscript • DOI: 10.1021/acsami.8b18947 • Publication Date (Web): 18 Dec 2018 Downloaded from http://pubs.acs.org on December 19, 2018

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Skin Adhesives with Controlled Adhesion by Polymer Chain Mobility

Zhen Gu,†,‡ Xizi Wan,†,§ Zheng Lou,∥ Feilong Zhang,§ Lianxin Shi,†,§ Siheng Li,† Bing Dai,†,§ Guozhen Shen,∥ and Shutao Wang*,†,§

†CAS

Key Laboratory of Bio-inspired Materials and Interfacial Science, CAS Center for

Excellence in Nanoscience, Technical Institute of Physics and Chemistry, Chinese Academy of Sciences, Beijing 100190, P. R. China. ‡Department

of Chemistry and Biological Engineering, University of Science and Technology

Beijing, Beijing 100083, P. R. China. §University ∥State

of Chinese Academy of Sciences, Beijing 100049, P. R. China.

Key Laboratory for Superlattices and Microstructures, Institute of Semiconductors,

Chinese Academy of Sciences, Beijing 100083, P. R. China.

KEYWORDS: skin adhesives; chain mobility; cross-linking; polydimethylsiloxane (PDMS); wearable devices

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ABSTRACT: Wearable devices have attracted numerous attentions because of their importance in biomedical and electronic fields. However, as one of important fixing materials, skin adhesives with controlled adhesion are often ignored. Although remarkable progresses have been achieved in revealing natural adhesion mechanism and biomimetic materials to complex solid surfaces, it remains great challenge to explore non-irritant, controlled skin adhesives without surface structure. Herein, we present skin adhesive patches of polydimethylsiloxane (SAPs) with controlled adhesion by simply modulating polymer chain mobility at molecular level. The controlled adhesion of SAP strongly depends on the proportion of polymer chains with different mobility exposed to the solid surface, including free chains, dangling chains and cross-linking chains. As a proof of concept, we demonstrate that the SAP can act as a skin-friendly fixer to monitor human pulse by integrating with poly (vinylidene fluoride-trifluorethylene)/reduced graphene oxide (P(VDF-TrFE)@rGO) nanofiber sensor. This study provides a clue to design durable and skin-friendly adhesives with controlled adhesion for wearable devices. 1. INTRODUCTION Wearable devices are of paramount importance in human healthcare,1,2 including real-time sensing of sweat,3-5 articular thermotherapy,6 drug delivery,7,8 human motion monitor,9 selfpowered biomedical systems,10 and piezoelectric nanogenerators.11 Generally, those devices are fixed with the skin via wrist-bands, wearable straps, and acrylic tapes.12,13 However, bands and straps difficultly make closely conformal contact with the skin surface,12 and conventional acrylic tapes often result in red spots and pain during adhesive removal,14 especially for the elderly and children.15 It is strongly demanded to develop skin-friendly adhesives with controlled adhesion for the wearable devices. Some unique adhesion phenomena in nature inspire us to design artificial adhesive materials. For example, gecko achieves controlled adhesion through hierarchical fibrillar microsetae and nanospatula,16 tree frog achieves controlled adhesion through micro/nano channel structured 2 ACS Paragon Plus Environment

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toe pads,17,18 and octopus achieves controlled adhesion through the dome-like protuberances in the suction cups.19 These unique natural adhesion phenomena brought out a series of adhesioncontrolled materials, including gecko-inspired hierarchical polymer nanosetae,20 channel patterned surface mimicking the toe pad of tree frog,21 and adhesive patches with protuberances in suction cups inspired by octopus.19 However, most of these biomimetic adhesive materials inevitably depend on ingenious surface micro/nano-structures. It remains a great challenge to develop an alternative strategy which is independent on surface structure to prepare a kind of skin-friendly adhesive tape with controlled adhesion. Herein, we report a skin adhesive patch of polydimethylsiloxane (SAP) with controlled adhesion by merely tuning polymer chain mobility, without any elaborate micro/nano surface structure. We also demonstrate that SAP can act as a skin-friendly fixer to adhere wearable strain sensor. PDMS is a kind of elastomer commonly used in the fields of microfluids devices,22 stretchable electronics sealants23 as well as biomedical implants24 for its good transparency, chemical inertia, softness and stretchability. Usually, Sylgard 184 (Dow Corning) is the widely used PDMS-based elastomer (Hereafter, the PDMS or PDMS-based elastomer refer to Sylgard 184 except for specific situation). We reveal that the skin adhesion strongly depends on the proportion of polymer chains, including free chains, dangling chains, and crosslinking chains,25,26 as shown in Figure 1. Note that free chains are trapped in the polymer network without fixation, dangling chains are connected to the network by one end, crosslinking chains are connected to the network by both ends. The uncross-linked PDMS adhesive liquid with plenty of free chains was highly mobile and easy to spread on the substrate because of its high mobility (Figure 1a, d). Compared with the highly cross-linked PDMS (Figure 1c, f), the low cross-linked PDMS (Figure 1b, e) with more free chains and dangling chains adhered more tightly to the substrate. 2. EXPERIMENTAL SECTION

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2.1 Fabrication of SAPs. PDMS base was mixed with cross-linking agent (Sylgard 184, Dow Corning, USA) under mechanical stirring at various amounts of curing agent (2.0 wt.%, 2.4 wt.%, 3.2 wt.%, 4.8 wt.%, 9.1 wt.%). Degassed PDMS mixtures were cured at 80 °C for 0.5 hour. After cooling to room temperature, the PDMS samples were used as skin adhesives. 2.2 Skin Adhesion Force Experiments. The skin adhesion force of the SAP was measured using a tensile tester (Mark-10 ESM301) based on peeling model. The long strip samples were sticked on the skin of volunteer’s forearm. The end of the strips were clamped, and pulled upward at a constant speed of 15 mm/s (inset, Figure 2a). The angle between the strip and the forearm skin maintained 90 degrees until the strip was completely detached from the skin. The long strip sample was prepared by laminating a PDMS prepolymer on a plastic film with a film applicator (PA2041, BYK) and then cutted to the size of 80 mm × 15 mm × 200 μm for the test. The maximum force read during the peel test is the skin adhesion force. 2.3 Normal Adhesion Tests on the PDMS adhesives. Adhesion measurements were performed on universal material tester (CETR-UMT-2, Bruker) with a sapphire sphere indenter with diameter 5 mm. The load range is 5 mN-500 mN and the load resolution is 50 μN. The procedure of the test was as follows: the indenter was applied to the PDMS sample with a prepressure of 10 mN for 20 seconds, and then was lifted up at a rate of 50 μm/s, and the forcedistance curves were recorded throughout the process. For each sample, the same process was repeated 20 times to test the durability of PDMS adhesion. The samples were also subjected to cyclic normal indentation by a sphere at different retract rates of indenter displacement. Experiments were conducted on each sample with retract speeds ranging from 2 μm/s to 500 μm/s. 2.4 Mechanical Property Experiments. The tensile test was carried out on an electric test bench (Mark-10 ESM301) at a speed of 100 mm/min. The test sample was a dog-bone shape obtained by cutting. 4 ACS Paragon Plus Environment

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2.5 NMR experiments. The nuclear magnetic test of PDMS was performed on VTMR20010V-T (Shanghai Niumag Electronic Technology Co., Ltd., China). The parameters of the test were set as follows: test temperature 60 °C, magnet temperature 35 °C, magnet strength 0.5 T, resonance frequency 21.31 MHz. The selection of the test temperature of 60 °C is mainly based on the following two considerations: on the one hand, it is advantageous to distinguish the difference between samples of different cross-linking densities, and at the temperature of 60 °C, the sample is not subjected to thermal damage. 2.6 Biocompatibility tests. The biocompatibility of SAP and acrylic medical patches (273325, 3M, Japan) was tested by attaching the same size of two adhesives (3 cm × 3 cm) on the forearm skin of a volunteer for the time period up to 1 day. Then, some known side effects such as redness were compared. 2.7 Fabrication and Characterization of the skin-attachable sensor. The skin-attachable sensor was fabricated by following the procedure of Lou and Shen.27 P(VDF-TrFE)@rGO nanofibers are sandwiched between the upper and lower SAP layers, and the two ends are connected by copper electrodes to external copper wires for testing. When testing the pulse, the sensor was directly attached to the arm, and then a copper wire is connected to a Keithley 6487 picoammeter (Keithley Instruments, Cleveland, OH) to test the resistance change over time during the pulse beat. The main dimensions of the sensor are as follows: the sensor size is 10 mm x 1.2 mm x 1.3 mm and the distance between the two copper electrodes is 1 cm. The size of the sample can be adjusted depending on the occasion. The preparation process of the 500 μm SAP was as follows: the PDMS prepolymer with cross-linking agent content 2.0 wt.% was spin-coated on a silicon substrate at 700 rpm by spin coater (MYCRO), and cured at 80 °C for 0.5 h, then peeled off from the silicon substrate, and cutted to the required size. 3. RESULTS AND DISCUSSION

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To explore the influence of cross-linking agent amounts on the adhesive property of SAP, we measured the peeling forces of a series of SAP in 90o peel test (Figure 2a). When the crosslinking agent amount was as low as about 2.0 wt.%, a strong adhesion force between SAP and a volunteer’s forearm skin was observed to be 1.27 N/cm. With the increasing amounts of crosslinking agent, the adhesion force decreases apparently (Figure 2b). When the cross-linking agent amount reached 9.1 wt.%, a weak adhesion force of SAP was only 0.02 N/cm, leading it easily peeled off (Figure 2a). Furthermore, to analyze the intrinsic adhesion of the as-prepared SAP, we carried out a sphere-on-plane test because the spherical indenter is insensitive to misalignment,28,29 As shown in Figure 3a, the spherical indenter slowly approaches and contacts the surface of SAP until reaching a certain loading force (Fl). Upon retracting, the force reaches equilibrium point at point a1 where there is no deformation between SAP and indenter. Subsequently, the maximum adhesion force is reached at point a2 when the crack initiates. At point a3, the relative displacement reaches the maximum δmax and then the indenter completely detaches from SAP. The shaded area from point a1 to point a3 represents the adhesion work Wadh needed to separate the indenter from the PDMS surface. The shaded area (adhesion work) and maximum relative displacement increased with decreasing cross-linking agent amounts (Figure S1a and 3b). These results indicate that the PDMS with less amount of cross-linking agent dissipates more energy. The amount of cross-linking agent also influences the mechanical properties of SAP. When the cross-linking agent reduces from 9.1 wt.% to 2.0 wt.%, the elongation at break increases from 172% to 304% and Young’s modulus decreases from 0.82 MPa to 11 kPa (Figure S2). This shows that the compliance and ductility of SAP increase with decreasing cross-linking agent amounts. Furthermore, there is no notable decay in adhesion force for all SAP samples with cross-linking agent contents ranging from 2.0 wt.% to 9.1 wt.% after 20 repeated sphere-on-plane tests (Figure S1b), suggesting a durable adhesive property of SAP.

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To further understand the adhesion mechanism of SAP, we investigated the influence of cross-linking agent amounts on the cross-linking density by swelling tests. Herein, toluene was used for swelling and sol extraction. Samples were weighed (Mi) and then immersed in the toluene for 36 hours. The samples reached swelling equilibrium state and were weighed (Ms). The swollen samples were dried to constant weight (Md) over 36 hours under vacuum at 85 °C. The soluble fraction Fs and the swelling ratio Q are calculated from the relations as follows:30

Fs 

Q  1

Mi - Md Mi

ρ polymer M s  M d ρtoluene Md

(1)

(2)

in which  polymer and toluene are density of the PDMS and the toluene, respectively. Figure S3 shows that the soluble fraction Fs and the swelling ratio Q decreased with increasing crosslinking agent amounts, which indicates PDMS becomes more cross-linked.31 To further investigate the relevance between adhesion force and different cross-linking density, we tested the evolution of adhesion force (F) under different retract speeds (Figure 3c). When the crosslinking agent content decreased, the increase of retract speed (ν) during high retract speed (𝐹 ∝ 𝜈𝛽) can cause more increase of the adhesion force (F), from ν15.9 for the PDMS with 9.1 wt.% of cross-linking agent to ν50.4 for the PDMS with 2.0 wt.% of cross-linking agent as the inset shows. These results indicate that the mobility of PDMS chains become easier with decreasing restrictions of the chemical cross-linking network. To explore the restriction effect of cross-linking agent on the mobility of PDMS chains, molecular network structures of PDMS with varying amounts of cross-linking agent were analyzed by the nuclear magnetic resonance spectrometer (NMR).32,33 The PDMS networks above the glass transition temperature (𝑇𝑔 ≈ ― 120 ℃) are composed of three main different kinds of chains: free chains, dangling chains, and cross-linking chains. The three different

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molecular chains produce distinguishable relaxation signals in NMR experiments.25 The total transversal magnetization decay (M (t)) can be described as follows:34

(

𝑡

)

(

𝑡

)

(

𝑡

)

𝑀(𝑡) = 𝐴𝑒𝑥𝑝 ― 𝑇2 ― 0.5𝑞𝑀2𝑡2 +𝐵𝑒𝑥𝑝 ― 𝑇2 +𝐶𝑒𝑥𝑝 ― 𝑇2𝑠 + 𝐴0

(3)

where M (t) is the detected signal, t is decay time, A, B, C are the part signal of the cross-linking chains, dangling chains, and free chains to the total signal content, respectively. T2 is the transversal relaxation time of cross-linking chains and dangling chains signal. T2s is the transversal relaxation time of the free chains signal. qM2 is the average remaining part of dipolar magnetic coupling, where M2 is the second moment of the rigid lattice and q is the ratio factor between the second moment above the glass transition temperature to the second moment of the rigid lattice. A0 is used to compensate for possible signal offsets.34 NMR spectra can give us a series of data, the signal intensity of PDMS (M (t)) at various cross-linking levels as a function of decay time (t) (Figure S4). After we brought the NMR test data into Equation 3, we got the parameters A , B, and C, the proportion of cross-linking, dangling chains, and free chains. As shown in Figure 3d, the proportion of dangling chains (green strands) and free chains (yellow strands) decrease and cross-linking chains (blue strands) increase with increasing crosslinking agent amounts. These results could reveal that low cross-linked PDMS with more free chains and dangling chains show higher adhesion than highly cross-linked PDMS with less free chains and dangling chains (Figure 3e, f), which is consistent with the adhesion force trend in Figure 2b. The adhesion force between PDMS and substrate is mainly derived from van der Waals force.17 The main reason for the high adhesion of PDMS with low cross-linking degree is that it contains more free chains and dangling chains. The highly mobile chains make the PDMS easily and conformally contact the substrate, increasing van der Waals force. Therefore, we chose low cross-linked PDMS as skin adhesive tape. To demonstrate the skin adhesion and biocompatible properties of SAP, we adhered one piece of coin (25 mm in diameter) onto the back of hand through low cross-linked PDMS (Figure 4a). The coin attached firmly onto the skin even the hand was violently rocking from 8 ACS Paragon Plus Environment

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side to side as shown in Figure 4b and Movie S1 (Supporting Information), which illustrates strong skin adhesion of SAP. We compared the biocompatibility of commercial acrylic adhesive patches with SAP by observing the forearm skin of volunteers after 24-hour adhesion.15,35 For the SAP, there is scarcely any red spots and hurts (Figure 4c). However, the skin under patch became apparently red for commercial acrylic adhesive patches (Figure 4d). It is probably caused by the damaged skin after removal and a small amount of residual adhesive.15,35 As a proof of concept, the SAP was used to construct a wearable pulse sensor as a skin-friendly fixer (Figure 4e). In brief, this wearable pulse sensor was fabricated via layerby-layer sandwiched structure. P(VDF-TrFE)@rGO nanofibers were between two SAPs (Figure S5). This sensing mechanism can be explained by the force-induced contact changes in the sandwiched sensor structure.27 To demonstrate the practicality, the wearable pulse sensor was sticked on the volunteer’s wrist skin just above the radial artery, as shown in Figure 4e. The sensor can continuously record the pulse beats for several cycles (Figure 4f), and one pulse pressure wave has two characteristic peaks (Figure 4g).36 These results confirm that the SAP is capable to adhere wearable devices closely onto skin surface as a friendly fixer. 4. Conclusion In conclusion, we develop a molecule mobility-based strategy to prepare skin-friendly adhesive patch with controlled adhesion towards potential wearable applications. Surface adhesion of SAP strongly depends on the proportion of polymer chains with different mobility. Free chains and dangling chains with high mobility facilitate surface adhesion. Low cross-linked PDMS with more free chains and dangling chains shows higher surface adhesion than highly crosslinked PDMS with less free chains and dangling chains. The controlled skin adhesion of SAP is independent on any surface structure and the skin-friendly SAP has been successfully applied to fix wearable sensors to monitor human pulse. It is anticipated that the SAP can facilitate the development of epidermal electronics and biomedical adhesive. This strategy based on

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molecular mobility will provide a general principle to regulate surface adhesion and design adhesive patches based on current materials, such as hydrogel, elastomer and so on.

ASSOCIATED CONTENT Supporting Information. The Supporting Information is available free of charge on the ACS Publications website at DOI: www.acs.org. The contact curves and durable adhesive property of SAPs (Figure S1). The stress-strain curves for the SAPs with varying amounts of cross-linking agent (Figure S2). Evolution of the soluble fraction Fs and swelling ratio Q for PDMS with various cross-linking agent amounts (Figure S3). The signal strengths of the PDMS with various cross-linking agent amounts were detected with the changes in decay time (Figure S4). Schematic diagrams of the preparation of the skinattachable sensor (Figure S5). The adhesion forces of PDMS tape on different substrates (Figure S6). A coin sticks firmly to the back of the volunteer’s left hand through the SAP (thickness: 500 μm, area: 1 × 1 cm2) even the hand is violently rocking from side to side (Movie S1). AUTHOR INFORMATION Corresponding Author * E-mail: [email protected] (Shutao Wang) Author Contributions Z. Gu and X. Z. Wan contributed equally to this work. Notes The authors declare no competing financial interest.

ACKNOWLEDGMENT This research is supported by the National Research Fund for National Natural Science Foundation (21425314, 21434009 and 21421061), National Program for Special Support of 10 ACS Paragon Plus Environment

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Eminent Professionals, Fundamental Research Funds for the Central Universities (FRF-TP-17051A1, FRF-BR-17-002B).

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(12) Kim, D. H.; Lu, N. S.; Ma, R.; Kim, Y. S.; Kim, R. H.; Wang, S. D.; Wu, J.; Won, S. M.; Tao, H.; Islam, A.; Yu, K. J.; Kim, T. I.; Chowdhury, R.; Ying, M.; Xu, L. Z.; Li, M.; Chung, H. J.; Keum, H.; McCormick, M.; Liu, P.; Zhang, Y. W.; Omenetto, F. G.; Huang, Y. G.; Coleman, T.; Rogers, J. A., Epidermal Electronics. Science 2011, 333, 838-843. (13) Son, D.; Lee, J.; Qiao, S.; Ghaffari, R.; Kim, J.; Lee, J. E.; Song, C.; Kim, S. J.; Lee, D. J.; Jun, S. W.; Yang, S.; Park, M.; Shin, J.; Do, K.; Lee, M.; Kang, K.; Hwang, C. S.; Lu, N. S.; Hyeon, T.; Kim, D. H., Multifunctional wearable devices for diagnosis and therapy of movement disorders. Nat. Nanotechnol. 2014, 9, 397-404. (14) Karp, J. M.; Langer, R., Dry solution to a sticky problem. Nature 2011, 477, 42-43. (15) Kwak, M. K.; Jeong, H. E.; Suh, K. Y., Rational Design and Enhanced Biocompatibility of a Dry Adhesive Medical Skin Patch. Adv. Mater. 2011, 23, 3949-3953. (16) Arzt, E.; Gorb, S.; Spolenak, R., From micro to nano contacts in biological attachment devices. P. Natl. Acad. Sci. USA 2003, 100, 10603-10606. (17) Yeo, W. H.; Kim, Y. S.; Lee, J.; Ameen, A.; Shi, L. K.; Li, M.; Wang, S. D.; Ma, R.; Jin, S. H.; Kang, Z.; Huang, Y. G.; Rogers, J. A., Multifunctional Epidermal Electronics Printed Directly Onto the Skin. Adv. Mater. 2013, 25, 2773-2778. (18) Drotlef, D. M.; Blumler, P.; del Campo, A., Magnetically Actuated Patterns for Bioinspired Reversible Adhesion (Dry and Wet). Adv. Mater. 2014, 26, 775-779. (19) Baik, S.; Kim, D. W.; Park, Y.; Lee, T. J.; Bhang, S. H.; Pang, C., A wet-tolerant adhesive patch inspired by protuberances in suction cups of octopi. Nature 2017, 546, 396-400. (20) Rong, Z. X.; Zhou, Y. M.; Chen, B. A.; Robertson, J.; Federle, W.; Hofmann, S.; Steiner, U.; Oppenheimer, P. G., Bio-Inspired Hierarchical Polymer Fiber-Carbon Nanotube Adhesives. Adv. Mater. 2014, 26, 1456-1461. (21) Drotlef, D. M.; Stepien, L.; Kappl, M.; Barnes, W. J. P.; Butt, H. J.; del Campo, A., Insights into the Adhesive Mechanisms of Tree Frogs using Artificial Mimics. Adv. Funct. Mater. 2013, 23, 1137-1146. (22) Wang, S.; Liu, K.; Liu, J.; Yu, Z. T. F.; Xu, X.; Zhao, L.; Lee, T.; Lee, E. K.; Reiss, J.; Lee, Y.-K.; Chung, L. W. K.; Huang, J.; Rettig, M.; Seligson, D.; Duraiswamy, K. N.; Shen, C. K. F.; Tseng, H.-R., Highly Efficient Capture of Circulating Tumor Cells by Using Nanostructured Silicon Substrates with Integrated Chaotic Micromixers. Angew. Chem., Int. Ed. 2011, 50, 3084-3088. (23) Liu, N.; Chortos, A.; Lei, T.; Jin, L. H.; Kim, T. R.; Bae, W. G.; Zhu, C. X.; Wang, S. H.; Pfattner, R.; Chen, X. Y.; Sinclair, R.; Bao, Z. A., Ultratransparent and stretchable graphene electrodes. Sci. Adv. 2017, 3, e1700159. (24) Jeong, S. H.; Zhang, S.; Hjort, K.; Hilborn, J.; Wu, Z. G., PDMS-Based Elastomer Tuned Soft, Stretchable, and Sticky for Epidermal Electronics. Adv. Mater. 2016, 28, 5830-5837. (25) Simon, G.; Baumann, K.; Gronski, W., Mc determination and molecular dynamics in crosslinked 1,4-cis-polybutadiene: a comparison of transversal proton and deuterium NMR relaxation. Macromolecules 1992, 25, 3624-3628. (26) Gu, Z.; Zhang, X.; Bao, C.; Xue, M.; Wang, H.; Tian, X. Y., Crosslinking-dependent relaxation dynamics in ethylene-propylene-diene (EPDM) terpolymer above the glass transition temperature. J. Macromol. Sci. B 2015, 54, 618-627. (27) Lou, Z.; Chen, S.; Wang, L.; Jiang, K.; Shen, G., An ultra-sensitive and rapid response 12 ACS Paragon Plus Environment

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speed graphene pressure sensors for electronic skin and health monitoring. Nano Energy 2016, 23, 7-14. (28) Boesel, L. F.; Greiner, C.; Arzt, E.; del Campo, A., Gecko-Inspired Surfaces: A Path to Strong and Reversible Dry Adhesives. Adv. Mater. 2010, 22, 2125-2137. (29) Lim, C.; Huang, J.; Kim, S.; Lee, H.; Zeng, H.; Hwang, D. S., Nanomechanics of Poly(catecholamine) Coatings in Aqueous Solutions. Angewandte Chemie International Edition 2016, 55, 1-6. (30) Planes, E.; Chazeau, L.; Vigier, G.; Fournier, J.; Stevenson-Royaud, I., Influence of fillers on mechanical properties of ATH filled EPDM during ageing by gamma irradiation. Polym. Degrad. Stabil. 2010, 95, 1029-1038. (31) Gu, Z.; Zhang, X.; Ding, X.; Bao, C.; Fang, F.; Li, S.; Zhou, H.; Xue, M.; Wang, H.; Tian, X., Two coupled effects of sub micron silica particles on the mechanical relaxation behavior of ethylene-propylene-diene rubber chains. Soft Matter 2014, 10, 6087-6095. (32) Saalwachter, K., Detection of heterogeneities in dry and swollen polymer networks by proton low-field NMR spectroscopy. J. Am. Chem. Soc. 2003, 125, 14684-14685. (33) Lv, X. R.; Song, S. Y.; Wang, H. M.; Wang, S. J., Effect of CO2 Gas on the Swelling and Tribological Behaviors of NBR Rubber in Water. J. Mater. Sci. Technol. 2015, 31, 1282-1288. (34) Peng-fei, G.; Lin-lin, C.; Yi, Y.; JIANG, J.-f.; Jia-chen, W.; Ye-feng, Y.; Bing, Z., Comparison of Three NMR Methods for Measuring Crosslink Density of Rubbers. Chin. J. Magn. Reson. 2017, 34, 408-420. (35) Laulicht, B.; Langer, R.; Karp, J. M., Quick-release medical tape. P. Natl. Acad. Sci. USA 2012, 109, 18803-18808. (36) Nichols, W. W., Clinical measurement of arterial stiffness obtained from noninvasive pressure waveforms. Am. J. Hypertens. 2005, 18, 3S-10S.

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Figure 1. Design of skin adhesive patches of PDMS (SAPs) by regulating the polymer chain mobility. (a, d) Uncross-linked PDMS adhesive liquid with free chains can spread on the substrate because of its high mobility. (b, e) Low cross-linked PDMS with free chains and dangling chains can tightly adhere to the surface. (c, f) Highly cross-linked PDMS can be easily peeled off from the substrate because of its less free chains and dangling chains. Note that the PDMS was dyed red to make the interface clear.

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Figure 2. Skin adhesion properties of PDMS tape with different amounts of cross-linking agent. (a) Representative peeling force versus displacement curves for low and highly cross-linked PDMS (cross-linking agent amount of 2.0 wt.% and 9.1 wt.%, respectively) on a male volunteer’s forearm skin. Compared with highly cross-linked PDMS, the low cross-lined PDMS shows higher adhesion and is more difficultly peeled off from the skin. (b) The adhesion force of PDMS tape on the skin of a forearm decreases with increasing cross-linking agent amounts.

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Figure 3. The adhesion properties and chain mobility of PDMS with different cross-linking density. (a) We compressed SAP to the value of Fl (loading force) and then measured the resultant maximum separation force, named as adhesion force Fad. δmax: the maximum relative displacement. (b) Maximum relative displacement (δmax) and adhesion work (Wadh) for PDMS decrease with increasing cross-linking agent amounts. Wadh: the adhesion work denoted as the shadow area. (c) Adhesion force (Fad) versus retract speed (ν) of PDMS with various crosslinking agent amounts. The inset shows the slope (β) of the Fad-ν curve decreases with increasing cross-linking agent amounts. (d) The dangling chains (green strands) and free chains (yellow strands) decrease with the cross-linking agent amounts. (e, f) Compared with PDMS 16 ACS Paragon Plus Environment

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with higher cross-linking agent amount, the network with low cross-linking agent amount has more free chains and dangling chains.

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Figure 4. Adhesion and skin-compatible performance of SAP and the SAP-based strain sensor. The SAP can tightly attach a coin onto the back of hand (a), and the coin cannot be detached even though hand-shaken violently from side to side (b). For the SAP, there is almost none red spots and hurts (c). For commercial acrylic adhesives, they usually generate red spots and pain after one-day adhesion on skin (d). A P(VDF-TrFE)@rGO based strain sensor was tightly sticked on the wrist skin through the SAP (e), which can monitor pulse characteristics (f, g).

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