Development of Magnetocaloric Wax Composites for Biodegradable Membranes for Microfluidic Platforms

Abstract

In recent years, there has been growing interest in the magnetocaloric effect (MCE) which is a magneto-thermodynamic phenomenon observed in certain magnetic materials. MCE materials undergo temperature changes when subjected to magnetic fields. Researchers are now exploring the possibilities of utilizing this material in biomedical application technologies, as they offer the potential for non-invasive control of their properties through external magnetic fields. However, there is a lack of research on suitable magnetic compositions that exhibit desired magnetic properties for medical purposes, while ensuring no adverse effects on the cells.

This master project explores the potential of a magnetocaloric (Mn,Fe)2(P,Si)-based compound as a biodegradable membrane for multi-cell separation in organ-on-chip platforms. Mn0.65Fe1.30Si0.37P0.65 compound was selected due to its sharp phase transition characteristics and tunable Curie temperature (Tc), which enable self-regulation of temperature within the therapeutic range, thus preventing potential damage to living cells. The synthesized Mn0.65Fe1.30Si0.37P0.65 compound exhibited a transition temperature of 316 K (43°C) with particle sizes ranging from 1-5 µm. A magnetocaloric wax-based composite was synthesized by integrating these particles with a wax component. Characterization under alternating magnetic fields (AMF) showed a significant temperature rise with higher magnetic concentrations and field amplitudes. At an applied AMF of 9 mT and a frequency of 244 kHz, a sample containing 15 vol.% magnetic particles stabilized at 44°C, effectively maintaining controlled temperatures within the therapeutic range (42-47°C) and efficiently melting the wax without harming living cells. Water absorption tests and SEM imaging further demonstrated the composite's low water permeability and minimal development of microcracks over time. These findings validate the potential of magnetocaloric materials with adjustable Curie temperatures for precise self-regulation of temperature in biomedical applications. The observed high heating efficiency and prevention of overheating offer promising opportunities for controlled thermal activation processes across various biomedical fields.