Dimensional Analysis Meets AI for Non-Newtonian Droplet Generation

Overview

Journal Lab Chip

Publisher Royal Society of Chemistry

Specialties Biotechnology
Chemistry

Date 2025 Feb 18

PMID 39964239

Authors

Farnoosh Hormozinezhad

Claire Barnes

Alexandre Fabregat

Salvatore Cito

Francesco Del Giudice

Affiliations

Soon will be listed here.

Abstract

Non-Newtonian droplets are used across various applications, including pharmaceuticals, food processing, drug delivery and material science. However, predicting droplet formation using such complex fluids is challenging due to the intricate multiphase interactions between fluids with varying viscosities, elastic properties and geometrical constraints. In this study, we introduce a novel hybrid machine-learning architecture that integrates dimensional analysis with machine learning to predict the flow rates required to generate droplets with specified sizes in systems involving non-Newtonian fluids. Unlike previous approaches, our model is designed to accommodate shear-rate-dependent viscosities and a simple estimate of the elastic properties of the fluids. It provides accurate predictions of the dispersed and continuous phases flow rates for given droplet length, height, and viscosity curves, even when the fluid properties deviate from those used during training. Our model demonstrates strong predictive power, achieving values of up to 0.82 for unseen data. The significance of our work lies in its ability to generalize across a broad range of non-Newtonian systems having different viscosity curves, offering a powerful tool for optimizing droplet generation. This model represents a significant advancement in the application of machine learning to microfluidics, providing new opportunities for efficient experimental design in complex multiphase systems.

References

Shahrivar K, Del Giudice F . Beating Poisson stochastic particle encapsulation in flow-focusing microfluidic devices using viscoelastic liquids. Soft Matter. 2022; 18(32):5928-5933. DOI: 10.1039/d2sm00935h. View

Ren Y, Liu Z, Shum H . Breakup dynamics and dripping-to-jetting transition in a Newtonian/shear-thinning multiphase microsystem. Lab Chip. 2014; 15(1):121-34. DOI: 10.1039/c4lc00798k. View

Elvira K, Gielen F, Tsai S, Nightingale A . Materials and methods for droplet microfluidic device fabrication. Lab Chip. 2022; 22(5):859-875. PMC: 9074766. DOI: 10.1039/d1lc00836f. View

Sartipzadeh O, Naghib S, Seyfoori A, Rahmanian M, Fateminia F . Controllable size and form of droplets in microfluidic-assisted devices: Effects of channel geometry and fluid velocity on droplet size. Mater Sci Eng C Mater Biol Appl. 2020; 109:110606. DOI: 10.1016/j.msec.2019.110606. View

Siemenn A, Shaulsky E, Beveridge M, Buonassisi T, Hashmi S, Drori I . A Machine Learning and Computer Vision Approach to Rapidly Optimize Multiscale Droplet Generation. ACS Appl Mater Interfaces. 2022; 14(3):4668-4679. DOI: 10.1021/acsami.1c19276. View

Fatehifar M, Revell A, Jabbari M . Non-Newtonian Droplet Generation in a Cross-Junction Microfluidic Channel. Polymers (Basel). 2021; 13(12). PMC: 8226625. DOI: 10.3390/polym13121915. View

Nan L, Zhang H, Weitz D, Shum H . Development and future of droplet microfluidics. Lab Chip. 2024; 24(5):1135-1153. DOI: 10.1039/d3lc00729d. View

Chagot L, Quilodran-Casas C, Kalli M, Kovalchuk N, Simmons M, Matar O . Surfactant-laden droplet size prediction in a flow-focusing microchannel: a data-driven approach. Lab Chip. 2022; 22(20):3848-3859. DOI: 10.1039/d2lc00416j. View

Shahrivar K, Del Giudice F . Controlled viscoelastic particle encapsulation in microfluidic devices. Soft Matter. 2021; 17(35):8068-8077. DOI: 10.1039/d1sm00941a. View

10.

Caggioni M, Bayles A, Lenis J, Furst E, Spicer P . Interfacial stability and shape change of anisotropic endoskeleton droplets. Soft Matter. 2014; 10(38):7647-52. DOI: 10.1039/c4sm01482k. View

11.

Xue C, Chen X, Li Y, Hu G, Cao T, Qin K . Breakup Dynamics of Semi-dilute Polymer Solutions in a Microfluidic Flow-focusing Device. Micromachines (Basel). 2020; 11(4). PMC: 7231330. DOI: 10.3390/mi11040406. View

12.

Lashkaripour A, McIntyre D, Calhoun S, Krauth K, Densmore D, Fordyce P . Design automation of microfluidic single and double emulsion droplets with machine learning. Nat Commun. 2024; 15(1):83. PMC: 10761910. DOI: 10.1038/s41467-023-44068-3. View

13.

Gupta A, Sbragaglia M . Effects of viscoelasticity on droplet dynamics and break-up in microfluidic T-Junctions: a lattice Boltzmann study. Eur Phys J E Soft Matter. 2016; 39(1):6. DOI: 10.1140/epje/i2016-16006-9. View

14.

Battat S, Weitz D, Whitesides G . Nonlinear Phenomena in Microfluidics. Chem Rev. 2022; 122(7):6921-6937. DOI: 10.1021/acs.chemrev.1c00985. View

15.

Sakai A, Murayama Y, Yanagisawa M . Cyclic Micropipette Aspiration Reveals Viscoelastic Change of a Gelatin Microgel Prepared Inside a Lipid Droplet. Langmuir. 2020; 36(19):5186-5191. DOI: 10.1021/acs.langmuir.0c00428. View

16.

Lashkaripour A, Rodriguez C, Mehdipour N, Mardian R, McIntyre D, Ortiz L . Machine learning enables design automation of microfluidic flow-focusing droplet generation. Nat Commun. 2021; 12(1):25. PMC: 7782806. DOI: 10.1038/s41467-020-20284-z. View

17.

McIntyre D, Lashkaripour A, Fordyce P, Densmore D . Machine learning for microfluidic design and control. Lab Chip. 2022; 22(16):2925-2937. PMC: 9361804. DOI: 10.1039/d2lc00254j. View

18.

Song X, Loskutova K, Chen H, Shen G, Grishenkov D . Deriving acoustic properties for perfluoropentane droplets with viscoelastic cellulose nanofiber shell via numerical simulations. J Acoust Soc Am. 2021; 150(3):1750. DOI: 10.1121/10.0006046. View

19.

Del Giudice F, DAvino G, Maffettone P . Microfluidic formation of crystal-like structures. Lab Chip. 2021; 21(11):2069-2094. DOI: 10.1039/d1lc00144b. View

20.

McIntyre D, Lashkaripour A, Arguijo D, Fordyce P, Densmore D . Versatility and stability optimization of flow-focusing droplet generators quality metric-driven design automation. Lab Chip. 2023; 23(23):4997-5008. PMC: 10694034. DOI: 10.1039/d3lc00189j. View