Droplet microfluidic networks as hybrid dynamical systems: Inlet spacing optimization for sorting of drops

Abstract: The ability to manipulate drops is essential for integrating multiple processes in droplet microfluidics‐based lab‐on‐a‐chip devices. Examples of such droplet manipulation operations include sorting, sequencing, synchronization, and so forth. Microfluidic networks are promising platforms for performing these functionalities. This work explores the design of entry times of drops, a set of operating parameters, in a microfluidic network to achieve a desired functionality. Here, we specifically focus on sorting o… Show more

“…Systems engineering toolshighly regarded for the unprecedented growth they have produced in manufacturing and logisticshave recently catalyzed major advancements in the healthcare industry. − Through synchronizing and exploiting the information available, these mathematical methods have found immense applications in drug discovery and development, therapeutic planning, diagnostics, pharmaceutical manufacturing, and patient management. ,− Furthermore, they are being increasingly employed to generate novel insights into the nature and function of biological systemsidentifying reaction and signaling pathways in living cells, deciphering the interactions between organs and organ systems, homeostasis within the organism, or sometimes even multiscale biological phenomena. − In this work, combining a systems engineering model of the human cardiorespiratory system with formal methods for sensitivity analysis and parameter estimation, we seek to improve our understanding of a widely prevalent condition called chronic obstructive pulmonary disease (COPD).…”

Systems Engineering Approach to Modeling and Analysis of Chronic Obstructive Pulmonary Disease Part II: Extension for Variable Metabolic Rates

“…Systems engineering toolshighly regarded for the unprecedented growth they have produced in manufacturing and logisticshave recently catalyzed major advancements in the healthcare industry. − Through synchronizing and exploiting the information available, these mathematical methods have found immense applications in drug discovery and development, therapeutic planning, diagnostics, pharmaceutical manufacturing, and patient management. ,− Furthermore, they are being increasingly employed to generate novel insights into the nature and function of biological systemsidentifying reaction and signaling pathways in living cells, deciphering the interactions between organs and organ systems, homeostasis within the organism, or sometimes even multiscale biological phenomena. − In this work, combining a systems engineering model of the human cardiorespiratory system with formal methods for sensitivity analysis and parameter estimation, we seek to improve our understanding of a widely prevalent condition called chronic obstructive pulmonary disease (COPD).…”

Systems Engineering Approach to Modeling and Analysis of Chronic Obstructive Pulmonary Disease Part II: Extension for Variable Metabolic Rates

“…By virtue of the advantage of microliter‐sized droplet, Misyura 5 and Bakshi et al 6 explored the crystallization kinetics of salt solution droplet under diverse temperatures and concentrations, which revealed the droplet evaporation and crystallization behavior. Besides, Xu et al 7 and Rengaswamy et al 8 optimized the droplet generation in microchannel by regulating the size distribution and inlet spacing of droplets, demonstrating the superiority of droplet microfluidic on continuous preparation. Generally, the regulation of droplet crystallization was focused on the modulation of substrate hydrophilicity, 9 substrate structure, 10 substrate temperature, 11 and air relative humidity, 12 etc.…”

Interfacial confined droplet on sessile platform for crystal screening and harvest

Analysis of potential flow networks: Variations in transport time with discrete, continuous, and selfish operation