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171 results on '"Shusteff, Maxim"'

1. Fundamental Scaling Relationships in Additive Manufacturing and their Implications for Future Manufacturing Systems

Author

Wirth, David M., Li, Chi Chung, Pokorski, Jonathan K., Taylor, Hayden K., and Shusteff, Maxim

Subjects
Condensed Matter - Materials Science
Abstract

The field of additive manufacturing (AM) has advanced considerably over recent decades through the development of novel methods, materials, and systems. However, as the field approaches maturity, it is relevant to investigate the scaling frontiers and fundamental limits of AM in a generalized sense. Here we propose a simplified universal mathematical model that describes the essential process dynamics of many AM hardware platforms. We specifically examine the influence of several key parameters on total manufacturing time, comparing these with performance results obtained from real-world AM systems. We find a inverse-cubic dependency on minimal feature size and a linear dependency on overall structure size. These relationships imply how certain process features such as parallelization and process dimensionality can help move toward the fundamental limits. AM methods that are capable of varying the size of deposited voxels provide one possibility to overcome these limits in the future development of AM. We also propose a new framework for classifying manufacturing processes as "top-down" vs "bottom-up" paradigms, which differs from the conventional usage of such terms, and present considerations for how "bottom-up" manufacturing approaches may surpass the fundamental limits of "top-down" systems., Comment: 32 pages, 5 figures

Published
2023

2. Development of a Reactive Force Field for Simulating Photoinitiated Acrylate Polymerization.

Author

Huang, Yihan, Karnes, John J, Shusteff, Maxim, and Faller, Roland

Subjects
Physical Sciences, Chemical Sciences, Engineering
Abstract

Light-driven and photocurable polymer-based additive manufacturing (AM) has enormous potential due to its excellent resolution and precision. Acrylated resins that undergo radical chain-growth polymerization are widely used in photopolymer AM due to their fast kinetics and often serve as a departure point for developing other resin materials for photopolymer-based AM technologies. For successful control of the photopolymer resins, the molecular basis of the acrylate free-radical polymerization has to be understood in detail. We present an optimized reactive force field (ReaxFF) for molecular dynamics (MD) simulations of acrylate polymer resins that captures radical polymerization thermodynamics and kinetics. The force field is trained against an extensive training set including density functional theory (DFT) calculations of reaction pathways along the radical polymerization from methyl acrylate to methyl butyrate, bond dissociation energies, and structures and partial charges of several molecules and radicals. We also found that it was critical to train the force field against an incorrect, nonphysical reaction pathway observed in simulations that used parameters not optimized for acrylate polymerization. The parameterization process utilizes a parallelized search algorithm, and the resulting model can describe polymer resin formation, crosslinking density, conversion rate, and residual monomers of the complex acrylate mixtures.

Published
2023

3. Isolating Chemical Reaction Mechanism as a Variable with Reactive Coarse-Grained Molecular Dynamics: Step-Growth versus Chain-Growth Polymerization

Author

Karnes, John J, Weisgraber, Todd H, Cook, Caitlyn C, Wang, Daniel N, Crowhurst, Jonathan C, Fox, Christina A, Harris, Bradley S, Oakdale, James S, Faller, Roland, and Shusteff, Maxim

Subjects
Bioengineering, 1.1 Normal biological development and functioning, Underpinning research, Chemical Sciences, Engineering, Polymers
Abstract

We present a general approach to isolate chemical reaction mechanism as an independently controllable variable across chemically distinct systems. Modern approaches to reduce the computational expense of molecular dynamics simulations often group multiple atoms into a single “coarse-grained” interaction site, which leads to a loss of chemical resolution. In this work we convert this shortcoming into a feature and use identical coarse-grained models to represent molecules that share nonreactive characteristics but react by different mechanisms. As a proof of concept, we use this approach to simulate and investigate distinct, yet similar, trifunctional isocyanurate resin formulations that polymerize by either chain- or step-growth. Because the underlying molecular mechanics of these models are identical, all emergent differences are a function of the reaction mechanism only. We find that the microscopic morphologies resemble related all-atom simulations and that simulated mechanical testing reasonably agrees with experiment.

Published
2023

4. Isolating Chemical Reaction Mechanism as a Variable with Reactive Coarse-Grained Molecular Dynamics: Step-Growth versus Chain-Growth Polymerization

Author

Karnes, John J., Weisgraber, Todd H., Cook, Caitlyn C., Wang, Daniel N., Crowhurst, Jonathan C., Fox, Christina A., Harris, Bradley S., Oakdale, James S., Faller, Roland, and Shusteff, Maxim

Subjects
Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter, Physics - Chemical Physics
Abstract

We present a general approach to isolate chemical reaction mechanism as an independently controllable variable across chemically distinct systems. Modern approaches to reduce the computational expense of molecular dynamics simulations often group multiple atoms into a single "coarse-grained" interaction site, which leads to a loss of chemical resolution. In this work we convert this shortcoming into a feature and use identical coarse-grained models to represent molecules that share non-reactive characteristics but react by different mechanisms. As a proof of concept we use this approach to simulate and investigate distinct, yet similar, trifunctional isocyanurate resin formulations that polymerize by either chain- or step-growth. Since the underlying molecular mechanics of these models are identical, all emergent differences are a function of the reaction mechanism only. We find that the microscopic morphologies resemble related all-atom simulations and that simulated mechanical testing reasonably agrees with experiment.

Published
2022
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5. A perfused multi-well bioreactor platform to assess tumor organoid response to a chemotherapeutic gradient.

Author

Wasson, Elisa Marie, He, Wei, Ahlquist, Jesse, Hynes, William Fredrick, Triplett, Michael Gregory, Hinckley, Aubree, Karelehto, Eveliina, Gray-Sherr, Delaney Ruth, Friedman, Caleb Fisher, Robertson, Claire, Shusteff, Maxim, Warren, Robert, Coleman, Matthew A, Moya, Monica Lizet, and Wheeler, Elizabeth K

Subjects
bioreactor 3D cell culture, colorectal (colon) cancer, drug transport, flow transport, tumor model, Biotechnology, Digestive Diseases, Colo-Rectal Cancer, Cancer, Good Health and Well Being, Other Biological Sciences, Biomedical Engineering, Medical Biotechnology
Abstract

There is an urgent need to develop new therapies for colorectal cancer that has metastasized to the liver and, more fundamentally, to develop improved preclinical platforms of colorectal cancer liver metastases (CRCLM) to screen therapies for efficacy. To this end, we developed a multi-well perfusable bioreactor capable of monitoring CRCLM patient-derived organoid response to a chemotherapeutic gradient. CRCLM patient-derived organoids were cultured in the multi-well bioreactor for 7 days and the subsequently established gradient in 5-fluorouracil (5-FU) concentration resulted in a lower IC50 in the region near the perfusion channel versus the region far from the channel. We compared behaviour of organoids in this platform to two commonly used PDO culture models: organoids in media and organoids in a static (no perfusion) hydrogel. The bioreactor IC50 values were significantly higher than IC50 values for organoids cultured in media whereas only the IC50 for organoids far from the channel were significantly different than organoids cultured in the static hydrogel condition. Using finite element simulations, we showed that the total dose delivered, calculated using area under the curve (AUC) was similar between platforms, however normalized viability was lower for the organoid in media condition than in the static gel and bioreactor. Our results highlight the utility of our multi-well bioreactor for studying organoid response to chemical gradients and demonstrate that comparing drug response across these different platforms is nontrivial.

Published
2023

6. A review of materials used in tomographic volumetric additive manufacturing

Author

Madrid-Wolff, Jorge, Toombs, Joseph, Rizzo, Riccardo, Bernal, Paulina Nuñez, Porcincula, Dominique, Walton, Rebecca, Wang, Bin, Kotz-Helmer, Frederik, Yang, Yi, Kaplan, David, Zhang, Yu Shrike, Zenobi-Wong, Marcy, McLeod, Robert R., Rapp, Bastian, Schwartz, Johanna, Shusteff, Maxim, Talyor, Hayden, Levato, Riccardo, and Moser, Christophe

Published
2023
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7. One-Pot Printing of Robust Multimaterial Devices

Author

Huang, Sijia, Adelmund, Steven, Pichumani, Pradip S., Schwartz, Johanna J., Menguc, Yigit, Shusteff, Maxim, and Wallin, Thomas J.

Subjects
Condensed Matter - Materials Science
Abstract

Polymer 3D printing is a broad set of manufacturing methods that permit the fabrication of complex architectures, and, as a result, numerous efforts focus on formulating processible chemistries that produce desirable material behavior in printed parts. However, current resin chemistries typically result in a single fixed set of properties once fully polymerized, a fact that poses significant engineering challenges to obtaining multimaterial devices. As an alternative to single-property materials, we introduce a ternary sequential reaction scheme that exhibits diverse multimaterial properties by profoundly altering the polymer microstructure from within a single resin composition. In this system, the photodosage during 3D printing sets both the shape and extent of conversion for each subsequent reaction. This different polymerization mechanisms of the subsequent stages yield disparate crosslink densities and viscoelastic properties. As a result, our materials possess Young's Moduli spanning over three orders of magnitude (400 kPa < E < 1.6 GPa) with smooth transitions between soft and stiff regions. We successfully pattern a 500x change in modulus in under a millimeter while the sequential assembly of our polymer networks ensures robust interfaces and enhances toughness by 10x compared to the single property materials. Most importantly, the final objects remain stable to UV and thermal aging, a key limitation to applications of previous multimaterial chemistries. We demonstrate the ability to 3D print intricate multimaterial architectures by fabricating a soft, wearable braille display., Comment: 54 pages including supplemental information, 5 main text figures

Published
2021

8. Programmable thermocapillary shaping of thin liquid films

Author

Eshel, Ran, Frumkin, Valeri, Nice, Matan, Luria, Omer, Ferdman, Boris, Opatovski, Nadav, Gommed, Khaled, Shusteff, Maxim, Shechtman, Yoav, and Bercovici, Moran

Subjects
Physics - Optics, Physics - Applied Physics, Physics - Fluid Dynamics
Abstract

We present a method that leverages projected light patterns as a mechanism for freeform deformations of a thin liquid film via the thermocapillary effect. We developed a closed-form solution for the inverse problem of the thin-film evolution equation, allowing to obtain the projection pattern required in order to achieve a desired topography. We experimentally implement the method using a computer controlled light projector, which illuminates any desired pattern onto the bottom of a fluidic chamber patterned with heat absorbing metal pads. The resulting heat map induces surface tension gradients in the liquid-air interface, giving rise to thermocapillary flow that deforms the liquid surface. If a polymer is used for the liquid film, it can then be photocured to yield a solid device. Based on the inverse problem solutions and using this system, we demonstrate the fabrication of several diffractive optical elements (DOEs), including phase masks for extended depth of field imaging, and for 3D localization microscopy. The entire process, from projection to solidification, is completed in less than five minutes, and yields a sub-nanometric surface quality without any post-processing., Comment: Manuscript and supplementary information combined

Published
2021
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11. Computed Axial Lithography (CAL): Toward Single Step 3D Printing of Arbitrary Geometries

Author

Kelly, Brett, Bhattacharya, Indrasen, Shusteff, Maxim, Panas, Robert M., Taylor, Hayden K., and Spadaccini, Christopher M.

Subjects
Computer Science - Graphics, I.3.1, I.3.3, I.3.5, I.3.7, I.3.8, I.4.0
Abstract

Most additive manufacturing processes today operate by printing voxels (3D pixels) serially point-by-point to build up a 3D part. In some more recently-developed techniques, for example optical printing methods such as projection stereolithography [Zheng et al. 2012], [Tumbleston et al. 2015], parts are printed layer-by-layer by curing full 2d (very thin in one dimension) layers of the 3d part in each print step. There does not yet exist a technique which is able to print arbitrarily-defined 3D geometries in a single print step. If such a technique existed, it could be used to expand the range of printable geometries in additive manufacturing and relax constraints on factors such as overhangs in topology optimization. It could also vastly increase print speed for 3D parts. In this work, we develop the principles for an approach for single exposure 3D printing of arbitrarily defined geometries. The approach, termed Computed Axial Lithgography (CAL), is based on tomographic reconstruction, with mathematical optimization to generate a set of projections to optically define an arbitrary dose distribution within a target volume. We demonstrate the potential ability of the technique to print 3D parts using a prototype CAL system based on sequential illumination from many angles. We also propose new hardware designs which will help us to realize true single-shot arbitrary-geometry 3D CAL., Comment: 10 pages, 17 figure, ACM SIGGRAPH format

Published
2017

12. One-step volumetric additive manufacturing of complex polymer structures.

Author

Shusteff, Maxim, Browar, Allison EM, Kelly, Brett E, Henriksson, Johannes, Weisgraber, Todd H, Panas, Robert M, Fang, Nicholas X, and Spadaccini, Christopher M

Abstract

Two limitations of additive manufacturing methods that arise from layer-based fabrication are slow speed and geometric constraints (which include poor surface quality). Both limitations are overcome in the work reported here, introducing a new volumetric additive fabrication paradigm that produces photopolymer structures with complex nonperiodic three-dimensional geometries on a time scale of seconds. We implement this approach using holographic patterning of light fields, demonstrate the fabrication of a variety of structures, and study the properties of the light patterns and photosensitive resins required for this fabrication approach. The results indicate that low-absorbing resins containing ~0.1% photoinitiator, illuminated at modest powers (~10 to 100 mW), may be successfully used to build full structures in ~1 to 10 s.

Published
2017

17. Glycerol-based sustainably sourced resin for volumetric printing

Author

Krumins, Eduards, primary, Lentz, Joachim C., additional, Sutcliffe, Ben, additional, Sohaib, Ali, additional, Jacob, Philippa L., additional, Brugnoli, Benedetta, additional, Cuzzucoli Crucitti, Valentina, additional, Cavanagh, Robert, additional, Owen, Robert, additional, Moloney, Cara, additional, Ruiz-Cantu, Laura, additional, Francolini, Iolanda, additional, Howdle, Steven M., additional, Shusteff, Maxim, additional, Rose, Felicity R. A. J., additional, Wildman, Ricky D., additional, He, Yinfeng, additional, and Taresco, Vincenzo, additional

Published
2024
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18. A Microfluidic Platform for Precision Small-volume Sample Processing and Its Use to Size Separate Biological Particles with an Acoustic Microdevice.

Author

Fong, Erika J, Huang, Chao, Hamilton, Julie, Benett, William J, Bora, Mihail, Burklund, Alison, Metz, Thomas R, and Shusteff, Maxim

Subjects
Bioengineering, Issue 105, microfluidics, lab on a chip, cell separation, acoustophoresis, lab automation, microfabrication, MEMS, LabVIEW, Biochemistry and Cell Biology, Psychology, Cognitive Sciences
Abstract

A major advantage of microfluidic devices is the ability to manipulate small sample volumes, thus reducing reagent waste and preserving precious sample. However, to achieve robust sample manipulation it is necessary to address device integration with the macroscale environment. To realize repeatable, sensitive particle separation with microfluidic devices, this protocol presents a complete automated and integrated microfluidic platform that enables precise processing of 0.15-1.5 ml samples using microfluidic devices. Important aspects of this system include modular device layout and robust fixtures resulting in reliable and flexible world to chip connections, and fully-automated fluid handling which accomplishes closed-loop sample collection, system cleaning and priming steps to ensure repeatable operation. Different microfluidic devices can be used interchangeably with this architecture. Here we incorporate an acoustofluidic device, detail its characterization, performance optimization, and demonstrate its use for size-separation of biological samples. By using real-time feedback during separation experiments, sample collection is optimized to conserve and concentrate sample. Although requiring the integration of multiple pieces of equipment, advantages of this architecture include the ability to process unknown samples with no additional system optimization, ease of device replacement, and precise, robust sample processing.

Published
2015

19. Spatial tuning of acoustofluidic pressure nodes by altering net sonic velocity enables high-throughput, efficient cell sorting

Author

Jung, Seung-Yong, Notton, Timothy, Fong, Erika, Shusteff, Maxim, and Weinberger, Leor S

Subjects
Fluid Mechanics and Thermal Engineering, Engineering, Biotechnology, Bioengineering, Acoustics, Cell Separation, High-Throughput Screening Assays, Humans, Hydrostatic Pressure, Microfluidic Analytical Techniques, Particle Size, T-Lymphocytes, Chemical Sciences, Analytical Chemistry, Chemical sciences
Abstract

Particle sorting using acoustofluidics has enormous potential but widespread adoption has been limited by complex device designs and low throughput. Here, we report high-throughput separation of particles and T lymphocytes (600 μL min(-1)) by altering the net sonic velocity to reposition acoustic pressure nodes in a simple two-channel device. The approach is generalizable to other microfluidic platforms for rapid, high-throughput analysis.

Published
2015

21. A perfused multi-well bioreactor platform to assess tumor organoid response to a chemotherapeutic gradient

Author

Wasson, Elisa Marie, primary, He, Wei, additional, Ahlquist, Jesse, additional, Hynes, William Fredrick, additional, Triplett, Michael Gregory, additional, Hinckley, Aubree, additional, Karelehto, Eveliina, additional, Gray-Sherr, Delaney Ruth, additional, Friedman, Caleb Fisher, additional, Robertson, Claire, additional, Shusteff, Maxim, additional, Warren, Robert, additional, Coleman, Matthew A., additional, Moya, Monica Lizet, additional, and Wheeler, Elizabeth K., additional

Published
2023
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22. Swab Testing Results

Author

Spadaccini, Chris, primary, Duoss, Eric, additional, Shusteff, Maxim, additional, Tooker, Angela, additional, and Haque, Razi, additional

Published
2020
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30. Ultralight, Ultrastiff Mechanical Metamaterials

Author

Zheng, Xiaoyu, Lee, Howon, Weisgraber, Todd H., Shusteff, Maxim, DeOtte, Joshua, Duoss, Eric B., Kuntz, Joshua D., Biener, Monika M., Ge, Qi, Jackson, Julie A., Kucheyev, Sergei O., Fang, Nicholas X., and Spadaccini, Christopher M.

Published
2014

32. Anisotropic Thermally Conductive Composites Enabled by Acoustophoresis and Stereolithography

Author

Melchert, Drew S., primary, Tahmasebipour, Amir, additional, Liu, Xin, additional, Mancini, Julie, additional, Moran, Bryan, additional, Giera, Brian, additional, Joshipura, Ishan D., additional, Shusteff, Maxim, additional, Meinhart, Carl D., additional, Cobb, Corie L., additional, Spadaccini, Christopher, additional, Gianola, Daniel S., additional, and Begley, Matthew R., additional

Published
2022
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35. Latent image volumetric additive manufacturing

Author

Rackson, Charles M., primary, Toombs, Joseph T., additional, De Beer, Martin P., additional, Cook, Caitlyn C., additional, Shusteff, Maxim, additional, Taylor, Hayden K., additional, and McLeod, Robert R., additional

Published
2022
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36. Fluorescence correlation spectroscopy measurements of proteins expressed inside microcapsules

Author

Liu, Chao, primary, Hoang-Phou, Steven A., additional, Ye, Congwang, additional, Laurence, Matthew J., additional, Rubinfeld, Bonnee, additional, Desautels, Thomas A., additional, Smith, Willaim L., additional, Fong, Erika J., additional, Watkins, Nicholas N., additional, Gilmore, Sean F., additional, Shusteff, Maxim, additional, Laurence, Ted A., additional, and Coleman, Matthew A., additional

Published
2022
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40. Programmable thermocapillary shaping of thin liquid films

Author

Eshel, Ran, primary, Frumkin, Valeri, additional, Nice, Matan, additional, Luria, Omer, additional, Ferdman, Boris, additional, Opatovski, Nadav, additional, Gommed, Khaled, additional, Shusteff, Maxim, additional, Shechtman, Yoav, additional, and Bercovici, Moran, additional

Published
2022
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45. Additive Manufacturing: Highly Tunable Thiol‐Ene Photoresins for Volumetric Additive Manufacturing (Adv. Mater. 47/2020)

Author

Cook, Caitlyn C., primary, Fong, Erika J., additional, Schwartz, Johanna J., additional, Porcincula, Dominique H., additional, Kaczmarek, Allison C., additional, Oakdale, James S., additional, Moran, Bryan D., additional, Champley, Kyle M., additional, Rackson, Charles M., additional, Muralidharan, Archish, additional, McLeod, Robert R., additional, and Shusteff, Maxim, additional

Published
2020
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46. Highly Tunable Thiol‐Ene Photoresins for Volumetric Additive Manufacturing

Author

Cook, Caitlyn C., primary, Fong, Erika J., additional, Schwartz, Johanna J., additional, Porcincula, Dominique H., additional, Kaczmarek, Allison C., additional, Oakdale, James S., additional, Moran, Bryan D., additional, Champley, Kyle M., additional, Rackson, Charles M., additional, Muralidharan, Archish, additional, McLeod, Robert R., additional, and Shusteff, Maxim, additional

Published
2020
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50. Volumetric additive manufacturing of polymer structures by holographically projected light fields

Author

Nicholas Xuanlai Fang., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., Shusteff, Maxim, 1979, Nicholas Xuanlai Fang., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., and Shusteff, Maxim, 1979

Abstract

Thesis: Ph. D. in Electrical Engineering, Massachusetts Institute of Technology, Department of Electrical Engineering and Computer Science, 2017., This electronic version was submitted by the student author. The certified thesis is available in the Institute Archives and Special Collections., Cataloged from student-submitted PDF version of thesis., Includes bibliographical references (pages 100-108)., As additive manufacturing technologies proliferate and mature, overcoming some of their process limitations becomes increasingly important for the continued expansion of practical applications. Two such limitations that arise from layer-based fabrication are slow speed and geometric constraints (which include poor surface quality and challenges fabricating span, cantilever, and overhang elements). Moving beyond point-by-point and layer-by-layer approaches, the ability to generate a complex 3D volume as a unit operation has the potential to overcome these limitations. Since holography has been extensively studied as a means for storage and retrieval of 3D geometrical information, this dissertation explores the use of holographically-shaped light fields for producing three-dimensional structures in a "volume at once" approach. Leveraging advances in spatial light modulator (SLM) technology, phase-controlled light fields are projected into photopolymer resin to cure a desired geometry. By overlapping multiple sub-regions of a single light field within the target volume, the successful fabrication of non-periodic complex 3D geometries is demonstrated by single exposures on timescales of seconds. This dissertation presents a complete prototype platform that makes this approach possible, comprising a suitable hardware configuration along with the computational algorithms necessary to calculate and optimize the required optical fields. A study of the photopolymerization kinetics is also carried out, to determine the boundaries of usable process parameters such as resin absorbance and available light intensity. The results indicate that low-absorbing resins containing ~0.1% photoinitiator, illuminated at modest powers (~10-100 mW) may be used to produce full 3D structures from 1-10 second exposures, with volume build rates exceeding 100 cm3/hr, without layering and with no need for a substrate or support material., by Maxim Shusteff., Ph. D. in Electrical Engineering

Published
2018

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