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Main Authors: Roldan, Elisa, Andrews, Kirstie, Richardson, Stephen M., Fatahian, Reyhaneh, Cooper, Glen, Erfani, Rasool, Sabir, Tasneem, Reeves, Neil D.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.04873
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author Roldan, Elisa
Andrews, Kirstie
Richardson, Stephen M.
Fatahian, Reyhaneh
Cooper, Glen
Erfani, Rasool
Sabir, Tasneem
Reeves, Neil D.
author_facet Roldan, Elisa
Andrews, Kirstie
Richardson, Stephen M.
Fatahian, Reyhaneh
Cooper, Glen
Erfani, Rasool
Sabir, Tasneem
Reeves, Neil D.
contents Electrospinning is a scalable technique for producing fibrous scaffolds with tunable micro- and nanoscale architectures for applications in tissue engineering, drug delivery, and wound care. While machine learning (ML) has been used to support electrospinning process optimisation, most existing approaches predict only mean fibre diameters, neglecting the full diameter distribution that governs scaffold performance. This work presents FibreCastML, an open, distribution-aware ML framework that predicts complete fibre diameter spectra from routinely reported electrospinning parameters and provides interpretable insights into process structure relationships. A meta-dataset comprising 68538 individual fibre diameter measurements extracted from 1778 studies across 16 biomedical polymers was curated. Six standard processing parameters, namely solution concentration, applied voltage, flow rate, tip to collector distance, needle diameter, and collector rotation speed, were used to train seven ML models using nested cross validation with leave one study out external folds. Model interpretability was achieved using variable importance analysis, SHapley Additive exPlanations, correlation matrices, and three dimensional parameter maps. Non linear models consistently outperformed linear baselines, achieving coefficients of determination above 0.91 for several widely used polymers. Solution concentration emerged as the dominant global driver of fibre diameter distributions. Experimental validation across different electrospinning systems demonstrated close agreement between predicted and measured distributions. FibreCastML enables more reproducible and data driven optimisation of electrospun scaffold architectures.
format Preprint
id arxiv_https___arxiv_org_abs_2601_04873
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle FibreCastML: An Open Web Platform for Predicting Electrospun Nanofibre Diameter Distributions
Roldan, Elisa
Andrews, Kirstie
Richardson, Stephen M.
Fatahian, Reyhaneh
Cooper, Glen
Erfani, Rasool
Sabir, Tasneem
Reeves, Neil D.
Machine Learning
Electrospinning is a scalable technique for producing fibrous scaffolds with tunable micro- and nanoscale architectures for applications in tissue engineering, drug delivery, and wound care. While machine learning (ML) has been used to support electrospinning process optimisation, most existing approaches predict only mean fibre diameters, neglecting the full diameter distribution that governs scaffold performance. This work presents FibreCastML, an open, distribution-aware ML framework that predicts complete fibre diameter spectra from routinely reported electrospinning parameters and provides interpretable insights into process structure relationships. A meta-dataset comprising 68538 individual fibre diameter measurements extracted from 1778 studies across 16 biomedical polymers was curated. Six standard processing parameters, namely solution concentration, applied voltage, flow rate, tip to collector distance, needle diameter, and collector rotation speed, were used to train seven ML models using nested cross validation with leave one study out external folds. Model interpretability was achieved using variable importance analysis, SHapley Additive exPlanations, correlation matrices, and three dimensional parameter maps. Non linear models consistently outperformed linear baselines, achieving coefficients of determination above 0.91 for several widely used polymers. Solution concentration emerged as the dominant global driver of fibre diameter distributions. Experimental validation across different electrospinning systems demonstrated close agreement between predicted and measured distributions. FibreCastML enables more reproducible and data driven optimisation of electrospun scaffold architectures.
title FibreCastML: An Open Web Platform for Predicting Electrospun Nanofibre Diameter Distributions
topic Machine Learning
url https://arxiv.org/abs/2601.04873