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Advances in microfluidics for environmental analysis.

The Analyst

Jokerst JC, Emory JM, Henry CS.
PMID: 22005445
Analyst. 2012 Jan 07;137(1):24-34. doi: 10.1039/c1an15368d. Epub 2011 Oct 18.

During the past few years, a growing number of groups have recognized the utility of microfluidic devices for environmental analysis. Microfluidic devices offer a number of advantages and in many respects are ideally suited to environmental analyses. Challenges faced...

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Jokerst JC, Emory JM, Henry CS. Advances in microfluidics for environmental analysis. Analyst. 2011;137(1):24-34doi: 10.1039/c1an15368d.
Jokerst, J. C., Emory, J. M., & Henry, C. S. (2012). Advances in microfluidics for environmental analysis. The Analyst, 137(1), 24-34. https://doi.org/10.1039/c1an15368d
Jokerst, Jana C, et al. "Advances in microfluidics for environmental analysis." The Analyst vol. 137,1 (2012): 24-34. doi: https://doi.org/10.1039/c1an15368d
Jokerst JC, Emory JM, Henry CS. Advances in microfluidics for environmental analysis. Analyst. 2012 Jan 07;137(1):24-34. doi: 10.1039/c1an15368d. Epub 2011 Oct 18. PMID: 22005445.
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Droplet microfluidics for synthetic biology.

Lab on a chip

Gach PC, Iwai K, Kim PW, Hillson NJ, Singh AK.
PMID: 28820204
Lab Chip. 2017 Oct 11;17(20):3388-3400. doi: 10.1039/c7lc00576h.

Synthetic biology is an interdisciplinary field that aims to engineer biological systems for useful purposes. Organism engineering often requires the optimization of individual genes and/or entire biological pathways (consisting of multiple genes). Advances in DNA sequencing and synthesis have...

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Gach PC, Iwai K, Kim PW, et al. Droplet microfluidics for synthetic biology. Lab Chip. 2017;17(20):3388-3400doi: 10.1039/c7lc00576h.
Gach, P. C., Iwai, K., Kim, P. W., Hillson, N. J., & Singh, A. K. (2017). Droplet microfluidics for synthetic biology. Lab on a chip, 17(20), 3388-3400. https://doi.org/10.1039/c7lc00576h
Gach, Philip C, et al. "Droplet microfluidics for synthetic biology." Lab on a chip vol. 17,20 (2017): 3388-3400. doi: https://doi.org/10.1039/c7lc00576h
Gach PC, Iwai K, Kim PW, Hillson NJ, Singh AK. Droplet microfluidics for synthetic biology. Lab Chip. 2017 Oct 11;17(20):3388-3400. doi: 10.1039/c7lc00576h. PMID: 28820204.
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Enhanced model-based design of a high-throughput three dimensional micromixer driven by alternating-current electrothermal flow.

Electrophoresis

Wu Y, Ren Y, Jiang H.
PMID: 27387819
Electrophoresis. 2017 Jan;38(2):258-269. doi: 10.1002/elps.201600106. Epub 2016 Aug 04.

We propose a 3D microfluidic mixer based on the alternating current electrothermal (ACET) flow. The ACET vortex is produced by 3D electrodes embedded in the sidewall of the microchannel and is used to stir the fluidic sample throughout the...

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Wu Y, Ren Y, Jiang H. Enhanced model-based design of a high-throughput three dimensional micromixer driven by alternating-current electrothermal flow. Electrophoresis. 2016;38(2):258-269doi: 10.1002/elps.201600106.
Wu, Y., Ren, Y., & Jiang, H. (2017). Enhanced model-based design of a high-throughput three dimensional micromixer driven by alternating-current electrothermal flow. Electrophoresis, 38(2), 258-269. https://doi.org/10.1002/elps.201600106
Wu, Yupan, et al. "Enhanced model-based design of a high-throughput three dimensional micromixer driven by alternating-current electrothermal flow." Electrophoresis vol. 38,2 (2017): 258-269. doi: https://doi.org/10.1002/elps.201600106
Wu Y, Ren Y, Jiang H. Enhanced model-based design of a high-throughput three dimensional micromixer driven by alternating-current electrothermal flow. Electrophoresis. 2017 Jan;38(2):258-269. doi: 10.1002/elps.201600106. Epub 2016 Aug 04. PMID: 27387819.
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Semi-autonomous liquid handling via on-chip pneumatic digital logic.

Lab on a chip

Nguyen TV, Duncan PN, Ahrar S, Hui EE.
PMID: 22968472
Lab Chip. 2012 Oct 21;12(20):3991-4. doi: 10.1039/c2lc40466d.

This report presents a liquid-handling chip capable of executing metering, mixing, incubation, and wash procedures largely under the control of on-board pneumatic circuitry. The only required inputs are four static selection lines to choose between the four machine states,...

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Nguyen TV, Duncan PN, Ahrar S, et al. Semi-autonomous liquid handling via on-chip pneumatic digital logic. Lab Chip. 2012;12(20):3991-4doi: 10.1039/c2lc40466d.
Nguyen, T. V., Duncan, P. N., Ahrar, S., & Hui, E. E. (2012). Semi-autonomous liquid handling via on-chip pneumatic digital logic. Lab on a chip, 12(20), 3991-4. https://doi.org/10.1039/c2lc40466d
Nguyen, Transon V, et al. "Semi-autonomous liquid handling via on-chip pneumatic digital logic." Lab on a chip vol. 12,20 (2012): 3991-4. doi: https://doi.org/10.1039/c2lc40466d
Nguyen TV, Duncan PN, Ahrar S, Hui EE. Semi-autonomous liquid handling via on-chip pneumatic digital logic. Lab Chip. 2012 Oct 21;12(20):3991-4. doi: 10.1039/c2lc40466d. PMID: 22968472.
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A valve-based microfluidic device for on-chip single cell treatments.

Electrophoresis

Sun Y, Cai B, Wei X, Wang Z, Rao L, Meng QF, Liao Q, Liu W, Guo S, Zhao X.
PMID: 30155963
Electrophoresis. 2019 Mar;40(6):961-968. doi: 10.1002/elps.201800213. Epub 2018 Sep 09.

Assays toward single-cell analysis have attracted the attention in biological and biomedical researches to reveal cellular mechanisms as well as heterogeneity. Yet nowadays microfluidic devices for single-cell analysis have several drawbacks: some would cause cell damage due to the...

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Sun Y, Cai B, Wei X, et al. A valve-based microfluidic device for on-chip single cell treatments. Electrophoresis. 2018;40(6):961-968doi: 10.1002/elps.201800213.
Sun, Y., Cai, B., Wei, X., Wang, Z., Rao, L., Meng, Q. F., Liao, Q., Liu, W., Guo, S., & Zhao, X. (2019). A valve-based microfluidic device for on-chip single cell treatments. Electrophoresis, 40(6), 961-968. https://doi.org/10.1002/elps.201800213
Sun, Yue, et al. "A valve-based microfluidic device for on-chip single cell treatments." Electrophoresis vol. 40,6 (2019): 961-968. doi: https://doi.org/10.1002/elps.201800213
Sun Y, Cai B, Wei X, Wang Z, Rao L, Meng QF, Liao Q, Liu W, Guo S, Zhao X. A valve-based microfluidic device for on-chip single cell treatments. Electrophoresis. 2019 Mar;40(6):961-968. doi: 10.1002/elps.201800213. Epub 2018 Sep 09. PMID: 30155963.
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A Microfluidic Sensor for Continuous, in Situ Surface Charge Measurement of Single Cells.

ACS sensors

Ni L, Shaik R, Xu R, Zhang G, Zhe J.
PMID: 31939290
ACS Sens. 2020 Feb 28;5(2):527-534. doi: 10.1021/acssensors.9b02411. Epub 2020 Jan 24.

Cell surface charge has been recognized as an important cellular property. We developed a microfluidic sensor based on resistive pulse sensing to assess surface charge and sizes of single cells suspended in a continuous flow. The device consists of...

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Ni L, Shaik R, Xu R, et al. A Microfluidic Sensor for Continuous, in Situ Surface Charge Measurement of Single Cells. ACS Sens. 2020;5(2):527-534doi: 10.1021/acssensors.9b02411.
Ni, L., Shaik, R., Xu, R., Zhang, G., & Zhe, J. (2020). A Microfluidic Sensor for Continuous, in Situ Surface Charge Measurement of Single Cells. ACS sensors, 5(2), 527-534. https://doi.org/10.1021/acssensors.9b02411
Ni, Liwei, et al. "A Microfluidic Sensor for Continuous, in Situ Surface Charge Measurement of Single Cells." ACS sensors vol. 5,2 (2020): 527-534. doi: https://doi.org/10.1021/acssensors.9b02411
Ni L, Shaik R, Xu R, Zhang G, Zhe J. A Microfluidic Sensor for Continuous, in Situ Surface Charge Measurement of Single Cells. ACS Sens. 2020 Feb 28;5(2):527-534. doi: 10.1021/acssensors.9b02411. Epub 2020 Jan 24. PMID: 31939290.
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[Research advances in clinical biochemical analysis systems based on microfluidic driving and control technique].

Se pu = Chinese journal of chromatography

Yuan Y, Fan C, Pan J, Fang Q.
PMID: 34213167
Se Pu. 2020 Feb 08;38(2):183-194. doi: 10.3724/SP.J.1123.2019.05006.

Microfluidic techniques have the features of high throughput, low consumption, as well as ease of miniaturization, integration, and automation, thus emerging as a feasible solution to cost-effective clinical biochemical analysis. Various clinical biochemical analysis systems based on the microfluidic...

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Yuan Y, Fan C, Pan J, et al. [Research advances in clinical biochemical analysis systems based on microfluidic driving and control technique]. Se Pu. 2020;38(2):183-194doi: 10.3724/SP.J.1123.2019.05006.
Yuan, Y., Fan, C., Pan, J., & Fang, Q. (2020). [Research advances in clinical biochemical analysis systems based on microfluidic driving and control technique]. Se pu = Chinese journal of chromatography, 38(2), 183-194. https://doi.org/10.3724/SP.J.1123.2019.05006
Yuan, Yingxin, et al. "[Research advances in clinical biochemical analysis systems based on microfluidic driving and control technique]." Se pu = Chinese journal of chromatography vol. 38,2 (2020): 183-194. doi: https://doi.org/10.3724/SP.J.1123.2019.05006
Yuan Y, Fan C, Pan J, Fang Q. [Research advances in clinical biochemical analysis systems based on microfluidic driving and control technique]. Se Pu. 2020 Feb 08;38(2):183-194. doi: 10.3724/SP.J.1123.2019.05006. Chinese. PMID: 34213167.
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On chip optofluidic low-pressure monitoring device.

Journal of biophotonics

Chandra Roy A, Bangalore Subramanya S, Manohar Rudresh S, Venkataraman V.
PMID: 33169514
J Biophotonics. 2021 Mar;14(3):e202000381. doi: 10.1002/jbio.202000381. Epub 2020 Nov 24.

We present an on chip optofluidic surface deformable liquid Dove prism (LDP) based low-fluid flow pressure monitoring device. The unique design of the device in combination with liquid and soft solid enabled by the total internal reflection of light...

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Chandra Roy A, Bangalore Subramanya S, Manohar Rudresh S, et al. On chip optofluidic low-pressure monitoring device. J Biophotonics. 2020;14(3):e202000381doi: 10.1002/jbio.202000381.
Chandra Roy, A., Bangalore Subramanya, S., Manohar Rudresh, S., & Venkataraman, V. (2021). On chip optofluidic low-pressure monitoring device. Journal of biophotonics, 14(3), e202000381. https://doi.org/10.1002/jbio.202000381
Chandra Roy, Abhijit, et al. "On chip optofluidic low-pressure monitoring device." Journal of biophotonics vol. 14,3 (2021): e202000381. doi: https://doi.org/10.1002/jbio.202000381
Chandra Roy A, Bangalore Subramanya S, Manohar Rudresh S, Venkataraman V. On chip optofluidic low-pressure monitoring device. J Biophotonics. 2021 Mar;14(3):e202000381. doi: 10.1002/jbio.202000381. Epub 2020 Nov 24. PMID: 33169514.
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Microfluidics in Nanomedicine.

Pharmaceutical nanotechnology

Boyd BJ, McDowell A.
PMID: 31840609
Pharm Nanotechnol. 2019;7(6):422. doi: 10.2174/221173850706191210152137.

No abstract available.

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Boyd BJ, McDowell A. Microfluidics in Nanomedicine. Pharm Nanotechnol. 2019;7(6):422doi: 10.2174/221173850706191210152137.
Boyd, B. J., & McDowell, A. (2019). Microfluidics in Nanomedicine. Pharmaceutical nanotechnology, 7(6), 422. https://doi.org/10.2174/221173850706191210152137
Boyd, Ben J, and McDowell, Arlene. "Microfluidics in Nanomedicine." Pharmaceutical nanotechnology vol. 7,6 (2019): 422. doi: https://doi.org/10.2174/221173850706191210152137
Boyd BJ, McDowell A. Microfluidics in Nanomedicine. Pharm Nanotechnol. 2019;7(6):422. doi: 10.2174/221173850706191210152137. PMID: 31840609.
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Frequency dependent multiphase flows on centrifugal microfluidics.

Lab on a chip

Pishbin E, Kazemzadeh A, Chimerad M, Asiaei S, Navidbakhsh M, Russom A.
PMID: 31898702
Lab Chip. 2020 Feb 07;20(3):514-524. doi: 10.1039/c9lc00924h. Epub 2020 Jan 03.

The simultaneous flow of gas and liquids in large scale conduits is an established approach to enhance the performance of different working systems under critical conditions. On the microscale, the use of gas-liquid flows is challenging due to the...

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Pishbin E, Kazemzadeh A, Chimerad M, et al. Frequency dependent multiphase flows on centrifugal microfluidics. Lab Chip. 2020;20(3):514-524doi: 10.1039/c9lc00924h.
Pishbin, E., Kazemzadeh, A., Chimerad, M., Asiaei, S., Navidbakhsh, M., & Russom, A. (2020). Frequency dependent multiphase flows on centrifugal microfluidics. Lab on a chip, 20(3), 514-524. https://doi.org/10.1039/c9lc00924h
Pishbin, Esmail, et al. "Frequency dependent multiphase flows on centrifugal microfluidics." Lab on a chip vol. 20,3 (2020): 514-524. doi: https://doi.org/10.1039/c9lc00924h
Pishbin E, Kazemzadeh A, Chimerad M, Asiaei S, Navidbakhsh M, Russom A. Frequency dependent multiphase flows on centrifugal microfluidics. Lab Chip. 2020 Feb 07;20(3):514-524. doi: 10.1039/c9lc00924h. Epub 2020 Jan 03. PMID: 31898702.
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Analysis of 3D multi-layer microfluidic gradient generator.

Electrophoresis

Ha JH, Kim TH, Lee JM, Ahrberg CD, Chung BG.
PMID: 27801504
Electrophoresis. 2017 Jan;38(2):270-277. doi: 10.1002/elps.201600443. Epub 2016 Nov 23.

We developed a three-dimensional (3D) simple multi-layer microfluidic gradient generator to create molecular gradients on the centimeter scale with a wide range of flow rates. To create the concentration gradients, a main channel (MC) was orthogonally intersected with vertical...

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Ha JH, Kim TH, Lee JM, et al. Analysis of 3D multi-layer microfluidic gradient generator. Electrophoresis. 2016;38(2):270-277doi: 10.1002/elps.201600443.
Ha, J. H., Kim, T. H., Lee, J. M., Ahrberg, C. D., & Chung, B. G. (2017). Analysis of 3D multi-layer microfluidic gradient generator. Electrophoresis, 38(2), 270-277. https://doi.org/10.1002/elps.201600443
Ha, Jang Ho, et al. "Analysis of 3D multi-layer microfluidic gradient generator." Electrophoresis vol. 38,2 (2017): 270-277. doi: https://doi.org/10.1002/elps.201600443
Ha JH, Kim TH, Lee JM, Ahrberg CD, Chung BG. Analysis of 3D multi-layer microfluidic gradient generator. Electrophoresis. 2017 Jan;38(2):270-277. doi: 10.1002/elps.201600443. Epub 2016 Nov 23. PMID: 27801504.
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Real-time dual-loop electric current measurement for label-free nanofluidic preconcentration chip.

Lab on a chip

Chung PS, Fan YJ, Sheen HJ, Tian WC.
PMID: 25372369
Lab Chip. 2015 Jan 07;15(1):319-30. doi: 10.1039/c4lc01143k.

An electrokinetic trapping (EKT)-based nanofluidic preconcentration device with the capability of label-free monitoring trapped biomolecules through real-time dual-loop electric current measurement was demonstrated. Universal current-voltage (I-V) curves of EKT-based preconcentration devices, consisting of two microchannels connected by ion-selective channels,...

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Chung PS, Fan YJ, Sheen HJ, et al. Real-time dual-loop electric current measurement for label-free nanofluidic preconcentration chip. Lab Chip. 2015;15(1):319-30doi: 10.1039/c4lc01143k.
Chung, P. S., Fan, Y. J., Sheen, H. J., & Tian, W. C. (2015). Real-time dual-loop electric current measurement for label-free nanofluidic preconcentration chip. Lab on a chip, 15(1), 319-30. https://doi.org/10.1039/c4lc01143k
Chung, Pei-Shan, et al. "Real-time dual-loop electric current measurement for label-free nanofluidic preconcentration chip." Lab on a chip vol. 15,1 (2015): 319-30. doi: https://doi.org/10.1039/c4lc01143k
Chung PS, Fan YJ, Sheen HJ, Tian WC. Real-time dual-loop electric current measurement for label-free nanofluidic preconcentration chip. Lab Chip. 2015 Jan 07;15(1):319-30. doi: 10.1039/c4lc01143k. PMID: 25372369.
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Showing 25 to 36 of 203 entries