Publications

2022

1. Zath, G. K. ; Sperling, R. A. ; Hoffman, C. W. ; Bikos, D. A. ; Abbasi, R. ; Abate, A. R. ; Weitz, D. A. ; Chang, C. B. Rapid parallel generation of a fluorescently barcoded drop library from a microtiter plate using the plate-interfacing parallel encapsulation (PIPE) chip. Lab on a Chip 2022, 22, 4735-4745. Rapid parallel generation of a fluorescently barcoded drop library from a microtiter plate using the plate-interfacing parallel encapsulation (PIPE) chipPublisher's Version Rapid parallel generation of a fluorescently barcoded drop library from a microtiter plate using the plate-interfacing parallel encapsulation (PIPE) chipPDF
2. Shang, L. ; Cao, Y. ; Weitz, D. A. Multidisciplinary endeavors make future medicine smart. Smart Medicine 2022, 1, e20220031. Multidisciplinary endeavors make future medicine smartPublisher's Version Multidisciplinary endeavors make future medicine smartPDF
3. Zhang, Y. ; Zhao, X. – Z. ; Han, P. – H. ; Zhang, L. – Y. ; Weitz, D. A. ; Feng, Y. – J. F. Visualization of adaptive polymer flow and displacement in medium-permeable 3D core-on-a-chip. Petroleum Science 2022, 20, 1018-1029. Visualization of adaptive polymer flow and displacement in medium-permeable 3D core-on-a-chipPublisher's Version Visualization of adaptive polymer flow and displacement in medium-permeable 3D core-on-a-chipPDF
4. Wang, X. ; Blumenfeld, R. ; Feng, X. – Q. ; Weitz, D. A. ‘Phase transitions’ in bacteria – From structural transitions in free living bacteria to phenotypic transitions in bacteria within biofilms. Physics of Life Reviews 2022, 43, 98-138. ‘Phase transitions’ in bacteria – From structural transitions in free living bacteria to phenotypic transitions in bacteria within biofilmsPublisher's Version ‘Phase transitions’ in bacteria – From structural transitions in free living bacteria to phenotypic transitions in bacteria within biofilmsPDF
5. Wu, Q. ; Pan, M. ; Zhang, S. ; Sun, D. ; Yang, Y. ; Chen, D. ; Weitz, D. A. ; Gao, X. Research Progress in High-Throughput Screening of CO₂ Reduction Catalysts. Energies 2022, 15, 6666. Research Progress in High-Throughput Screening of CO2 Reduction CatalystsDOI Research Progress in High-Throughput Screening of CO2 Reduction CatalystsPDF
6. Weitz, D. A. “Soft materials evolution and revolution“. Nature Materials 2022, 21, 986-988. Soft materials evolution and revolutionPublisher's Version Soft materials evolution and revolutionPDF
7. Shen, Y. ; Weitz, D. A. ; Forde, N. R. ; Shayegan, M. “Line optical tweezers as controllable micromachines: techniques and emerging trends“. Soft Matter 2022, 18, 5359-5365. Line optical tweezers as controllable micromachines: techniques and emerging trendsPublisher's Version Line optical tweezers as controllable micromachines: techniques and emerging trendsPDF
8. Zheng, W. ; Zhao, S. ; Yin, Y. ; Zhang, H. ; Needham, D. M. ; Evans, E. D. ; Dai, C. L. ; Lu, P. J. ; Alm, E. J. ; Weitz, D. A. “High-throughput, single-microbe genomics with strain resolution, applied to a human gut microbiome“. Science 2022, 376, eabm1483. High-throughput, single-microbe genomics with strain resolution, applied to a human gut microbiomePublisher's Version High-throughput, single-microbe genomics with strain resolution, applied to a human gut microbiomePDF
9. Koveal, D. ; Rosen, P. C. ; Meyer, D. J. ; Diaz-Garcia, C. M. ; Wang, Y. ; Cai, L. – H. ; Chou, P. J. ; Weitz, D. A. ; Yellen, G. “A high-throughput multiparameter screen for accelerated development and optimization of soluble genetically encoded fluorescent biosensors“. Nature Communications 2022, 13, 2919. A high-throughput multiparameter screen for accelerated development and optimization of soluble genetically encoded fluorescent biosensorsPublisher's Version A high-throughput multiparameter screen for accelerated development and optimization of soluble genetically encoded fluorescent biosensorsPDF
10. Zhang, H. ; Zhang, L. ; An, C. ; Zhang, Y. ; Zhao, F. ; Gao, Y. ; Zhang, Y. ; Li, H. ; Zhang, Y. ; Ren, C. ; et al. “Large-scale single-cell encapsulation in microgels through metastable droplet-templating combined with microfluidic-integration“. Biofabrication 2022, 14, 035015. Large-scale single-cell encapsulation in microgels through metastable droplet-templating combined with microfluidic-integrationPublisher's Version Large-scale single-cell encapsulation in microgels through metastable droplet-templating combined with microfluidic-integrationPDF
11. Saad, A. M. ; Aime, S. ; Mahavadi, S. C. ; Song, Y. – Q. ; Yutkin, M. P. ; Weitz, D. A. ; Patzek, T. W. Adsorption of Polar Species at Crude Oil-Water Interfaces: the Chemoelastic Behavior. Langmuir 2022, 38, 6523–6530. Adsorption of Polar Species at Crude Oil-Water Interfaces: the Chemoelastic BehaviorPublisher's Version Adsorption of Polar Species at Crude Oil-Water Interfaces: the Chemoelastic BehaviorPDF
12. King, E. M. ; Wang, Z. ; Weitz, D. A. ; Spaepen, F. ; Brenner, M. P. Correlation Tracking: Using simulations to interpolate highly correlated particle tracks. Physical Review E 2022, 105, 044608. Correlation Tracking: Using simulations to interpolate highly correlated particle tracksPublisher's Version Correlation Tracking: Using simulations to interpolate highly correlated particle tracksPDF
13. Elkeles, T. ; Park, S. ; Werner, J. G. ; Weitz, D. A. ; Yossifon, G. Dielectrophoretic Characterization of Dynamic Microcapsules and Their Magnetophoretic Manipulation. ACS Appl. Mater. Interfaces 2022, 14, 15765–15773. Dielectrophoretic Characterization of Dynamic Microcapsules and Their Magnetophoretic ManipulationPublisher's Version Dielectrophoretic Characterization of Dynamic Microcapsules and Their Magnetophoretic ManipulationPDF
14. Xia, J. ; Liu, Z. – Y. ; Han, Z. – Y. ; Yuan, Y. ; Shao, Y. ; Feng, X. – Q. ; Weitz, D. A. Regulation of cell attachment, spreading, and migration by hydrogel substrates with independently tunable mesh size. Acta Biomaterialia 2022, 141, 178-189. Regulation of cell attachment, spreading, and migration by hydrogel substrates with independently tunable mesh sizePublisher's Version Regulation of cell attachment, spreading, and migration by hydrogel substrates with independently tunable mesh sizePDF
15. Wu, H. ; Shen, Y. ; Sivagurunathan, S. ; Weber, M. S. ; Adam, S. A. ; Shin, J. H. ; Fredberg, J. J. ; Medalia, O. ; Goldman, R. ; Weitz, D. A. Vimentin intermediate filaments and filamentous actin form unexpected interpenetrating networks that redefine the cell cortex. PNAS 2022, 119, e2115217119. Vimentin intermediate filaments and filamentous actin form unexpected interpenetrating networks that redefine the cell cortexPublisher's Version Vimentin intermediate filaments and filamentous actin form unexpected interpenetrating networks that redefine the cell cortexPDF
16. Battat, S. ; Weitz, D. A. ; Whitesides, G. “Nonlinear Phenomena in Microfluidics”. Chemical Reviews 2022, 122, 6921-6937. Nonlinear Phenomena in MicrofluidicsPublisher's Version Nonlinear Phenomena in MicrofluidicsPDF
17. Wu, Y. ; Pegoraro, A. F. ; Weitz, D. A. ; Janmey, P. ; Sun, S. X. “The correlation between cell and nucleus size is explained by an eukaryotic cell growth model”. PLOS Computational Biology 2022, 18, e1009400. The correlation between cell and nucleus size is explained by an eukaryotic cell growth modelPublisher's Version The correlation between cell and nucleus size is explained by an eukaryotic cell growth modelPDF
18. Chu, J. – O. ; Choi, Y. ; Kim, D. – W. ; Jeong, H. – S. ; Park, J. P. ; Weitz, D. A. ; Kee, S. – J. ; Lee, H. ; Choi, C. – H. “Cell-Inspired Hydrogel Microcapsules with a Thin Oil Layer of Enhanced Retention of Highly Reactive Antioxidants”. ACS Appl. Mater. Interfaces 2022, 14, 2597–2604. Cell-Inspired Hydrogel Microcapsules with a Thin Oil Layer of Enhanced Retention of Highly Reactive AntioxidantsPublisher's Version Cell-Inspired Hydrogel Microcapsules with a Thin Oil Layer of Enhanced Retention of Highly Reactive AntioxidantsPDF
19. Battat, S. ; Weitz, D. A. ; Whitesides, G. “An outlook on microfluidics: the promise and the challenge”. Lab on a Chip 2022, 22, 530-536. An outlook on microfluidics: the promise and the challengePublisher's Version An outlook on microfluidics: the promise and the challengePDF
20. Yang, C. ; Chen, L. ; Zhang, R. ; Chen, D. ; Arriaga, L. R. ; Weitz, D. A. “Local high-density distributions of phospholipids induced by the nucleation and growth of smectic liquid crystals at the interface”. Chinese Chemical Letters 2022, 33, 3973-3976. Local high-density distributions of phospholipids induced by the nucleation and growth of smectic liquid crystals at the interfacePublisher's Version
21. Sun, Z. ; Yan, X. ; Xiao, Y. ; Hu, L. ; Eggersdorfer, M. ; Chen, D. ; Yang, Z. ; Weitz, D. A. “Pickering emulsions stabilized by colloidal surfactants: Role of solid particles”. Particuology 2022, 64, 153-163. Pickering emulsions stabilized by colloidal surfactants: Role of solid particlesPublisher's Version Pickering emulsions stabilized by colloidal surfactants: Role of solid particlesPDF