1. Lee PJ, Hung PJ, Lee LP. An artificial liver sinusoid with a microfluidic endothelial-like barrier for primary hepatocyte culture. Biotechnol Bioeng. 2007 Aug;97(5):1340-6.
2. Geraili A, Jafari P, Hassani MS, Araghi BH, Mohammadi MH, Ghafari AM, et al. Controlling differentiation of stem cells for developing personalized organ-on-chip platforms. Adv Healthc Mater. 2018 Jan;7(2):1700426.
3. Kieninger J, Weltin A, Flamm H, Urban GA. Microsensor systems for cell metabolism: from 2D culture to organ-on-chip. Lab Chip. 2018 May;18(9):1274-91.
4. Huh D, Torisawa YS, Hamilton GA, Kim HJ, Ingber DE. Microengineered physiological biomimicry: organs-on-chips. Lab Chip. 2012 Jun;12(12):2156-64.
6. Gurman P, Miranda OR, Clayton K, Rosen Y, Elman NM. Clinical applications of biomedical microdevices for controlled drug delivery. Mayo Clin Proc. 2015 Jan;90(1):93-108.
7. Whitesides GM. The origins and the future of microfluidics. Nature. 2006 Jul;442(7101):368-73.
8. Beebe DJ, Mensing GA, Walker GM. Physics and applications of microfluidics in biology. Annu Rev Biomed Eng. 2002;4:261-86.
9. Atencia J, Beebe DJ. Controlled microfluidic interfaces. Nature. 2005 Sep;437(7059):648-55.
10. Li Jeon N, Baskaran H, Dertinger SK, Whitesides GM, Van de Water L, Toner M. Neutrophil chemotaxis in linear and complex gradients of interleukin-8 formed in a microfabricated device. Nat Biotechnol. 2002 Aug;20(8):826-30.
13. Sai J, Rogers M, Hockemeyer K, Wikswo JP, Richmond A. Study of chemotaxis and cell-cell interactions in cancer with microfluidic devices. Methods Enzymol. 2016;570:19-45.
15. Seemann R, Brinkmann M, Pfohl T, Herminghaus S. Droplet based microfluidics. Rep Prog Phys. 2012 Jan;75(1):016601.
16. Sackmann EK, Fulton AL, Beebe DJ. The present and future role of microfluidics in biomedical research. Nature. 2014 Mar;507(7491):181-9.
17. Olanrewaju A, Beaugrand M, Yafia M, Juncker D. Capillary microfluidics in microchannels: from microfluidic networks to capillaric circuits. Lab Chip. 2018 Aug;18(16):2323-47.
20. Shadpour H, Musyimi H, Chen J, Soper SA. Physiochemical properties of various polymer substrates and their effects on microchip electrophoresis performance. J Chromatogr A. 2006 Apr;1111(2):238-51.
21. Young EW, Berthier E, Beebe DJ. Assessment of enhanced autofluorescence and impact on cell microscopy for microfabricated thermoplastic devices. Anal Chem. 2013 Jan;85(1):44-9.
22. Nie J, Gao Q, Wang Y, Zeng J, Zhao H, Sun Y, et al. Vessel-on-a-chip with Hydrogel-based Microfluidics. Small. 2018 Nov;14(45):e1802368.
23. Zhang X, Li L, Luo C. Gel integration for microfluidic applications. Lab Chip. 2016 May;16(10):1757-76.
24. Iliescu C, Taylor H, Avram M, Miao J, Franssila S. A practical guide for the fabrication of microfluidic devices using glass and silicon. Biomicrofluidics. 2012 Mar;6(1):16505-16.
25. Shin DS, Matharu Z, You J, Siltanen C, Vu T, Raghunathan VK, et al. Sensing conductive hydrogels for rapid detection of cytokines in blood. Adv Healthc Mater. 2016 Mar;5(6):659-64.
28. Han P, Bartels DM. Temperature dependence of oxygen diffusion in H2O and D2O. J Phys Chem. 1996 Mar;100(13):5597-602.
29. Unger MA, Chou HP, Thorsen T, Scherer A, Quake SR. Monolithic microfabricated valves and pumps by multilayer soft lithography. Science. 2000 Apr;288(5463):113-6.
30. Bhattacharya S, Datta A, Berg JM, Gangopadhyay S. Studies on surface wettability of poly(dimethyl) siloxane (PDMS) and glass under oxygen-plasma treatment and correlation with bond strength. J Microelectromech Syst. 2005 Jun;14(3):590-7.
31. Gonzalez-Suarez AM, Pena-Del Castillo JG, Hernandez-Cruz A, Garcia-Cordero JL. Dynamic generation of concentration- and temporal-dependent chemical signals in an integrated microfluidic device for single-cell analysis. Anal Chem. 2018 Jul;90(14):8331-6.
34. Lau D, Walsh JC, Peng W, Shah VB, Turville S, Jacques DA, et al. Fluorescence biosensor for real-time interaction dynamics of host proteins with HIV-1 capsid tubes. ACS Appl Mater Interfaces. 2019 Sep;11(38):34586-94.
35. Yeh YT, Gulino K, Zhang Y, Sabestien A, Chou TW, Zhou B, et al. A rapid and label-free platform for virus capture and identification from clinical samples. Proc Natl Acad Sci U S A. 2020 Jan;117(2):895-901.
36. Maerkl SJ. Integration column: microfluidic high-throughput screening. Integr Biol (Camb). 2009 Jan;1(1):19-29.
40. Kalidoss R, Umapathy S. An overview on the exponential growth of non- invasive diagnosis of diabetes mellitus from exhaled breath by nanostructured metal oxide chemi-resistive gas sensors and μ-preconcentrator. Biomed Microdevices. 2019 Dec;22(1):2.
41. Choi J, Cho SJ, Kim YT, Shin H. Development of a film-based immunochromatographic microfluidic device for malaria diagnosis. Biomed Microdevices. 2019 Aug;21(4):86.
44. Fattahi P, Haque A, Son KJ, Guild J, Revzin A. Microfluidic devices, accumulation of endogenous signals and stem cell fate selection. Differentiation. 2020 Mar-Apr;112:39-46.
46. Kim YH, Ko KP, Kang IG, Jung JH, Oh DK, Jang TY, et al. Low concentration PM(10) had no effect on nasal symptoms and flow in allergic rhinitis patients. Clin Exp Otorhinolaryngol. 2017 Jun;10(2):164-7.
47. Khan DA. Allergic rhinitis and asthma: epidemiology and common pathophysiology. Allergy Asthma Proc. 2014 Sep-Oct;35(5):357-61.
49. Huang Z, Luo W, Zou X, Liu X, Cai C, Wu Z, et al. Application of biochip microfluidic technology to detect serum allergen-specific immunoglobulin E (sIgE). J Vis Exp. 2019 Apr;(146):e59100.
50. Huang WY, Chou ST, Chen CH, Chou SY, Wu JH, Chen YC, et al. An automatic integrated microfluidic system for allergy microarray chips. Analyst. 2018 May;143(10):2285-92.
51. Zheng L, Fu Y, Jiang X, Man S, Ran W, Feng M, et al. Microfluidic system for high-throughput immunoglobulin-E analysis from clinical serum samples. Talanta. 2015 Oct;143:83-9.
52. Bernstein DI, Schwartz G, Bernstein JA. Allergic rhinitis: mechanisms and treatment. Immunol Allergy Clin North Am. 2016 May;36(2):261-78.
53. Aljadi Z, Kalm F, Nilsson C, Winqvist O, Russom A, Lundahl J, et al. A novel tool for clinical diagnosis of allergy operating a microfluidic immunoaffinity basophil activation test technique. Clin Immunol. 2019 Dec;209:108268.
56. Nopp A, Johansson SG, Ankerst J, Bylin G, Cardell LO, Gronneberg R, et al. Basophil allergen threshold sensitivity: a useful approach to anti-IgE treatment efficacy evaluation. Allergy. 2006 Mar;61(3):298-302.
58. Chen QL, Cheung KL, Kong SK, Zhou JQ, Kwan YW, Wong CK, et al. An integrated lab-on-a-disc for automated cell-based allergen screening bioassays. Talanta. 2012 Aug;97:48-54.
59. Aljadi Z, Kalm F, Ramachandraiah H, Nopp A, Lundahl J, Russom A. Microfluidic immunoaffinity basophil activation test for point-of-care allergy diagnosis. J Appl Lab Med. 2019 Sep;4(2):152-63.
60. Knol EF, Mul FP, Jansen H, Calafat J, Roos D. Monitoring human basophil activation via CD63 monoclonal antibody 435. J Allergy Clin Immunol. 1991 Sep;88(3 Pt 1):328-38.
61. Yan Y, Gordon WM, Wang DY. Nasal epithelial repair and remodeling in physical injury, infection, and inflammatory diseases. Curr Opin Otolaryngol Head Neck Surg. 2013 Jun;21(3):263-70.
62. Na K, Lee M, Shin HW, Chung S. In vitro nasal mucosa gland-like structure formation on a chip. Lab Chip. 2017 May;17(9):1578-84.
63. Yu F, Zhao X, Li C, Li Y, Yan Y, Shi L, et al. Airway stem cells: review of potential impact on understanding of upper airway diseases. Laryngoscope. 2012 Jul;122(7):1463-9.
64. Wang W, Yan Y, Li CW, Xia HM, Chao SS, Wang de Y, et al. Live human nasal epithelial cells (hNECs) on chip for in vitro testing of gaseous formaldehyde toxicity via airway delivery. Lab Chip. 2014 Feb;14(4):677-80.
65. Ayoob AM, Borenstein JT. The role of intracochlear drug delivery devices in the management of inner ear disease. Expert Opin Drug Deliv. 2015 Mar;12(3):465-79.
67. Tandon V, Kang WS, Spencer AJ, Kim ES, Pararas EE, McKenna MJ, et al. Microfabricated infuse-withdraw micropump component for an integrated inner-ear drug-delivery platform. Biomed Microdevices. 2015 Apr;17(2):37.
69. Brown JN, Miller JM, Altschuler RA, Nuttall AL. Osmotic pump implant for chronic infusion of drugs into the inner ear. Hear Res. 1993 Nov;70(2):167-72.
73. Jahn K. The Aging vestibular system: dizziness and imbalance in the elderly. Adv Otorhinolaryngol. 2019;82:143-9.
79. Zhou Q, Rahimian A, Son K, Shin DS, Patel T, Revzin A. Development of an aptasensor for electrochemical detection of exosomes. Methods. 2016 Mar;97:88-93.
81. Poulet G, Massias J, Taly V. Liquid biopsy: general concepts. Acta Cytol. 2019;63(6):449-55.
82. Paoletti C, Hayes DF. Circulating tumor cells. Adv Exp Med Biol. 2016;882:235-58.
83. Garcia SA, Weitz J, Scholch S. Circulating tumor cells. Methods Mol Biol. 2018;1692:213-9.
84. Cho H, Kim J, Song H, Sohn KY, Jeon M, Han KH. Microfluidic technologies for circulating tumor cell isolation. Analyst. 2018 Jun;143(13):2936-70.
87. Sontheimer-Phelps A, Hassell BA, Ingber DE. Modelling cancer in microfluidic human organs-on-chips. Nat Rev Cancer. 2019 Feb;19(2):65-81.
88. Zhang H, Zhu Y, Shen Y. Microfluidics for cancer nanomedicine: from fabrication to evaluation. Small. 2018 Jul;14(28):e1800360.
89. Cheah R, Srivastava R, Stafford ND, Beavis AW, Green V, Greenman J. Measuring the response of human head and neck squamous cell carcinoma to irradiation in a microfluidic model allowing customized therapy. Int J Oncol. 2017 Oct;51(4):1227-38.
90. Al-Samadi A, Poor B, Tuomainen K, Liu V, Hyytiainen A, Suleymanova I, et al. In vitro humanized 3D microfluidic chip for testing personalized immunotherapeutics for head and neck cancer patients. Exp Cell Res. 2019 Oct;383(2):111508.