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Machine learning-guided space-filling designs for high throughput liquid formulation development

Machine learning-guided space-filling designs for high throughput liquid formulation development
Machine learning-guided space-filling designs for high throughput liquid formulation development
Liquid formulation design involves using a relatively limited experimental budget to search a high-dimensional space, owing to the combinatorial selection of ingredients and their concentrations from a larger subset of available ingredients. This work investigates alternative shampoo formulations. A space-filling design is desired for screening relatively unexplored formulation chemistries. One of the few computationally efficient solutions for this mixed nominal-continuous design of experiments problem is the adoption of maximum projection designs with quantitative and qualitative factors (MaxProQQ). However, such purely space-filling designs can select experiments in infeasible regions of the design space. Here, stable products are considered feasible. We develop and apply weighted-space filling designs, where predictive phase stability classifiers are trained for difficult-to-formulate (predominantly unstable) sub-systems, to guide these experiments to regions of feasibility, whilst simultaneously optimising for chemical diversity by building on MaxProQQ. This approach is extendable to other mixed-variable design problems, particularly those with sequential design objectives.
Design of experiments, Liquid formulations, Machine learning, Phase stability
0098-1354
Chitre, Aniket
1427fd52-6201-45b8-ab21-df300a5ebc58
Semochkina, Dasha
011d4fa0-cf50-4739-890e-7f453027432f
Woods, Dave
ae21f7e2-29d9-4f55-98a2-639c5e44c79c
Lapkin, Alexei
b7143831-f788-4ce9-9cec-24e6fd74d396
Chitre, Aniket
1427fd52-6201-45b8-ab21-df300a5ebc58
Semochkina, Dasha
011d4fa0-cf50-4739-890e-7f453027432f
Woods, Dave
ae21f7e2-29d9-4f55-98a2-639c5e44c79c
Lapkin, Alexei
b7143831-f788-4ce9-9cec-24e6fd74d396

Chitre, Aniket, Semochkina, Dasha, Woods, Dave and Lapkin, Alexei (2025) Machine learning-guided space-filling designs for high throughput liquid formulation development. Computers and Chemical Engineering, 195, [109007]. (doi:10.1016/j.compchemeng.2025.109007).

Record type: Article

Abstract

Liquid formulation design involves using a relatively limited experimental budget to search a high-dimensional space, owing to the combinatorial selection of ingredients and their concentrations from a larger subset of available ingredients. This work investigates alternative shampoo formulations. A space-filling design is desired for screening relatively unexplored formulation chemistries. One of the few computationally efficient solutions for this mixed nominal-continuous design of experiments problem is the adoption of maximum projection designs with quantitative and qualitative factors (MaxProQQ). However, such purely space-filling designs can select experiments in infeasible regions of the design space. Here, stable products are considered feasible. We develop and apply weighted-space filling designs, where predictive phase stability classifiers are trained for difficult-to-formulate (predominantly unstable) sub-systems, to guide these experiments to regions of feasibility, whilst simultaneously optimising for chemical diversity by building on MaxProQQ. This approach is extendable to other mixed-variable design problems, particularly those with sequential design objectives.

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More information

Accepted/In Press date: 17 January 2025
e-pub ahead of print date: 18 January 2025
Published date: 22 January 2025
Keywords: Design of experiments, Liquid formulations, Machine learning, Phase stability

Identifiers

Local EPrints ID: 498613
URI: http://eprints.soton.ac.uk/id/eprint/498613
DOI: doi:10.1016/j.compchemeng.2025.109007
ISSN: 0098-1354
PURE UUID: c8a3d2f2-26e7-4095-8601-b4a7923f9b8d
ORCID for Dasha Semochkina: ORCID iD orcid.org/0000-0003-0607-5882
ORCID for Dave Woods: ORCID iD orcid.org/0000-0001-7648-429X

Catalogue record

Date deposited: 24 Feb 2025 17:40
Last modified: 22 Aug 2025 02:26

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Contributors

Author: Aniket Chitre
Author: Dasha Semochkina ORCID iD
Author: Dave Woods ORCID iD
Author: Alexei Lapkin

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