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Journal articles on the topic 'Bio-Interfaces'

Author: Grafiati
Published: 4 June 2021
Last updated: 20 June 2025

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1

Cai, Pingqiang, Xiaoqian Zhang, Ming Wang, Yun-Long Wu, and Xiaodong Chen. "Combinatorial Nano–Bio Interfaces." ACS Nano 12, no. 6 (2018): 5078–84. http://dx.doi.org/10.1021/acsnano.8b03285.

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2

Balakumar Muniandi. "Bio-Electronics Interface between Electronics and Biological Systems for Healthcare Applications." Power System Technology 48, no. 1 (2024): 698–714. http://dx.doi.org/10.52783/pst.329.

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The intersection of electronics and biology has led to the emergence of bio-electronics interfaces, which hold tremendous potential for revolutionizing healthcare applications. These interfaces facilitate seamless communication between electronic devices and biological systems, enabling a range of diagnostic, therapeutic, and monitoring capabilities with unprecedented precision and efficiency.This paper provides a comprehensive overview of the recent advancements in bio-electronics interfaces and their diverse applications in healthcare. The fundamental principles underlying the integration of electronics with biological systems, including the design and fabrication of bio-compatible materials, signal transduction mechanisms, and biointegration strategies are discussed. [1] The paper discusses specific healthcare applications enabled by bio-electronics interfaces, such as bio-sensing for disease diagnosis, neural interfaces for brain-machine communication and prosthetics, bio-electronic implants for targeted drug delivery and neuromodulation, and wearable devices for continuous health monitoring. We also examine the challenges and opportunities associated with the development and implementation of bio-electronics interfaces in healthcare settings. These challenges include biocompatibility issues, signal interference, power management, data security, and regulatory considerations. However, rapid advancements in materials science, microfabrication techniques, wireless communication, and machine learning are driving innovation and overcoming these hurdles. We highlight the potential of bio-electronics interfaces to transform personalized medicine by enabling real-time monitoring of physiological parameters, early detection of diseases, and personalized therapeutic interventions tailored to individual patients' needs. By integrating electronic devices with biological systems at the molecular, cellular, and organismal levels, bio-electronics interfaces have the potential to revolutionize healthcare delivery, improve patient outcomes, and enhance quality of life.
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3

Zhu, Guolong, Ziyang Xu, and Li-Tang Yan. "Entropy at Bio–Nano Interfaces." Nano Letters 20, no. 8 (2020): 5616–24. http://dx.doi.org/10.1021/acs.nanolett.0c02635.

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4

Roke, Sylvie. "Nonlinear spectroscopy of bio-interfaces." International Journal of Materials Research 102, no. 7 (2011): 906–12. http://dx.doi.org/10.3139/146.110535.

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5

Caliò, Alessandro, Ilaria Rea, Jane Politi, Paola Giardina, Sara Longobardi, and Luca De Stefano. "Hybrid bio/non-bio interfaces for protein-glucose interaction monitoring." Journal of Applied Physics 114, no. 13 (2013): 134904. http://dx.doi.org/10.1063/1.4824379.

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6

Chen, Weiqiang, and Deok‐Ho Kim. "Special Issue: Bio‐Interfaces for Immunoengineering." Advanced Healthcare Materials 8, no. 4 (2019): 1900098. http://dx.doi.org/10.1002/adhm.201900098.

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7

Wong, Ian Y., Benjamin D. Almquist, and Nicholas A. Melosh. "Dynamic actuation using nano-bio interfaces." Materials Today 13, no. 6 (2010): 14–22. http://dx.doi.org/10.1016/s1369-7021(10)70105-x.

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8

Weng, Bo, Jianglin Diao, Qun Xu, et al. "Bio-Interfaces: Bio-Interface of Conducting Polymer-Based Materials for Neuroregeneration (Adv. Mater. Interfaces 8/2015)." Advanced Materials Interfaces 2, no. 8 (2015): n/a. http://dx.doi.org/10.1002/admi.201570037.

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9

Seo, Ji Hun, Sachiro Kakinoki, Tetsuji Yamaoka, and Nobuhiko Yui. "Movable Polyrotaxane Surfaces for Modulating Cellular Adhesion via Specific RGD-Integrin Binding." Advances in Science and Technology 86 (September 2012): 59–62. http://dx.doi.org/10.4028/www.scientific.net/ast.86.59.

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Immobilizing bioactive molecules on the materials surfaces is one of the main strategies for creating functional bio-interfaces. In these kinds of bio-interfaces, the density of immobilized functional groups and the following physicochemical factors such as roughness, polarity and electrical charge have been thought important variables for regulating biological responses such as cell adhesion and differentiations. Here in this study, differences between rigidity and dynamically immobilized bioactive molecules on the biological responses will be discussed. In order to develop dynamic bio-interfaces, a polyrotaxane based block-copolymer containing clickable azide groups for conjugating various bioactive molecules was designed. Cell adhesive RGD peptide was then conjugated with the azide group by click reaction on both dynamic and rigid surfaces. As a result, cell adhesive RGD peptide immobilized on the dynamic bio-interfaces shows larger initial cell adhesion area, indicating that molecular dynamics of surface chemical groups is another important variable for the regulation of biological responses.
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10

Jena, Soumyasree, Sanchari Bhattacharya, and Sanjoy Datta. "Evidence of half-metallic-2DHG at BiFeO3 based heterointerfaces." Journal of Physics: Conference Series 2518, no. 1 (2023): 012020. http://dx.doi.org/10.1088/1742-6596/2518/1/012020.

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Abstract The electronic properties of tetragonal BiFeO3 based hetero-structures, along with the tetragonal phase of SrTiO3 and PbTiO3 in (001) direction, is investigated with two types of interfaces. In the case of BiFeO3/SrTiO3(001) hetero-structure, the (FeO2)−/(SrO)0, and (BiO)+/(TiO2)0 interfaces are investigated respectively. For BiFeO3/PbTiO3(001) hetero-structure, the (FeO2)−/(PbO)0, and (BiO)+ / (TiO2)0 interfaces are studied. A tiny amount of half-metallicity has been found in the (FeO2)−/(SrO)0 interface while (BiO)+/(TiO2)0 interface behaves as metallic in the case of BiFeO3/SrTiO3(001) heterostructure. However, interestingly, (FeO2)−/(PbO)0 interface turns out to be a prominent half-metal with hole-type charge carriers, and (BiO)+/(TiO2)0 exhibits two-dimensional electron gas in the case of BiFeO3/PbTiO3(001).
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11

ARIGA, Katsuhiko. "Mechano-Nanoarchitectonics for Bio-Functions at Interfaces." Analytical Sciences 32, no. 11 (2016): 1141–49. http://dx.doi.org/10.2116/analsci.32.1141.

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12

Zhao, Qilong, and Xuemin Du. "Multi-scale adaptions of dynamic bio-interfaces." Smart Materials in Medicine 3 (2022): 37–40. http://dx.doi.org/10.1016/j.smaim.2021.12.001.

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13

Hernandez-Aristizabal, David, Santiago Arroyave-Tobon, and Jean-Marc Linares. "Bio-inspired Generative Design for Contact Interfaces." Procedia CIRP 128 (2024): 245–49. http://dx.doi.org/10.1016/j.procir.2024.03.011.

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14

Audette, Gerald F., Stephanie Lombardo, Jonathan Dudzik, et al. "Protein hot spots at bio-nano interfaces." Materials Today 14, no. 7-8 (2011): 360–65. http://dx.doi.org/10.1016/s1369-7021(11)70167-5.

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15

Marino, Attilio, Giada Graziana Genchi, Edoardo Sinibaldi, and Gianni Ciofani. "Piezoelectric Effects of Materials on Bio-Interfaces." ACS Applied Materials & Interfaces 9, no. 21 (2017): 17663–80. http://dx.doi.org/10.1021/acsami.7b04323.

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16

Rochford, Amy E., Alejandro Carnicer‐Lombarte, Vincenzo F. Curto, George G. Malliaras, and Damiano G. Barone. "When Bio Meets Technology: Biohybrid Neural Interfaces." Advanced Materials 32, no. 15 (2019): 1903182. http://dx.doi.org/10.1002/adma.201903182.

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17

Tang, Y. H., and H. P. Zhang. "Theoretical understanding of bio-interfaces/bio-surfaces by simulation: A mini review." Biosurface and Biotribology 2, no. 4 (2016): 151–61. http://dx.doi.org/10.1016/j.bsbt.2016.11.003.

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18

Hu, Xinghao, Sandhya Rani Goudu, Sri Ramulu Torati, Byeonghwa Lim, Kunwoo Kim, and CheolGi Kim. "An on-chip micromagnet frictionometer based on magnetically driven colloids for nano-bio interfaces." Lab on a Chip 16, no. 18 (2016): 3485–92. http://dx.doi.org/10.1039/c6lc00666c.

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A novel method based on remotely controlled magnetic forces of bio-functionalized superparamagnetic colloids using micromagnet arrays was devised to measure frictional force at the sub-picoNewton (pN) scale for bio-nano-/micro-electromechanical system (bio-NEMS/MEMS) interfaces in liquid.
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19

Seki, Takakazu, Chun-Chieh Yu, Xiaoqing Yu, et al. "Decoding the molecular water structure at complex interfaces through surface-specific spectroscopy of the water bending mode." Physical Chemistry Chemical Physics 22, no. 19 (2020): 10934–40. http://dx.doi.org/10.1039/d0cp01269f.

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The water bending mode vibrational spectroscopy provides a new avenue for unveiling the hydrogen bonding structure of interfacial water at complex aqueous interfaces such as solid–water and bio–water interfaces.
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20

Yann Ponty. "Bio-algorithmique des ARN : petite promenade aux interfaces." Bulletin 1024, no. 4 (October 2014): 23–53. http://dx.doi.org/10.48556/sif.1024.4.23.

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21

Li, Ming, Chang Li, Bamber R. K. Blackman, and Eduardo Saiz. "Energy conversion based on bio-inspired superwetting interfaces." Matter 4, no. 11 (2021): 3400–3414. http://dx.doi.org/10.1016/j.matt.2021.09.018.

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22

Shaer, Orit, Consuelo Valdes, Sirui Liu, et al. "Designing reality-based interfaces for experiential bio-design." Personal and Ubiquitous Computing 18, no. 6 (2013): 1515–32. http://dx.doi.org/10.1007/s00779-013-0752-1.

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23

Cai, Pingqiang, Wan Ru Leow, Xiaoyuan Wang, Yun-Long Wu, and Xiaodong Chen. "Programmable Nano-Bio Interfaces for Functional Biointegrated Devices." Advanced Materials 29, no. 26 (2017): 1605529. http://dx.doi.org/10.1002/adma.201605529.

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24

Ratna, K. "Examining the synergy of interfacial science and rheology: A review." i-manager's Journal on Chemical Sciences 3, no. 2 (2023): 1. http://dx.doi.org/10.26634/jchem.3.2.20324.

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Interfaces, where different fluids meet, are crucial zones influencing processes like emulsification and foam creation. Understanding their properties is vital in chemical, biosciences and oil industry. Rheology, evaluating stress and strain, helps characterize these properties, distinguishing between material behavior like elasticity and viscosity. Stress causes deformation, crucial in defining a material's response. Elastic materials return to shape after stress, maintaining ratios. Interfacial studies benefit diverse fields like engineering, biology, and medicine, unveiling unique properties for material design. In biology, studying bio-interfaces elucidates complex cell behaviors and drug delivery. Recent research emphasizes the importance of studying interfaces. Peptide interfaces exhibit self-organization in cell elongation, while motor protein-based nano-biodevices and antimicrobial implant surfaces demonstrate new applications. Interfacial studies impact nanocomposites, dental materials, cancer stem cells, and nanospheres, showcasing their broad implications in diverse fields. Nanotechnology combined with biology creates new medical possibilities. Nanomedicine, using nanoparticles, shows promise in drug delivery and cancer treatment. Challenges exist in understanding bio-interfaces, crucial for medical progress. Advances in nanotech and interfacial studies could transform fields with ongoing research needed for big changes.
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25

Kaur, Manvir, Harmandeep Kaur, Manpreet Singh, Gagandeep Singh, and Tejwant Singh Kang. "Biamphiphilic ionic liquid based aqueous microemulsions as an efficient catalytic medium for cytochrome c." Physical Chemistry Chemical Physics 23, no. 1 (2021): 320–28. http://dx.doi.org/10.1039/d0cp04513f.

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26

Dinca, Valentina. "Advanced Functional Bio-interfaces Engineering for Medical Applications: From Drug Delivery to Bio-scaffolds." Current Medicinal Chemistry 27, no. 6 (2020): 836–37. http://dx.doi.org/10.2174/092986732706200316153403.

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27

Vo, Richard, Huan-Hsuan Hsu, and Xiaocheng Jiang. "Hydrogel facilitated bioelectronic integration." Biomaterials Science 9, no. 1 (2021): 23–37. http://dx.doi.org/10.1039/d0bm01373k.

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28

Rupp, Ariana I. K. S., and Petra Gruber. "Bio-inspired evaporation from shaped interfaces: an experimental study." Bioinspiration & Biomimetics 16, no. 4 (2021): 045001. http://dx.doi.org/10.1088/1748-3190/abdd9e.

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29

Li, Jie, Na Lu, Suping Han, et al. "Construction of Bio-Nano Interfaces on Nanozymes for Bioanalysis." ACS Applied Materials & Interfaces 13, no. 18 (2021): 21040–50. http://dx.doi.org/10.1021/acsami.1c04241.

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30

Liu, Juewen, and Juewen Liu. "Freezing DNA for Controlling Bio/nano Interfaces and Catalysis." General Chemistry 5, no. 4 (2019): 190008. http://dx.doi.org/10.21127/yaoyigc20190008.

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31

TAGAYA, Motohiro. "Investigation of Bio-Nano Interfaces for Activating Cell Functions." KOBUNSHI RONBUNSHU 70, no. 8 (2013): 398–418. http://dx.doi.org/10.1295/koron.70.398.

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32

Bensaid, Imen, Sylvie Masse, Mohamed Selmane, Shemseddine Fessi, and Thibaud Coradin. "Growth of gold nanoparticles at gelatin-silica bio-interfaces." APL Materials 4, no. 1 (2016): 015704. http://dx.doi.org/10.1063/1.4935309.

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33

Morano, Chiara, Pablo Zavattieri, and Marco Alfano. "Tuning energy dissipation in damage tolerant bio-inspired interfaces." Journal of the Mechanics and Physics of Solids 141 (August 2020): 103965. http://dx.doi.org/10.1016/j.jmps.2020.103965.

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34

Abbate, Emanuela, Matteo Porro, Thierry Nieus, and Riccardo Sacco. "Hierarchical electrochemical modeling and simulation of bio-hybrid interfaces." Computer Methods in Applied Mechanics and Engineering 300 (March 2016): 561–92. http://dx.doi.org/10.1016/j.cma.2015.11.024.

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35

Hatakeyama, Hideyuki, Akihiko Kikuchi, Masayuki Yamato, and Teruo Okano. "Bio-functionalized thermoresponsive interfaces facilitating cell adhesion and proliferation." Biomaterials 27, no. 29 (2006): 5069–78. http://dx.doi.org/10.1016/j.biomaterials.2006.05.019.

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36

Louise Grothaus, Isabell, Giovanni Bussi, Janine Kirstein, Susan Köppen, and Lucio Colombi Ciacchi. "Unraveling disease mechanisms using molecular modeling of bio-interfaces." Biophysical Journal 122, no. 3 (2023): 481a. http://dx.doi.org/10.1016/j.bpj.2022.11.2573.

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37

Skorb, Ekaterina V., and Daria V. Andreeva. "Surface Nanoarchitecture for Bio-Applications: Self-Regulating Intelligent Interfaces." Advanced Functional Materials 23, no. 36 (2013): 4483–506. http://dx.doi.org/10.1002/adfm.201203884.

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38

Crescentini, Marco, Marco Bennati, and Marco Tartagni. "Recent Trends for (Bio)Chemical Impedance Sensor Electronic Interfaces." Electroanalysis 24, no. 3 (2012): 563–72. http://dx.doi.org/10.1002/elan.201100547.

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39

Carrara, Sandro. "Integrated Bio/Nano/CMOS interfaces for electrochemical molecular sensing." IEEJ Transactions on Electrical and Electronic Engineering 13, no. 11 (2018): 1534–39. http://dx.doi.org/10.1002/tee.22793.

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40

Qiao, He, Runguo Wang, Hui Yao, et al. "Preparation of graphene oxide/bio-based elastomer nanocomposites through polymer design and interface tailoring." Polymer Chemistry 6, no. 34 (2015): 6140–51. http://dx.doi.org/10.1039/c5py00720h.

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41

Tang, Xintong, Guanbin Gao, Ting Zhang, et al. "Charge effects at nano-bio interfaces: a model of charged gold nanoclusters on amylin fibrillation." Nanoscale 12, no. 36 (2020): 18834–43. http://dx.doi.org/10.1039/d0nr03877f.

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42

Kim, Seong-Oh, Joshua A. Jackman, Masahito Mochizuki, Bo Kyeong Yoon, Tomohiro Hayashi, and Nam-Joon Cho. "Correlating single-molecule and ensemble-average measurements of peptide adsorption onto different inorganic materials." Physical Chemistry Chemical Physics 18, no. 21 (2016): 14454–59. http://dx.doi.org/10.1039/c6cp01168c.

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43

Vaquero, Susana, Caterina Bossio, Sebastiano Bellani, et al. "Conjugated polymers for the optical control of the electrical activity of living cells." Journal of Materials Chemistry B 4, no. 31 (2016): 5272–83. http://dx.doi.org/10.1039/c6tb01129b.

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44

Campuzano, Susana, María Pedrero, Paloma Yáñez-Sedeño, and José Pingarrón. "Antifouling (Bio)materials for Electrochemical (Bio)sensing." International Journal of Molecular Sciences 20, no. 2 (2019): 423. http://dx.doi.org/10.3390/ijms20020423.

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(Bio)fouling processes arising from nonspecific adsorption of biological materials (mainly proteins but also cells and oligonucleotides), reaction products of neurotransmitters oxidation, and precipitation/polymerization of phenolic compounds, have detrimental effects on reliable electrochemical (bio)sensing of relevant analytes and markers either directly or after prolonged incubation in rich-proteins samples or at extreme pH values. Therefore, the design of antifouling (bio)sensing interfaces capable to minimize these undesired processes is a substantial outstanding challenge in electrochemical biosensing. For this purpose, efficient antifouling strategies involving the use of carbon materials, metallic nanoparticles, catalytic redox couples, nanoporous electrodes, electrochemical activation, and (bio)materials have been proposed so far. In this article, biomaterial-based strategies involving polymers, hydrogels, peptides, and thiolated self-assembled monolayers are reviewed and critically discussed. The reported strategies have been shown to be successful to overcome (bio)fouling in a diverse range of relevant practical applications. We highlight recent examples for the reliable sensing of particularly fouling analytes and direct/continuous operation in complex biofluids or harsh environments. Opportunities, unmet challenges, and future prospects in this field are also pointed out.
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45

Futera, Zdenek. "Amino-acid interactions with the Au(111) surface: adsorption, band alignment, and interfacial electronic coupling." Physical Chemistry Chemical Physics 23, no. 17 (2021): 10257–66. http://dx.doi.org/10.1039/d1cp00218j.

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Electronic properties of tryptophan, its band alignment to gold states and strong interfacial coupling, make this amino acid particularly suitable for charge transfer on heterogeneous bio-metallic interfaces.
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46

Demirci, Gokhan, Malwina J. Niedźwiedź, Nina Kantor-Malujdy, and Miroslawa El Fray. "Elastomer–Hydrogel Systems: From Bio-Inspired Interfaces to Medical Applications." Polymers 14, no. 9 (2022): 1822. http://dx.doi.org/10.3390/polym14091822.

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Novel advanced biomaterials have recently gained great attention, especially in minimally invasive surgical techniques. By applying sophisticated design and engineering methods, various elastomer–hydrogel systems (EHS) with outstanding performance have been developed in the last decades. These systems composed of elastomers and hydrogels are very attractive due to their high biocompatibility, injectability, controlled porosity and often antimicrobial properties. Moreover, their elastomeric properties and bioadhesiveness are making them suitable for soft tissue engineering. Herein, we present the advances in the current state-of-the-art design principles and strategies for strong interface formation inspired by nature (bio-inspiration), the diverse properties and applications of elastomer–hydrogel systems in different medical fields, in particular, in tissue engineering. The functionalities of these systems, including adhesive properties, injectability, antimicrobial properties and degradability, applicable to tissue engineering will be discussed in a context of future efforts towards the development of advanced biomaterials.
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47

Jin, Congrui, Zhen Yang, Jianlin Li, Yijing Zheng, Wilhelm Pfleging, and Tian Tang. "Bio-inspired interfaces for easy-to-recycle lithium-ion batteries." Extreme Mechanics Letters 34 (January 2020): 100594. http://dx.doi.org/10.1016/j.eml.2019.100594.

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48

Geckeler, Kurt E., Frank Rupp, and J�rgen Geis-Gerstorfer. "Interfaces and interphases of (bio)materials: Definitions, structures, and dynamics." Advanced Materials 9, no. 6 (1997): 513–18. http://dx.doi.org/10.1002/adma.19970090614.

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49

Tamerler, Candan. "Surfaces and Their Interfaces Meet Biology at the Bio-interface." JOM 67, no. 11 (2015): 2480–82. http://dx.doi.org/10.1007/s11837-015-1669-0.

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50

Arraez, Francisco J., Paul H. M. Van Steenberge, and Dagmar R. D’hooge. "A Generic Combined Matrix- and Lattice-Based Kinetic Monte Carlo Modeling Tool to Tune Surface-Initiated Polymerization." Proceedings 69, no. 1 (2020): 14. http://dx.doi.org/10.3390/cgpm2020-07206.

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The development of biofunctionalized polymer interfaces through the deposition of bio-derived polymeric layers to flat surfaces has attracted much attention, due to the wide range of potentially relevant applications. [...]
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