Morphology, energetics and growth kinetics of diphenylalanine fibres

Phillip Mark Rodger; Caroline Montgomery; Giovanni Costantini; Alison Rodger

doi:10.1039/d0cp05477a

Morphology, energetics and growth kinetics of diphenylalanine fibres

Phillip Mark Rodger, Caroline Montgomery, Giovanni Costantini^*, Alison Rodger^*

^*Corresponding author for this work

Chemistry

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

2 Downloads (Pure)

Abstract

Diphenylalanine (FF) has been shown to self-assemble from water into heterogeneous fibres that are among the stiffest biomaterials known. How and why the fibres form has, however, not been clear. In this work, the nucleation and growth of FF fibres was investigated in a combined experimental and theoretical study. Scanning electron microscopy and optical microscopy showed FF fibre morphology to be hollow tubes of varying widths with occasional endcaps. Molecular dynamics simulations of FF nanostructures based on the bulk crystalline geometry demonstrated that axial growth stablilises the fibres and that structures with different widths show similar stabilities, in accord with the wide range of fibre widths observed experimentally. Linear dichroism (LD) spectroscopy was used to determine the thermal stability of the fibres, showing that FF solutions are fully monomeric at 70 °C and that fibres begin to form at ∼40 °C upon cooling. The LD kinetic studies indicated a nucleation-driven assembly with subsequent fibre growth, but a secondary nucleation process is required to explain the data.

Original language	English
Pages (from-to)	4597-4604
Number of pages	8
Journal	Physical Chemistry Chemical Physics
Volume	23
Issue number	8
Early online date	5 Feb 2021
DOIs	https://doi.org/10.1039/d0cp05477a
Publication status	Published - 28 Feb 2021

Bibliographical note

Funding Information:
Financial support from the Engineering and Physical Sciences Research Council (EPSRC, grant EP/F500378/1) for the MOAC Doctoral Training Centre is gratefully acknowledged.

Publisher Copyright:
© the Owner Societies 2021.

ASJC Scopus subject areas

General Physics and Astronomy
Physical and Theoretical Chemistry

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RodgerP2021MorphologyFinal published version, 2.28 MBLicence: Creative Commons: Attribution (CC BY)

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title = "Morphology, energetics and growth kinetics of diphenylalanine fibres",

abstract = "Diphenylalanine (FF) has been shown to self-assemble from water into heterogeneous fibres that are among the stiffest biomaterials known. How and why the fibres form has, however, not been clear. In this work, the nucleation and growth of FF fibres was investigated in a combined experimental and theoretical study. Scanning electron microscopy and optical microscopy showed FF fibre morphology to be hollow tubes of varying widths with occasional endcaps. Molecular dynamics simulations of FF nanostructures based on the bulk crystalline geometry demonstrated that axial growth stablilises the fibres and that structures with different widths show similar stabilities, in accord with the wide range of fibre widths observed experimentally. Linear dichroism (LD) spectroscopy was used to determine the thermal stability of the fibres, showing that FF solutions are fully monomeric at 70 °C and that fibres begin to form at ∼40 °C upon cooling. The LD kinetic studies indicated a nucleation-driven assembly with subsequent fibre growth, but a secondary nucleation process is required to explain the data.",

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AU - Montgomery, Caroline

AU - Costantini, Giovanni

AU - Rodger, Alison

N1 - Funding Information: Financial support from the Engineering and Physical Sciences Research Council (EPSRC, grant EP/F500378/1) for the MOAC Doctoral Training Centre is gratefully acknowledged. Publisher Copyright: © the Owner Societies 2021.

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N2 - Diphenylalanine (FF) has been shown to self-assemble from water into heterogeneous fibres that are among the stiffest biomaterials known. How and why the fibres form has, however, not been clear. In this work, the nucleation and growth of FF fibres was investigated in a combined experimental and theoretical study. Scanning electron microscopy and optical microscopy showed FF fibre morphology to be hollow tubes of varying widths with occasional endcaps. Molecular dynamics simulations of FF nanostructures based on the bulk crystalline geometry demonstrated that axial growth stablilises the fibres and that structures with different widths show similar stabilities, in accord with the wide range of fibre widths observed experimentally. Linear dichroism (LD) spectroscopy was used to determine the thermal stability of the fibres, showing that FF solutions are fully monomeric at 70 °C and that fibres begin to form at ∼40 °C upon cooling. The LD kinetic studies indicated a nucleation-driven assembly with subsequent fibre growth, but a secondary nucleation process is required to explain the data.

AB - Diphenylalanine (FF) has been shown to self-assemble from water into heterogeneous fibres that are among the stiffest biomaterials known. How and why the fibres form has, however, not been clear. In this work, the nucleation and growth of FF fibres was investigated in a combined experimental and theoretical study. Scanning electron microscopy and optical microscopy showed FF fibre morphology to be hollow tubes of varying widths with occasional endcaps. Molecular dynamics simulations of FF nanostructures based on the bulk crystalline geometry demonstrated that axial growth stablilises the fibres and that structures with different widths show similar stabilities, in accord with the wide range of fibre widths observed experimentally. Linear dichroism (LD) spectroscopy was used to determine the thermal stability of the fibres, showing that FF solutions are fully monomeric at 70 °C and that fibres begin to form at ∼40 °C upon cooling. The LD kinetic studies indicated a nucleation-driven assembly with subsequent fibre growth, but a secondary nucleation process is required to explain the data.

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Morphology, energetics and growth kinetics of diphenylalanine fibres

Abstract

Bibliographical note

ASJC Scopus subject areas

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