Abstract
When \( \beta\) -lactoglobulin in low p H aqueous solutions is exposed to high temperature for extended time, spherulites composed of amyloid fibrils of the \( \beta\) -lactoglobulin protein form. Many of these spherulites have fibrils that radiate out from a centre and, under crossed polarisers, exhibit a symmetric Maltese Cross structure. However, a significant fraction (50 of the 101 observed spherulites) of \( \beta\) -lactoglobulin spherulites formed under these conditions demonstrate various forms of irregularity in apparent structure. The irregularities of spherulites structures were qualitatively investigated by comparing optical microscopy images observed under crossed polarisers to computationally produced images of various internal structures. In this way, inner spherulite structures are inferred from microscopy images. Modelled structures that were found to produce computed images similar to some of the experimentally viewed images include fibrils curving as they radiate from a single nucleation point; multiple spherulites nucleating in close proximity to one another; and fibrils curving in opposite directions above and below a single nucleation point.
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Domike, K.R., Hardin, E., Armstead, D.N. et al. Investigating the inner structure of irregular \( \beta\) -lactoglobulin spherulites. Eur. Phys. J. E 29, 173–182 (2009). https://doi.org/10.1140/epje/i2009-10465-y
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DOI: https://doi.org/10.1140/epje/i2009-10465-y