Microengineered poly(HEMA) hydrogels for wearable contact lens biosensing.

Microchannels in hydrogels play an essential role in enabling a smart contact lens. However, microchannels have rarely been created in commercial hydrogel contact lenses due to their sensitivity to conventional microfabrication techniques. Here, we report the fabrication of microchannels in poly(2-hydroxyethyl methacrylate) (poly(HEMA)) hydrogels that are used in commercial contact lenses with a three-dimensional (3D) printed mold. We investigated the corresponding capillary flow behaviors in these microchannels. We observed different capillary flow regimes in these microchannels, depending on their hydration level. In particular, we found that a peristaltic pressure could reinstate flow in a dehydrated channel, indicating that the motion of eye-blinking may help tears flow in a microchannel-containing contact lens. Colorimetric pH and electrochemical Na+ sensing capabilities were demonstrated in these microchannels. This work paves the way for the development of microengineered poly(HEMA) hydrogels for various biomedical applications such as eye-care and wearable biosensing.

[1]  Jang‐Ung Park,et al.  Smart Contact Lenses: Recent Advances in Smart Contact Lenses (Adv. Mater. Technol. 1/2020) , 2020, Advanced Materials Technologies.

[2]  Martin C. Hartel,et al.  Hydrogel‐Enabled Transfer‐Printing of Conducting Polymer Films for Soft Organic Bioelectronics , 2019, Advanced Functional Materials.

[3]  A. Yetisen,et al.  Contact Lens Technology: From Fundamentals to Applications , 2019, Advanced healthcare materials.

[4]  Wei Gao,et al.  Wearable and flexible electronics for continuous molecular monitoring. , 2019, Chemical Society reviews.

[5]  Seung Ho Lee,et al.  Noninvasive Self-diagnostic Device for Tear Collection and Glucose Measurement , 2019, Scientific Reports.

[6]  F. Fang,et al.  Contact Lens Materials: A Materials Science Perspective , 2019, Materials.

[7]  Shiming Zhang,et al.  Flexible self-powered biosensors , 2018, Nature.

[8]  Han-Sheng Chuang,et al.  Contact-Lens Biosensors , 2018, Sensors.

[9]  John A Rogers,et al.  A fluorometric skin-interfaced microfluidic device and smartphone imaging module for in situ quantitative analysis of sweat chemistry. , 2018, Lab on a chip.

[10]  Jaeyun Kim,et al.  Therapeutic Contact Lenses with Polymeric Vehicles for Ocular Drug Delivery: A Review , 2018, Materials.

[11]  Franklin Bien,et al.  Soft, smart contact lenses with integrations of wireless circuits, glucose sensors, and displays , 2018, Science Advances.

[12]  Zhixiong Zhang,et al.  Single cell dual adherent-suspension co-culture micro-environment for studying tumor-stromal interactions with functionally selected cancer stem-like cells. , 2016, Lab on a chip.

[13]  Mukhtar Ahmad,et al.  Fabrication of microchannels on PMMA using a low power CO2 laser , 2016 .

[14]  E. Yoon,et al.  High-Throughput Single-Cell Derived Sphere Formation for Cancer Stem-Like Cell Identification and Analysis , 2016, Scientific Reports.

[15]  Sam Emaminejad,et al.  Fully integrated wearable sensor arrays for multiplexed in situ perspiration analysis , 2016, Nature.

[16]  Tao Zhou,et al.  Microdynamics mechanism of D2O absorption of the poly(2-hydroxyethyl methacrylate)-based contact lens hydrogel studied by two-dimensional correlation ATR-FTIR spectroscopy. , 2016, Soft matter.

[17]  Ali K. Yetisen,et al.  A smartphone algorithm with inter-phone repeatability for the analysis of colorimetric tests , 2014 .

[18]  Aydogan Ozcan,et al.  A personalized food allergen testing platform on a cellphone. , 2013, Lab on a chip.

[19]  W. Qiu,et al.  Integration of cell phone imaging with microchip ELISA to detect ovarian cancer HE4 biomarker in urine at the point-of-care. , 2011, Lab on a chip.

[20]  G. Whitesides,et al.  Three-dimensional microfluidic devices fabricated in layered paper and tape , 2008, Proceedings of the National Academy of Sciences.

[21]  A. Cadotte,et al.  Poly-HEMA as a drug delivery device for in vitro neural networks on micro-electrode arrays , 2005, Journal of neural engineering.

[22]  D. Wilson,et al.  Stability of plasma-treated silicone rubber and its influence on the interfacial aspects of blood compatibility. , 2004, Biomaterials.

[23]  G. Qiao,et al.  Synthetic hydrogels 3. Solvent effects on poly(2-hydroxyethyl methacrylate) networks , 2004 .

[24]  C. Young,et al.  Fabrication and characteristics of polyHEMA artificial skin with improved tensile properties , 1998 .

[25]  Ernesto Occhiello,et al.  On the aging of oxygen plasma-treated polydimethylsiloxane surfaces , 1990 .

[26]  N. Peppas,et al.  Correlation between mesh size and equilibrium degree of swelling of polymeric networks. , 1989, Journal of biomedical materials research.

[27]  W. Coles,et al.  Dynamics of ocular surface pH. , 1984, The British journal of ophthalmology.

[28]  B. Ratner,et al.  Interaction of urea with poly(2‐hydroxyethyl methacrylate) hydrogels , 1972 .

[29]  M. Refojo Hydrophobic interaction in poly(2-hydroxyethyl methacrylate) homogeneous hydrogel. , 1967, Journal of polymer science. Part A-1, Polymer chemistry.

[30]  G. Baud,et al.  XPS characterisation of plasma-treated and alumina-coated PMMA , 2000 .