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Journal articles on the topic 'Biomicrofluidica'

Author: Grafiati
Published: 11 September 2021
Last updated: 30 July 2025

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1

Dhall, Atul, Tim Masiello, Suhasini Gattu, et al. "Characterization and Neutral Atom Beam Surface Modification of a Clear Castable Polyurethane for Biomicrofluidic Applications." Surfaces 2, no. 1 (2019): 100–116. http://dx.doi.org/10.3390/surfaces2010009.

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Polyurethanes (PU) are a broad class of polymers that offer good solvent compatibility and a wide range of properties that can be used to generate microfluidic layers. Here, we report the first characterization of a commercially available Shore 80D polyurethane (Ultraclear™ 480N) for biomicrofluidic applications. Studies included comparing optical clarity with Polydimethylsiloxane (PDMS) and using high-fidelity replica molding to produce solid PU structures from the millimeter to nanometer scales. Additionally, we report the first use of NanoAccel™ treatment in Accelerated Neutral Atom Beam (A
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2

Liu, Liyu, Wenbin Cao, Jinbo Wu, Weijia Wen, Donald Choy Chang, and Ping Sheng. "Publisher’s Note: “Design and integration of an all-in-one biomicrofluidic chip” [Biomicrofluidics 2, 034103 (2008)]." Biomicrofluidics 5, no. 1 (2011): 019901. http://dx.doi.org/10.1063/1.3533672.

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3

He, Pei Yuan, and Li Guo Zhang. "Analytical Modeling and Numerical Simulations on the Scaling of Biomicrofluidic Droplets." Advanced Materials Research 968 (June 2014): 235–39. http://dx.doi.org/10.4028/www.scientific.net/amr.968.235.

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Biomicrofluidic silhouettes brought about scientific challenges merited to be investigated through explicit florescence observation, implicit physical-chemical analysis and intermediate conductive level manipulation. Droplet generation, as the typical biomicrofluidic phenomenon, is a complicated dynamic process. In this work, we established both linear and non-linear models to describe the biomicrofluidic droplet variation through applied mathematical techniques, in order to find the corresponding summarizations. Model analysis showed that non-linear models presented ameliorated descriptive ca
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4

Chang, Hsueh-Chia, and Leslie Yeo. "Editorial: Moving on in biomicrofluidics." Biomicrofluidics 7, no. 1 (2013): 010401. http://dx.doi.org/10.1063/1.4775344.

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5

Das, Tamal, and Suman Chakraborty. "Biomicrofluidics: Recent trends and future challenges." Sadhana 34, no. 4 (2009): 573–90. http://dx.doi.org/10.1007/s12046-009-0035-8.

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6

Kuo, Alexandra P., Nirveek Bhattacharjee, Yuan‐Sheng Lee, Kurt Castro, Yong Tae Kim, and Albert Folch. "High‐Precision Stereolithography of Biomicrofluidic Devices." Advanced Materials Technologies 4, no. 6 (2019): 1800395. http://dx.doi.org/10.1002/admt.201800395.

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7

Chang, Hsueh-Chia. "Editorial: Biomicrofluidics—Growing with the micro/nanofluidics community." Biomicrofluidics 3, no. 1 (2009): 010901. http://dx.doi.org/10.1063/1.3068295.

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8

Edwards, John M., Mark N. Hamblin, Hernan V. Fuentes, et al. "Thin film electro-osmotic pumps for biomicrofluidic applications." Biomicrofluidics 1, no. 1 (2007): 014101. http://dx.doi.org/10.1063/1.2372215.

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9

Ortiz, Raphael, Jian Lin Chen, David C. Stuckey, and Terry W. J. Steele. "Rapid serial diluting biomicrofluidic provides EC50 in minutes." Micro and Nano Engineering 2 (March 2019): 92–103. http://dx.doi.org/10.1016/j.mne.2019.02.002.

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10

Fantino, Erika, Alessandro Chiadò, Marzia Quaglio, et al. "Photofabrication of polymeric biomicrofluidics: New insights into material selection." Materials Science and Engineering: C 106 (January 2020): 110166. http://dx.doi.org/10.1016/j.msec.2019.110166.

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11

He, J. H., J. Reboud, H. Ji, L. Zhang, Y. Long, and C. Lee. "Biomicrofluidic lab-on-chip device for cancer cell detection." Applied Physics Letters 93, no. 22 (2008): 223905. http://dx.doi.org/10.1063/1.3040313.

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12

Sabounchi, Poorya, Cristian Ionescu-Zanetti, Roger Chen, Manjiree Karandikar, Jeonggi Seo, and Luke P. Lee. "Soft-state biomicrofluidic pulse generator for single cell analysis." Applied Physics Letters 88, no. 18 (2006): 183901. http://dx.doi.org/10.1063/1.2195106.

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13

Chowdury, Mosfera A., Khalil L. Heileman, Thomas A. Moore, and Edmond W. K. Young. "Biomicrofluidic Systems for Hematologic Cancer Research and Clinical Applications." SLAS TECHNOLOGY: Translating Life Sciences Innovation 24, no. 5 (2019): 457–76. http://dx.doi.org/10.1177/2472630319846878.

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A persistent challenge in developing personalized treatments for hematologic cancers is the lack of patient specific, physiologically relevant disease models to test investigational drugs in clinical trials and to select therapies in a clinical setting. Biomicrofluidic systems and organ-on-a-chip technologies have the potential to change how researchers approach the fundamental study of hematologic cancers and select clinical treatment for individual patient. Here, we review microfluidics cell-based technology with application toward studying hematologic tumor microenvironments (TMEs) for the
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14

Kabandana, Giraso Keza Monia, Adam Michael Ratajczak, and Chengpeng Chen. "Making quantitative biomicrofluidics from microbore tubing and 3D-printed adapters." Biomicrofluidics 15, no. 3 (2021): 034107. http://dx.doi.org/10.1063/5.0052314.

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15

Sapuppo, Francesca, Andreu Llobera, Florinda Schembri, Marcos Intaglietta, Victor J. Cadarso, and Maide Bucolo. "A polymeric micro-optical interface for flow monitoring in biomicrofluidics." Biomicrofluidics 4, no. 2 (2010): 024108. http://dx.doi.org/10.1063/1.3435333.

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16

Lee, H., Y. H. Roh, H. U. Kim, and K. W. Bong. "Publisher's Note: ‘Low temperature flow lithography’ [Biomicrofluidics 12, 054105 (2018)]." Biomicrofluidics 12, no. 6 (2018): 069901. http://dx.doi.org/10.1063/1.5084274.

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17

Chang, Hsueh-Chia. "Editorial: Farewell from the Founding and Chief Editor of Biomicrofluidics." Biomicrofluidics 12, no. 6 (2018): 060401. http://dx.doi.org/10.1063/1.5084549.

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18

Ortiz, Raphael, David C. Stuckey, and Terry W. J. Steele. "Rapid EC50 determination of hydrophobic toxicants in continuous droplet biomicrofluidics." Micro and Nano Engineering 3 (May 2019): 82–91. http://dx.doi.org/10.1016/j.mne.2019.05.001.

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19

Liu, Liyu, Wenbin Cao, Jinbo Wu, Weijia Wen, Donald Choy Chang, and Ping Sheng. "Design and integration of an all-in-one biomicrofluidic chip." Biomicrofluidics 2, no. 3 (2008): 034103. http://dx.doi.org/10.1063/1.2966453.

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20

Zhang, Li Guo, Le Xun Xue, Pei Yuan He, Yuan Ming Qi, and Yu Min Lu. "Intelligent Numerical Manipulation of Micrometer-Scale Emulsions Using Polymer Confinement." Advanced Materials Research 813 (September 2013): 431–34. http://dx.doi.org/10.4028/www.scientific.net/amr.813.431.

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The manipulation of emulsions at micrometer-scale is a challenging topic for industrial application, especially for monodisperse microemulsions production. The development of material science and afterwards the creation of polymer confinement proposed efficient devices for micrometer scale emulsions fabrication. In this work, the flow regime of emulsion generation was studied to depict numerical manipulation of micrometer-scale emulsions through biomicrofluidic technology. At first, correlation analysis between experiment conditions and results were conducted, then different linear modeling an
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21

Wang, Zongjie. "Detection and Automation Technologies for the Mass Production of Droplet Biomicrofluidics." IEEE Reviews in Biomedical Engineering 11 (2018): 260–74. http://dx.doi.org/10.1109/rbme.2018.2826984.

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22

Plouffe, Brian D., Laura H. Lewis, and Shashi K. Murthy. "Erratum: “Computational design optimization for microfluidic magnetophoresis” [Biomicrofluidics 5, 013413 (2011)]." Biomicrofluidics 5, no. 4 (2011): 049901. http://dx.doi.org/10.1063/1.3668225.

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23

Langer, Krzysztof, Nicolas Bremond, Laurent Boitard, Jean Baudry, and Jérôme Bibette. "Publisher's Note: “Micropipette-powered droplet based microfluidics” [Biomicrofluidics 12, 044106 (2018)]." Biomicrofluidics 12, no. 4 (2018): 049902. http://dx.doi.org/10.1063/1.5049817.

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24

Bazban-Shotorbani, Salime, Felicity Gavins, Krishna Kant, Martin Dufva, and Nazila Kamaly. "A Biomicrofluidic Screening Platform for Dysfunctional Endothelium‐Targeted Nanoparticles and Therapeutics." Advanced NanoBiomed Research 2, no. 1 (2021): 2100092. http://dx.doi.org/10.1002/anbr.202100092.

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25

Bazban-Shotorbani, Salime, Felicity Gavins, Krishna Kant, Martin Dufva, and Nazila Kamaly. "A Biomicrofluidic Screening Platform for Dysfunctional Endothelium‐Targeted Nanoparticles and Therapeutics." Advanced NanoBiomed Research 2, no. 1 (2022): 2270011. http://dx.doi.org/10.1002/anbr.202270011.

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26

Jenkins, J., B. Prabhakarpandian, K. Lenghaus, J. Hickman, and S. Sundaram. "Fluidics-resolved estimation of protein adsorption kinetics in a biomicrofluidic system." Analytical Biochemistry 331, no. 2 (2004): 207–15. http://dx.doi.org/10.1016/j.ab.2004.03.072.

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27

Lee, Dong Jun, John Mai, and Tony Jun Huang. "Erratum: “Microfluidic approaches for cell-based molecular diagnosis” [Biomicrofluidics, 12, 051501 (2018)]." Biomicrofluidics 14, no. 4 (2020): 049901. http://dx.doi.org/10.1063/5.0023355.

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28

Lee, Chun-Wei, and Fan-Gang Tseng. "Surface enhanced Raman scattering (SERS) based biomicrofluidics systems for trace protein analysis." Biomicrofluidics 12, no. 1 (2018): 011502. http://dx.doi.org/10.1063/1.5012909.

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29

Aboelkassem, Yasser. "Chaotic mixing by oscillating a Stokeslet in a circular Hele-Shaw microfluidic device." Mathematics of Quantum Technologies 5, no. 1 (2016): 1–8. http://dx.doi.org/10.1515/nsmmt-2016-0001.

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AbstractChaotic mixing by oscillating a Stokeslet in a circular Hele-Shaw microffluidic device is presented in this article. Mathematical modeling for the induced flow motions by moving a Stokeslet along the x-axis is derived using Fourier expansion method. The solution is formulated in terms of the velocity stream function. The model is then used to explore different stirring dynamics as function of the Stokeslet parameters. For instance, the effects of using various oscillation amplitudes and force strengths are investigated. Mixing patterns using Poincaré maps are obtained numerically and h
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30

Li, F. Q., Y. J. Jian, Z. Y. Xie, and L. Wang. "Electromagnetohydrodynamic Flow of Powell-Eyring Fluids in a Narrow Confinement." Journal of Mechanics 33, no. 2 (2016): 225–33. http://dx.doi.org/10.1017/jmech.2016.75.

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AbstractIn this work, we investigate electromagnetohydrodynamic (EMHD) flow of Powell-Eyring fluid through a slit confinement. The approximate analytical solution and numerical result of EMHD velocity are obtained by using homotopy perturbation method and Chebyshev spectral method, respectively. The analytical solutions are found to be in good agreement with numerical results under the same conditions. The influences of Hartmann number Ha, electrical field strength parameter S, the Powell-Eyring fluid parameters γ and β on velocity are discussed in detail. It is found that the volume flow rate
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31

Mohan, Michael D., and Edmond W. K. Young. "TANDEM: biomicrofluidic systems with transverse and normal diffusional environments for multidirectional signaling." Lab on a Chip 21, no. 21 (2021): 4081–94. http://dx.doi.org/10.1039/d1lc00279a.

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32

Gonçalves, I. M., D. Pinho, A. Zille, et al. "A Simple Method To Modify The PDMS Surface Wettability For Biomicrofluidic Applications." Proceedings of the International Symposium on the Application of Laser and Imaging Techniques to Fluid Mechanics 20 (July 11, 2022): 1–8. http://dx.doi.org/10.55037/lxlaser.20th.207.

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Polydimethylsiloxane (PDMS) is one of the most used materials for the manufacture of microfluidic devices. Recent studies have combined microfluidic devices and cell cultures to originate a new group of devices, the organs-on-achip (OoC). These devices replicate the microphysiological features that can be found in the human body so that healthy and pathological conditions can be easily studied. PDMS is also one of the materials of choice for the manufacture of the OoC, due to its mechanical and chemical properties, and due to the fact that is a biocompatible and inert material. However, the hy
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33

Rismani Yazdi, Saeed, Reza Nosrati, Corey A. Stevens, David Vogel, and Carlos Escobedo. "Publisher's Note: “Migration of magnetotactic bacteria in porous media” [Biomicrofluidics 12, 011101 (2018)]." Biomicrofluidics 12, no. 4 (2018): 049901. http://dx.doi.org/10.1063/1.5045672.

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34

Liebendorfer, Adam. "Advances in design position push-button mechanisms for future use in biomicrofluidic applications." Scilight 2021, no. 28 (2021): 281108. http://dx.doi.org/10.1063/10.0005665.

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35

Liu, Yifan, та Levent Yobas. "Cylindrical glass nanocapillaries patterned via coarse lithography (>1 μm) for biomicrofluidic applications". Biomicrofluidics 6, № 4 (2012): 046502. http://dx.doi.org/10.1063/1.4771691.

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36

Pawell, Ryan S., David W. Inglis, Tracie J. Barber, and Robert A. Taylor. "Erratum: “Manufacturing and wetting low-cost microfluidic cell separation devices” [Biomicrofluidics 7, 056501 (2013)]." Biomicrofluidics 7, no. 5 (2013): 059901. http://dx.doi.org/10.1063/1.4827599.

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37

Prakash, J., Ashish Sharma, and Dharmendra Tripathi. "Thermal radiation effects on electroosmosis modulated peristaltic transport of ionic nanoliquids in biomicrofluidics channel." Journal of Molecular Liquids 249 (January 2018): 843–55. http://dx.doi.org/10.1016/j.molliq.2017.11.064.

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38

Kong, Lingbao, Panyu Zhou, and Zhenzhen Xu. "Theoretical and Experimental Studies of the Functional Structure Effect on Directional Transport in Biomicrofluidics." Langmuir 36, no. 32 (2020): 9523–33. http://dx.doi.org/10.1021/acs.langmuir.0c01503.

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39

Feng, Shilun, Alison M. Skelley, Ayad G. Anwer, Guozhen Liu, and David W. Inglis. "Publisher's Note: “Maximizing particle concentration in deterministic lateral displacement arrays” [Biomicrofluidics 11, 024121 (2017)]." Biomicrofluidics 11, no. 3 (2017): 039901. http://dx.doi.org/10.1063/1.4983666.

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40

Muñoz-Sánchez, B. N., S. F. Silva, D. Pinho, E. J. Vega, and R. Lima. "Generation of micro-sized PDMS particles by a flow focusing technique for biomicrofluidics applications." Biomicrofluidics 10, no. 1 (2016): 014122. http://dx.doi.org/10.1063/1.4943007.

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41

Sadeghi, Arman, Younes Amini, Mohammad Hassan Saidi, and Hadi Yavari. "Shear-rate-dependent rheology effects on mass transport and surface reactions in biomicrofluidic devices." AIChE Journal 61, no. 6 (2015): 1912–24. http://dx.doi.org/10.1002/aic.14781.

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42

Musgrove, Hannah B., Amirus Saleheen, Jonathan M. Zatorski, Abhinav Arneja, Chance John Luckey, and Rebecca R. Pompano. "A Scalable, Modular Degasser for Passive In-Line Removal of Bubbles from Biomicrofluidic Devices." Micromachines 14, no. 2 (2023): 435. http://dx.doi.org/10.3390/mi14020435.

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Bubbles are a common cause of microfluidic malfunction, as they can perturb the fluid flow within the micro-sized features of a device. Since gas bubbles form easily within warm cell culture reagents, degassing is often necessary for biomicrofluidic systems. However, fabrication of a microscale degasser that can be used modularly with pre-existing chips may be cumbersome or challenging, especially for labs not equipped for traditional microfabrication, and current commercial options can be expensive. Here, we address the need for an affordable, accessible bubble trap that can be used in-line f
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43

Rajashekhar, Choudhari, Fateh Mebarek-Oudina, Ioannis E. Sarris, et al. "Impact of Electroosmosis and Wall Properties in Modelling Peristaltic Mechanism of a Jeffrey Liquid through a Microchannel with Variable Fluid Properties." Inventions 6, no. 4 (2021): 73. http://dx.doi.org/10.3390/inventions6040073.

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The current work emphasizes the modelling of the electroosmosis-modulated peristaltic flow of Jeffery liquid. Such flows emerge in understanding the movement of biological fluids in a microchannel, such as in targeted drug delivery and blood flow through micro arteries. The non-Newtonian fluid flows inside a non-uniform cross-section and an inclined microchannel. The effects of wall properties and variable fluid properties are considered. The long wavelength and small Re number approximations are assumed to simplify the governing equations. Debye-Hückel linearization is also utilized. The nonl
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44

Miles, Michael, Biddut Bhattacharjee, Nakul Sridhar, et al. "Flattening of Diluted Species Profile via Passive Geometry in a Microfluidic Device." Micromachines 10, no. 12 (2019): 839. http://dx.doi.org/10.3390/mi10120839.

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In recent years, microfluidic devices have become an important tool for use in lab-on-a-chip processes, including drug screening and delivery, bio-chemical reactions, sample preparation and analysis, chemotaxis, and separations. In many such processes, a flat cross-sectional concentration profile with uniform flow velocity across the channel is desired to achieve controlled and precise solute transport. This is often accommodated by the use of electroosmotic flow, however, it is not an ideal for many applications, particularly biomicrofluidics. Meanwhile, pressure-driven systems generally exhi
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45

Kotnurkar, Asha S., Joonabi Beleri, Irfan Anjum Badruddin, Khaleed H.M.T., Sarfaraz Kamangar, and Nandalur Ameer Ahammad. "Effect of Thermal Radiation and Double-Diffusion Convective Peristaltic Flow of a Magneto-Jeffrey Nanofluid through a Flexible Channel." Mathematics 10, no. 10 (2022): 1701. http://dx.doi.org/10.3390/math10101701.

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The noteworthiness of double-diffusive convection with magneto-Jeffrey nanofluid on a peristaltic motion under the effect of MHD and porous medium through a flexible channel with the permeable wall has been theoretically examined. A non-linearized Rosseland approximation is utilized to show the thermal radiation effect. The governing equations are converted to standard non-linear partial differential equations by using suitable non-dimensional parameters. Solutions of emerging equations are obtained by using the multi-step differential transformation method (Ms-DTM). The differential transform
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46

Agastin, Sivaprakash, Ut-Binh T. Giang, Yue Geng, Lisa A. DeLouise, and Michael R. King. "Publisher's Note: “Continuously perfused microbubble array for 3D tumor spheroid model” [Biomicrofluidics 5, 024110 (2011)]." Biomicrofluidics 5, no. 3 (2011): 039901. http://dx.doi.org/10.1063/1.3634012.

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47

Mehta, Viraj, Sukanya Vilikkathala Sudhakaran, and Subha Narayan Rath. "Facile Route for 3D Printing of Transparent PETg-Based Hybrid Biomicrofluidic Devices Promoting Cell Adhesion." ACS Biomaterials Science & Engineering 7, no. 8 (2021): 3947–63. http://dx.doi.org/10.1021/acsbiomaterials.1c00633.

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48

Pethig, Ronald. "Publisher’s Note: “Review Article—Dielectrophoresis: Status of the theory, technology, and applications” [Biomicrofluidics 4, 022811 (2010)]." Biomicrofluidics 4, no. 3 (2010): 039901. http://dx.doi.org/10.1063/1.3474458.

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49

Lentz, Cody J., Samuel Hidalgo-Caballero, and Blanca H. Lapizco-Encinas. "Erratum: “Low frequency cyclical potentials for fine tuning insulator-based dielectrophoretic separations” [Biomicrofluidics 13, 044114 (2019)]." Biomicrofluidics 13, no. 6 (2019): 069901. http://dx.doi.org/10.1063/1.5134802.

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50

Bonabi, Tähkä, Ollikainen, Jokinen, and Sikanen. "Metallization of Organically Modified Ceramics for Microfluidic Electrochemical Assays." Micromachines 10, no. 9 (2019): 605. http://dx.doi.org/10.3390/mi10090605.

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Organically modified ceramic polymers (ORMOCERs) have attracted substantial interest in biomicrofluidic applications owing to their inherent biocompatibility and high optical transparency even in the near-ultraviolet (UV) range. However, the processes for metallization of ORMOCERs as well as for sealing of metallized surfaces have not been fully developed. In this study, we developed metallization processes for a commercial ORMOCER formulation, Ormocomp, covering several commonly used metals, including aluminum, silver, gold, and platinum. The obtained metallizations were systematically charac
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