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1. Inertial and viscous flywheel sensing of nanoparticles

Author

Katsikis, Georgios, Collis, Jesse F., Knudsen, Scott M., Agache, Vincent, Sader, John E., and Manalis, Scott R.

Subjects
Physics - Fluid Dynamics
Abstract

Rotational dynamics often challenge physical intuition while enabling unique realizations, from the rotor of a gyroscope that maintains its orientation regardless of the outer gimbals, to a tennis racket that rotates around its handle when tossed face-up in the air. In the context of inertial mass sensing, which can measure mass with atomic precision, rotational dynamics are normally considered a complication hindering measurement interpretation. Here, we exploit the rotational dynamics of a microfluidic device to develop a new modality in inertial resonant sensing. Combining theory with experiments, we show that this modality normally measures the volume of the particle while being insensitive to its density. Paradoxically, particle density only emerges when fluid viscosity becomes dominant over inertia. We explain this paradox via a viscosity-driven, hydrodynamic coupling between the fluid and the particle that activates the rotational inertia of the particle, converting it into a viscous flywheel. This modality now enables the simultaneous measurement of particle volume and mass in fluid, using a single, high-throughput measurement., Comment: 20 pages, 4 figures, 12 s. figures, 2 s. tables

Published
2020
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3. Weighing the DNA Content of Adeno-Associated Virus Vectors with Zeptogram Precision Using Nanomechanical Resonators

Author

Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Chemical Engineering, Katsikis, Georgios, Hwang, Iris E, Wang, Wade, Bhat, Vikas S, McIntosh, Nicole L, Karim, Omair A, Blus, Bartlomiej J, Sha, Sha, Agache, Vincent, Wolfrum, Jacqueline M, Springs, Stacy L, Sinskey, Anthony J, Barone, Paul W, Braatz, Richard D, Manalis, Scott R, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Chemical Engineering, Katsikis, Georgios, Hwang, Iris E, Wang, Wade, Bhat, Vikas S, McIntosh, Nicole L, Karim, Omair A, Blus, Bartlomiej J, Sha, Sha, Agache, Vincent, Wolfrum, Jacqueline M, Springs, Stacy L, Sinskey, Anthony J, Barone, Paul W, Braatz, Richard D, and Manalis, Scott R

Abstract

Quantifying the composition of viral vectors used in vaccine development and gene therapy is critical for assessing their functionality. Adeno-associated virus (AAV) vectors, which are the most widely used viral vectors for in vivo gene therapy, are typically characterized using PCR, ELISA, and analytical ultracentrifugation which require laborious protocols or hours of turnaround time. Emerging methods such as charge-detection mass spectroscopy, static light scattering, and mass photometry offer turnaround times of minutes for measuring AAV mass using optical or charge properties of AAV. Here, we demonstrate an orthogonal method where suspended nanomechanical resonators (SNR) are used to directly measure both AAV mass and aggregation from a few microliters of sample within minutes. We achieve a precision near 10 zeptograms which corresponds to 1% of the genome holding capacity of the AAV capsid. Our results show the potential of our method for providing real-time quality control of viral vectors during biomanufacturing.

Published
2023

5. Weighing the DNA Content of Adeno-Associated Virus Vectors with Zeptogram Precision Using Nanomechanical Resonators

Author

Katsikis, Georgios, primary, Hwang, Iris E., additional, Wang, Wade, additional, Bhat, Vikas S., additional, McIntosh, Nicole L., additional, Karim, Omair A., additional, Blus, Bartlomiej J., additional, Sha, Sha, additional, Agache, Vincent, additional, Wolfrum, Jacqueline M., additional, Springs, Stacy L., additional, Sinskey, Anthony J., additional, Barone, Paul W., additional, Braatz, Richard D., additional, and Manalis, Scott R., additional

Published
2022
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7. Weighing the DNA content of Adeno-Associated Virus vectors with zeptogram precision using nanomechanical resonators

Author

Katsikis, Georgios, primary, Hwang, Iris E, additional, Wang, Wade, additional, Bhat, Vikas S, additional, McIntosh, Nicole L, additional, Karim, Omair A, additional, Blus, Bartlomiej J, additional, Sha, Sha, additional, Agache, Vincent, additional, Wolfrum, Jacqueline M, additional, Springs, Stacy L, additional, Sinskey, Anthony J, additional, Barone, Paul W, additional, Braatz, Richard D, additional, and Manalis, Scott R, additional

Published
2021
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8. Inertial and viscous flywheel sensing of nanoparticles

Author

Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Katsikis, Georgios, Collis, Jesse F., Knudsen, Scott, Agache, Vincent, Sader, John E., Manalis, Scott R, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Katsikis, Georgios, Collis, Jesse F., Knudsen, Scott, Agache, Vincent, Sader, John E., and Manalis, Scott R

Abstract

Rotational dynamics often challenge physical intuition while enabling unique realizations, from the rotor of a gyroscope that maintains its orientation regardless of the outer gimbals, to a tennis racket that rotates around its handle when tossed face-up in the air. In the context of inertial sensing, which can measure mass with atomic precision, rotational dynamics are normally considered a complication hindering measurement interpretation. Here, we exploit the rotational dynamics of a microfluidic device to develop a modality in inertial sensing. Combining theory with experiments, we show that this modality measures the volume of a rigid particle while normally being insensitive to its density. Paradoxically, particle density only emerges when fluid viscosity becomes dominant over inertia. We explain this paradox via a viscosity-driven, hydrodynamic coupling between the fluid and the particle that activates the rotational inertia of the particle, converting it into a ‘viscous flywheel’. This modality now enables the simultaneous measurement of particle volume and mass in fluid, using a single, high-throughput measurement.

Published
2021

9. Suspended Nanochannel Resonator Arrays with Piezoresistive Sensors for High-Throughput Weighing of Nanoparticles in Solution

Author

Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Gagino, Marco, Katsikis, Georgios, Olcum, Selim A., Virot, Leopold, Cochet, Martine, Thuaire, Aurélie, Manalis, Scott R, Agache, Vincent, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Mechanical Engineering, Gagino, Marco, Katsikis, Georgios, Olcum, Selim A., Virot, Leopold, Cochet, Martine, Thuaire, Aurélie, Manalis, Scott R, and Agache, Vincent

Abstract

As the use of nanoparticles is expanding in many industrial sectors, pharmaceuticals, cosmetics among others, flow-through characterization techniques are often required for in-line metrology. Among the parameters of interest, the concentration and mass of nanoparticles can be informative for yield, aggregates formation or even compliance with regulation. The Suspended Nanochannel Resonator (SNR) can offer mass resolution down to the attogram scale precision in a flow-through format. However, since the readout has been based on the optical lever, operating more than a single resonator at a time has been challenging. Here we present a new architecture of SNR devices with piezoresistive sensors that allows simultaneous readout from multiple resonators. To enable this architecture, we push the limits of nanofabrication to create implanted piezoresistors of nanoscale thickness (∼100 nm) and implement an algorithm for designing SNRs with dimensions optimized for maintaining attogram scale precision. Using 8-in. processing technology, we fabricate parallel array SNR devices which contain ten resonators. While maintaining a precision similar to that of the optical lever, we demonstrate a throughput of 40 »000 particles per hour - an order of magnitude improvement over a single device with an analogous flow rate. Finally, we show the capability of the SNR array device for measuring polydisperse solutions of gold particles ranging from 20 to 80 nm in diameter. We envision that SNR array devices will open up new possibilities for nanoscale metrology by measuring not only synthetic but also biological nanoparticles such as exosomes and viruses.

Published
2021

10. Rapid and high-precision sizing of single particles using parallel suspended microchannel resonator arrays and deconvolution

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Computational and Systems Biology Program, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Koch Institute for Integrative Cancer Research at MIT, Stockslager, Max Andrew, Olcum, Selim, Knudsen, Scott Michael, Kimmerling, Robert J., Cermak, Nathan, Payer, Kristofor Robert, Agache, Vincent, Manalis, Scott R., Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Computational and Systems Biology Program, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Koch Institute for Integrative Cancer Research at MIT, Stockslager, Max Andrew, Olcum, Selim, Knudsen, Scott Michael, Kimmerling, Robert J., Cermak, Nathan, Payer, Kristofor Robert, Agache, Vincent, and Manalis, Scott R.

Abstract

Measuring the size of micron-scale particles plays a central role in the biological sciences and in a wide range of industrial processes. A variety of size parameters, such as particle diameter, volume, and mass, can be measured using electrical and optical techniques. Suspended microchannel resonators (SMRs) are microfluidic devices that directly measure particle mass by detecting a shift in resonance frequency as particles flow through a resonating microcantilever beam. While these devices offer high precision for sizing particles by mass, throughput is fundamentally limited by the small dimensions of the resonator and the limited bandwidth with which changes in resonance frequency can be tracked. Here, we introduce two complementary technical advancements that vastly increase the throughput of SMRs. First, we describe a deconvolution-based approach for extracting mass measurements from resonance frequency data, which allows an SMR to accurately measure a particle's mass approximately 16-fold faster than previously possible, increasing throughput from 120 particles/min to 2000 particles/min for our devices. Second, we describe the design and operation of new devices containing up to 16 SMRs connected fluidically in parallel and operated simultaneously on the same chip, increasing throughput to approximately 6800 particles/min without significantly degrading precision. Finally, we estimate that future systems designed to combine both of these techniques could increase throughput by nearly 200-fold compared to previously described SMR devices, with throughput potentially as high as 24 000 particles/min. We envision that increasing the throughput of SMRs will broaden the range of applications for which mass-based particle sizing can be employed. Keywords: Particle size analysis; Signal processing; Microfluidic devices; Phase lock loop; Cantilever; Resonator device; MEMS devices; Mass measurement, Cancer Systems Biology Consortium (Grant R33 CA191143), National Cancer Institute (Grant U54 CA217377), National Cancer Institute. Koch Institute Support (Grant P30-CA14051)

Published
2020

14. Purification of complex samples: Implementation of a modular and reconfigurable droplet-based microfluidic platform with cascaded deterministic lateral displacement separation modules

Author

European Commission, Bpifrance, Pariset, Eloise [0000-0002-9375-2361], Pariset, Eloise, Pudda, Catherine, Boizot, François, Verplanck, Nicolas, Revol-Cavalier, Frédéric, Berthier, Jean, Thuaire, Aurélie, Agache, Vincent, European Commission, Bpifrance, Pariset, Eloise [0000-0002-9375-2361], Pariset, Eloise, Pudda, Catherine, Boizot, François, Verplanck, Nicolas, Revol-Cavalier, Frédéric, Berthier, Jean, Thuaire, Aurélie, and Agache, Vincent

Abstract

Particle separation in microfluidic devices is a common problematic for sample preparation in biology. Deterministic lateral displacement (DLD) is efficiently implemented as a sizebased fractionation technique to separate two populations of particles around a specific size. However, real biological samples contain components of many different sizes and a single DLD separation step is not sufficient to purify these complex samples. When connecting several DLD modules in series, pressure balancing at the DLD outlets of each step becomes critical to ensure an optimal separation efficiency. A generic microfluidic platform is presented in this paper to optimize pressure balancing, when DLD separation is connected either to another DLD module or to a different microfluidic function. This is made possible by generating droplets at T-junctions connected to the DLD outlets. Droplets act as pressure controllers, which perform at the same time the encapsulation of DLD sorted particles and the balance of output pressures. The optimized pressures to apply on DLD modules and on T-junctions are determined by a general model that ensures the equilibrium of the entire platform. The proposed separation platform is completely modular and reconfigurable since the same predictive model applies to any cascaded DLD modules of the dropletbased cartridge.

Published
2018

15. High-throughput measurement of single-cell growth rates using serial microfluidic mass sensor arrays

Author

Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Koch Institute for Integrative Cancer Research at MIT, Olcum, Selim A., Delgado, Francisco Feijo, Wasserman, Steven, Payer, Kristofor, Knudsen, Scott, Kimmerling, Robert John, Stevens, Mark M., Kikuchi, Yuki, Sandikci, Arzu, Manalis, Scott R, Cermak, Nathan, A Murakami, Mark, Ogawa, Masaaki, Agache, Vincent, Baléras, François, Weinstock, David M, Payer, Kristofor Robert, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Koch Institute for Integrative Cancer Research at MIT, Olcum, Selim A., Delgado, Francisco Feijo, Wasserman, Steven, Payer, Kristofor, Knudsen, Scott, Kimmerling, Robert John, Stevens, Mark M., Kikuchi, Yuki, Sandikci, Arzu, Manalis, Scott R, Cermak, Nathan, A Murakami, Mark, Ogawa, Masaaki, Agache, Vincent, Baléras, François, Weinstock, David M, and Payer, Kristofor Robert

Abstract

Methods to rapidly assess cell growth would be useful for many applications, including drug susceptibility testing, but current technologies have limited sensitivity or throughput. Here we present an approach to precisely and rapidly measure growth rates of many individual cells simultaneously. We flow cells in suspension through a microfluidic channel with 10-12 resonant mass sensors distributed along its length, weighing each cell repeatedly over the 4-20 min it spends in the channel. Because multiple cells traverse the channel at the same time, we obtain growth rates for >60 cells/h with a resolution of 0.2 pg/h for mammalian cells and 0.02 pg/h for bacteria. We measure the growth of single lymphocytic cells, mouse and human T cells, primary human leukemia cells, yeast, Escherichia coli and Enterococcus faecalis. Our system reveals subpopulations of cells with divergent growth kinetics and enables assessment of cellular responses to antibiotics and antimicrobial peptides within minutes., United States. Army Research Office (Grant W911NF-09-D-0001), National Science Foundation (U.S.) (Grant 1129359), National Cancer Institute (U.S.) (Grant U54CA143874), National Cancer Institute (U.S.) (Grant P30-CA14051), National Cancer Institute (U.S.) (Grant R33-CA191143), National Institutes of Health (U.S.) (Grant T32-GM008334), National Institute of General Medical Sciences (U.S.) (Grant T32-GM008334)

Published
2018

23. Emerging nano-devices for IOT applications

Author

Ernst, Thomas, primary, Agache, Vincent, additional, Rudan, Lionel, additional, Alava, Thomas, additional, Vianello, Elisa, additional, Hutin, Louis, additional, Gamrat, Christian, additional, Beigne, Edith, additional, Clermidy, Fabien, additional, Vinet, Maud, additional, Perniola, Luca, additional, de Salvo, Barbara, additional, and Hentz, Sebastien, additional

Published
2016
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24. High-throughput measurement of single-cell growth rates using serial microfluidic mass sensor arrays

Author

Cermak, Nathan, primary, Olcum, Selim, additional, Delgado, Francisco Feijó, additional, Wasserman, Steven C, additional, Payer, Kristofor R, additional, A Murakami, Mark, additional, Knudsen, Scott M, additional, Kimmerling, Robert J, additional, Stevens, Mark M, additional, Kikuchi, Yuki, additional, Sandikci, Arzu, additional, Ogawa, Masaaki, additional, Agache, Vincent, additional, Baléras, François, additional, Weinstock, David M, additional, and Manalis, Scott R, additional

Published
2016
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26. High performance NEMS devices for sensing applications

Author

Ernst, Thomas, primary, Hentz, Sebatien, additional, Arcamone, Julien, additional, Agache, Vincent, additional, Duraffourg, Laurent, additional, Ouerghi, Issam, additional, Ludurczak, Willy, additional, Ladner, Carine, additional, Ollier, Eric, additional, Andreucci, Philippe, additional, Colinet, Eric, additional, and Puget, Pierre, additional

Published
2015
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29. RF blade nano-electromechanical resonator with self-aligned process for definition of lateral electrostatic transducers

Author

Agache, Vincent, Legrand, Bernard, Collard, Dominique, Fujita, Hiroyuki, Buchaillot, Lionel, Institut d’Électronique, de Microélectronique et de Nanotechnologie - UMR 8520 (IEMN), Centrale Lille-Institut supérieur de l'électronique et du numérique (ISEN)-Université de Valenciennes et du Hainaut-Cambrésis (UVHC)-Université de Lille-Centre National de la Recherche Scientifique (CNRS)-Université Polytechnique Hauts-de-France (UPHF), Laboratory for Integrated Micro Mechatronics Systems (LIMMS), The University of Tokyo (UTokyo)-Centre National de la Recherche Scientifique (CNRS), Inst Ind Sci, CIRMM, and The University of Tokyo (UTokyo)

Subjects
[SPI]Engineering Sciences [physics]
Abstract

In this paper, the design, fabrication, and characterization of a new class of electromechanical resonator based on a blade geometry is proposed. This particular geometry allows self-alignment of the mechanical resonator to its lateral electrodes with nanometer scale lateral gap (

Published
2005

30. Microsystèmes, résonateurs électromécaniques : où cela nous mène-t-il ?

Author

Agache, Vincent, Quévy, Emmanuel, Millet, Olivier, Rollier, Anne-Sophie, Ringot, Roger, Collard, Dominique, Legrand, Bernard, Buchaillot, Lionel, Institut d’Électronique, de Microélectronique et de Nanotechnologie - UMR 8520 (IEMN), and Centrale Lille-Institut supérieur de l'électronique et du numérique (ISEN)-Université de Valenciennes et du Hainaut-Cambrésis (UVHC)-Université de Lille-Centre National de la Recherche Scientifique (CNRS)-Université Polytechnique Hauts-de-France (UPHF)

Subjects
[SPI]Engineering Sciences [physics]
Published
2005

31. Stiction-controlled locking system for three-dimensional self-assembling microstructures : theory and experimental validation

Author

Agache, Vincent, Buchaillot, Lionel, Collard, Dominique, Quévy, Emmanuel, Institut d’Électronique, de Microélectronique et de Nanotechnologie - UMR 8520 (IEMN), and Centrale Lille-Institut supérieur de l'électronique et du numérique (ISEN)-Université de Valenciennes et du Hainaut-Cambrésis (UVHC)-Université de Lille-Centre National de la Recherche Scientifique (CNRS)-Université Polytechnique Hauts-de-France (UPHF)

Subjects
locking system, [SPI]Engineering Sciences [physics], Stiction, SDA, modeling, self-assembly
Abstract

The novelty of our study lies in the first controlled use of the phenomenon of stiction to lock three-dimensional self- assembled polysilicon microstructures. The stiction refers to the permanent adhesion of the microstructures to adjacent surfaces. It can occur either during the final stage of the micromachining process, that is to say the releasing of the microstructural material, or after the packaging of the device, due to overrange input signals or electromechanical instability. As a result, we often regard stiction as a major failure issue in the MEMS field of research. This paper reports both the theory of our stiction-controlled locking system operation mode and the validation of our original concept through the stiction-locking of a 3-D self-assembled device

Published
2001

37. A programmable and reconfigurable microfluidic chip

Author

Renaudot, Raphael, primary, Agache, Vincent, additional, Fouillet, Yves, additional, Laffite, Guillaume, additional, Bisceglia, Emilie, additional, Jalabert, Laurent, additional, Kumemura, Momoko, additional, Collard, Dominique, additional, and Fujita, Hiroyuki, additional

Published
2013
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45. Purification of complex samples: Implementation of a modular and reconfigurable droplet-based microfluidic platform with cascaded deterministic lateral displacement separation modules

Author

Pariset, Eloise, Pudda, Catherine, Boizot, François, Verplanck, Nicolas, Revol-Cavalier, Frédéric, Berthier, Jean, Thuaire, Aurélie, Agache, Vincent, European Commission, Bpifrance, Pariset, Eloise, and Pariset, Eloise [0000-0002-9375-2361]

Subjects
Imaging Techniques, Materials by Structure, Microfluidics, Materials Science, lcsh:Medicine, Fluid Mechanics, Aqueous Solutions, Research and Analysis Methods, Biochemistry, Continuum Mechanics, Mathematical and Statistical Techniques, Lab-On-A-Chip Devices, Fluorescence Imaging, Nanotechnology, Statistical Methods, lcsh:Science, Flow Rate, Physics, lcsh:R, Biology and Life Sciences, Classical Mechanics, Fluid Dynamics, Microfluidic Analytical Techniques, Lipids, Solutions, Microscopy, Fluorescence, Mixtures, Physical Sciences, Engineering and Technology, Nanoparticles, lcsh:Q, Fluidics, Oils, Mathematics, Statistics (Mathematics), Research Article, Forecasting
Abstract

Particle separation in microfluidic devices is a common problematic for sample preparation in biology. Deterministic lateral displacement (DLD) is efficiently implemented as a sizebased fractionation technique to separate two populations of particles around a specific size. However, real biological samples contain components of many different sizes and a single DLD separation step is not sufficient to purify these complex samples. When connecting several DLD modules in series, pressure balancing at the DLD outlets of each step becomes critical to ensure an optimal separation efficiency. A generic microfluidic platform is presented in this paper to optimize pressure balancing, when DLD separation is connected either to another DLD module or to a different microfluidic function. This is made possible by generating droplets at T-junctions connected to the DLD outlets. Droplets act as pressure controllers, which perform at the same time the encapsulation of DLD sorted particles and the balance of output pressures. The optimized pressures to apply on DLD modules and on T-junctions are determined by a general model that ensures the equilibrium of the entire platform. The proposed separation platform is completely modular and reconfigurable since the same predictive model applies to any cascaded DLD modules of the dropletbased cartridge., This work was supported by a CFR CEA grant for Ph.D. funding, FET Proactive VIRUSCAN H2020 project (No. 731868) and BactiDIAG grant funded by BPI France under the FUI framework (FUI-AAP18).

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