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Ice-Templated and Cross-Linked Amyloid Fibril Aerogel Scaffolds for Cell Growth Gustav Nyström, Wye-Khay Fong, and Raffaele Mezzenga Biomacromolecules, Just Accepted Manuscript • DOI: 10.1021/acs.biomac.7b00792 • Publication Date (Web): 17 Aug 2017 Downloaded from http://pubs.acs.org on August 18, 2017

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Ice-Templated and Cross-Linked Amyloid Fibril

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Aerogel Scaffolds for Cell Growth

3 Gustav Nyström‡, Wye-Khay Fong‡§ and Raffaele Mezzenga*,‡

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‡

ETH Zurich, Department of Health Science & Technology, Schmelzbergstrasse 9, 8092 Zurich,

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Switzerland §

Drug Delivery, Disposition and Dynamics, Monash Institute of Pharmaceutical Sciences,

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Monash University, 381 Royal Parade, Parkville, Victoria 3052, Australia.

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Keywords: self-assembly, templated assembly, amyloid fibril, 3D scaffold, cell, microscopy

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*Email: [email protected]

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ABSTRACT

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Amyloid fibrils prepared from β-lactoglobulin were used to form freeze-dried and cross-linked

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aerogels. By varying the fibril concentration and freezing gradient, it was possible to control the

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pore structure and elastic modulus of the aerogels over one order of magnitude from ~2 to ~200

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kPa. Using butane tetracarboxylic acid as cross-linker these aerogels maintained their monolithic

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shape in aqueous conditions displaying elastic behavior and a modulus in the range of 4–40 kPa.

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When explored as scaffolds for cell growth, the amyloid fibril aerogels demonstrated

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biocompatibility and led to the successful penetration and permeation of two epithelial cell lines

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(Caco-2 and HT29) throughout the scaffold. These soft, elastic and water-stable biomaterials

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expand the scope of amyloid fibril aerogels, making them suitable for wet state applications such

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as heterogeneous catalysis, purification membranes and 3D matrices for cell growth.

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1. INTRODUCTION

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Water is the most important liquid available; it is critical to sustain life and is highly useful for

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dissolving, dispersing, processing and distributing media. Water also has structural properties,

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showing regular ordering,1 as well as an accessible liquid to solid transition, both of which can

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be exploited on the nanoscale. By controlling the depth and direction of the freezing gradient,

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different forms and shapes of solid, amorphous or crystalline2 ice can form. During the growth of

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ice crystals, solutes3 or colloidal particles4 dispersed in the aqueous phase are expelled from the

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ice phase and concentrated in regions surrounding the growing ice front. This phenomenon has

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been used to template and control the pores in composite materials,5 to modify the texture of

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foods,6 as well as a way to control the aggregation7 and to induce phase separation between

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colloids.8

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Amyloid fibrils are semi-flexible anisotropic colloids formed through self-assembly from protein

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aggregates. They were initially discovered in vivo, in relation to neurodegenerative disorders

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including Alzheimer's and Parkinson's disease, but have recently attracted increasing attention in

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bio-functional materials such as catalytic scaffolds, hormone storage and functional coatings.9–11

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These fibrils are known to self-assemble into nematic liquid crystal phases12,13 and to form

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physical hydrogels at appropriate fibril and salt concentrations.14,15 These gels are typically weak

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with elastic moduli in the order of 10–50 Pa and while they maintain their structural integrity in

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solution, they are difficult to handle without causing the gel network to break. One option to

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improve the mechanical properties of the gels is to use chemical cross-links. While there are

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many different alternatives to form the cross-links, a particularly appealing route is to use a

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solid-state reaction approach,16,17 allowing for the homogenous distribution of cross-linker

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throughout the gel network, and to go through a freezing and drying step before finally re-

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dispersing the gel in the medium of interest.

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Cells are known to naturally adhere to amyloid fibrils,18,19 and the existing literature includes the

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use of α-synuclein amyloid fibril hydrogels to promote stem cell differentiation to neurons20 and

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the exploration of heat-induced gelation of lysozyme amyloid fibril hydrogels as cell scaffolds.21

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Lysozyme fibrils have also been used as two-dimensional cell supports for the study of

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controlled cell attachment,22 spreading and growth of cells,23 as well as substrates for primary

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human trabecular bone-derived pre-osteoblast cells,24 further demonstrating the viability of these

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fibrils for supported cell growth. Other, more specific peptide-based systems have also been used

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to study the interaction between amyloid fibrils and cells. For instance, thin films of TTR1-

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cycloRGDfK peptide fibrils demonstrated cell adhesion and spreading of cells,25 and hydrogels

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formed using fibrils based on the C-terminal amyloid β-protein (Aβ42) were used for cell culture

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and stem cell differentiation.26

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Here, we use amyloid fibrils prepared from β-lactoglobulin (BLG) as starting colloidal particles

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and a controlled freezing, drying and cross-linking protocol to prepare porous structural amyloid

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fibril aerogel scaffolds. By changing the particle concentration and morphology of the scaffolds,

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it is possible to control the mechanical stiffness of these materials within one order of magnitude

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reaching final hydrated stiffness values up to ~40 kPa, three orders of magnitude higher than

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traditional amyloid hydrogels. The chemical cross-linking renders these materials highly stable

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in water, opening up a wide range of post-functionalization treatments and wet state applications

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such as filters, purification membranes27 and catalysis substrates.28 In this paper, we explore

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these porous structural amyloid materials as scaffolds for cell growth using cells from two

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different cell lines. The results, evaluated using laser scanning confocal microscopy and cell

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viability assays, show that these materials are biocompatible, making them good candidates for

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applications as cell growth scaffolds, drug delivery systems and artificial implant materials.

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2. EXPERIMENTAL SECTION

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Materials. Biopure β-lactoglobulin (BLG) monomer (lot JE 003−6−922) was obtained from

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Davisco Foods International, Inc. (Le Sueur, MN). 1,2,3,4 Butanetetracarboxylic acid (BTCA)

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and sodium hypophosphite, NaH2PO2 (SHP) was purchased from Sigma Aldrich. For the cell

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culture and DOX release studies, Dulbecco’s modified Eagle’s media (DMEM), fetal bovine

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serum (FBS), non-essential amino acids (NEAA) and Penicillin-Streptomycin (5,000 U/mL)

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(pen/strep) were acquired from Gibco, Life Technologies, Switzerland. 24 well plates were

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purchased from Bioswisstec AG, Switzerland and the µ-Slide 8 Well, ibiTreat from Vitaris AG,

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Switzerland. The HT29 and Caco2 cell lines were a generous gift from Dr. Tomás de Wouters of

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the Food Biotechnology group at ETH Zürich.

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Preparation of amyloid fibrils. Amyloid fibrils were prepared according to a previous

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protocol.12 In short, 20 g of BLG monomer were dissolved in 180 mL deionized water (Milli-Q

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purification system, Millipore). The pH was set to 4.6 followed by centrifugation (20 000 RCF

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for 15 min) to remove larger protein aggregates or denatured protein particles. The supernatant

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was collected and the pH was readjusted to 2 followed by filtration through a 0.22 µm cellulose

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filter and finally dialyzed (6000-8000 MWCO, Spectrum Laboratories) against pH 2 Milli-Q

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water and subsequently Milli-Q water for 5 days with daily bath changes. Following the

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purification, the protein monomer solution was incubated at 2 wt% monomer concentration, pH

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2 and 90 °C for 5 hours. During the incubation, the protein monomer unfolds, hydrolyzes and

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self-assembles into amyloid fibrils.

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Preparation of cross-linked amyloid fibril scaffolds. Amyloid fibril dispersions (at

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concentrations of 1–4 wt%) were mixed with dry powder of BTCA and NaH2PO2 at a fibril to

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BTCA weight ratio of 1:0.2 and a NaH2PO2 to BTCA weight ratio of 2:1. For the Amyloid-196

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samples, aliquots of 90 µL were put in 7 mm diameter and 2 mm height stainless steel cylindrical

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molds and frozen using liquid nitrogen. For the Amyloid-20 samples, aliquots of 90 µL were put

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in 7 mm diameter and 2 mm height PDMS molds placed on a stainless-steel bottom plate,

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covered with an isolating PDMS sheet and put to freeze at -20 °C. Following freezing, the

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samples were freeze dried (FreeZone 4.5, Labconco, US) and the dried samples were heat cured

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at 150 °C for 3 min. Prior to use, the scaffolds were thoroughly washed using Milli-Q water to

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remove any remaining chemicals as well as UV sterilized before the cell experiments.

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Characterization. Scanning Electron Microscopy (SEM) was performed using a Leo 1530

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Gemini microscope (Zeiss) operated at 1 kV acceleration voltage and a working distance of 5

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mm. Thin sections of the scaffolds were cut with a razor blade and attached to aluminum stubs

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using adhesive carbon tape and a ~3 nm layer of platinum was deposited on the samples prior to

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imaging. Transmission Electron Microscopy (TEM) was performed using a Morgagni 268 (FEI)

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microscope operated at 100 kV acceleration voltage. The samples were prepared by placing 4 µL

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of 1 g L-1 dispersion on carbon coated copper grids (Quantifoil). After an adsorption time of 60 s

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the grids were blotted, rinsed 2 times with pH 2 Milli-Q water and dried at ambient conditions.

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Fourier Transform Infrared Spectroscopy (FTIR) was performed using a Varian 640

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spectrometer equipped with a Golden Gate diamond ATR stage. Mechanical testing was

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performed using a Z010 (Zwick) operating in compression mode, using a 10 N load cell and a

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compression rate corresponding to 10% of the initial specimen height per min. Compressive

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stress-strain curves were plotted and the Young's modulus was determined from the slope of the

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low strain region. The density and porosity of the amyloid fibril scaffolds were calculated by

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gravimetric determination of the aerogel weight using a balance and careful measurement of the

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aerogel volume using optical microscopy imaging. By taking only the mass given by the balance

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into consideration we obtain the apparent density of the scaffolds as the mass of the solid divided

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by the geometric volume of the scaffolds. The porosity is calculated according to: φ = 1−

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where ρ app is the apparent scaffold density and ρ fib is the density of the amyloid fibrils

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measured by helium pycnometry (Accupyc 1340, Micromeritics) to 1.3 g cm-3.

ρapp ρ fib

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Cell Studies. Prior to seeding, the amyloid fibril scaffolds were sterilized by exposure to UV

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light for 1 h and then hydrated and rinsed with a large volume of autoclaved Milli-Q water to

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ensure clean and sterile samples. Individual hydrated scaffolds were then placed into separate

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wells and rinsed twice with cell culture medium.

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Caco-2 human epithelial colorectal adenocarcinoma and HT29

human colorectal

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adenocarcinoma monolayer cells were cultured in DMEM, supplemented with 1% v/v NEAA

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(nonessential amino acids, Gibco), 1% (v/v) Penicillin Streptomycin, and 10% (v/v) fetal bovine

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serum, (FBS, Gibco) at 37 °C with 10% CO2 to 80% confluence. Cells were harvested by

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trypsinization (2 mL) and then diluted to 10 mL media followed by centrifugation (105 RCF for

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5 min). Processed cells were re-suspended, counted and then seeded into each well at a density of

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10 000 cells/well in 1 mL of media in a 24 well plate or 3000 cells/well in 300 µL media in the

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8-well µ-Slides. For the wells that contained fibril scaffolds, cells were seeded at the same

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density into the fibril network. The plates were then incubated overnight at 37 °C with 10% CO2.

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After 24 h incubation, non-adherent cells were removed by rinsing the samples in fresh media.

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The culture media was changed daily. At 4 days after seeding, the fibril scaffolds were removed

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from the cell culture medium and subsequently then prepared for either viability assays or for

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confocal fluorescence imaging.

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Cell Viability Assay and Imaging. Cell viability was investigated utilizing a lactate

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dehydrogenase (LDH) assay (CytoTox 96® Non-Radioactive Cytotoxicity Assay, Promega,

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Switzerland). Data were further analyzed using a one-way ANOVA statistical test (Holm-Sidak

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method) in order to determine statistical significance (p < 0.05) between the groups.

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For imaging, cells were labeled using a LIVE/DEAD viability/cytotoxicity staining kit (L-

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3224, Molecular Probes) where the fluorophores, calcein-AM and ethidium homodimer-1, was

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used to stain live and cells respectively. Cells were imaged using an LSM 780 laser scanning

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confocal microscope (Zeiss). A 488 nm argon laser was used as excitation source and the emitted

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photons were collected in the wavelength interval 493–540 nm (live cells) and 614–702 nm

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(dead cells).

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3. RESULTS AND DISCUSSION

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Amyloid fibril scaffolds were prepared as schematically described in Figure 1A. First BLG

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monomers were self-assembled into high aspect ratio fibrils12 as imaged by TEM in Figure 1C.

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Thereafter, ice-templating, using two different freezing gradients, followed by freeze-drying was

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used to prepare porous, dry amyloid fibril aerogel scaffolds. Since untreated freeze-dried fibrils

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immediately re-disperse when added to water, we used a solid-state cross-linking process to

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stabilize the scaffolds. For this reaction, BTCA29 was added to the fibril dispersion together with

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SHP which was used as a catalyst30 prior to templating and drying to allow a good distribution of

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cross-linker among the fibrils. This means that, in the heat curing step following the freeze-

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drying, they were in immediate proximity to the fibrils allowing for an efficient and

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homogeneous cross-linking of the fibril scaffold. Re-dispersibility tests as well as SEM were

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used to determine the optimal weight ratio of amyloid fibril to cross-linker (1:0.2), as well as the

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optimal heat curing time (180 s at 150 °C) (Figure S1–S3 in the Supporting Information). By

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varying the freezing temperature, and thereby the freezing gradient, it is possible to control the

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shape and size of the ice crystals formed31 and with that, the final pores created in the material

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(Figure 1B,E). In this study, the concentration of amyloid fibrils in the dispersion has been varied

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and two different freezing gradients (-20 °C and -196 °C) were utilized to create 6 different

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material combinations (Figure S4). In general, the larger freezing gradient produced stratified

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pores with a smaller pore size than the lower freezing gradient sample, which showed a more

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cellular structure. The apparent densities and porosities were found to be similar for both

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freezing gradients and increased proportionally to the total concentration of fibrils used in the

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materials (ρapp ~ 20, ~30 and ~50 mg cm-3 and ϕ ~ 96–98% for 1, 2 and 4 wt% materials

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respectively). Closer examination of the pore walls by high resolution SEM revealed that the

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morphology of the intertwined amyloid fibril network remained, as seen by the appearance of

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fibril aggregates on the otherwise smooth pore surface, after the scaffold ice-templating and

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cross-linking (Figure 1D).

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Figure 1. Schematics of amyloid fibril scaffold preparation and electron microscopy of amyloid

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fibrils and amyloid fibril scaffolds. A, Schematic of amyloid fibril cross-linking mechanism and

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preparation of scaffolds templated by ice crystals. B, Scanning electron micrograph of a dry 2

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wt% amyloid fibril aerogel scaffold prepared using a -20 °C freezing gradient. C, Transmission

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electron micrograph of amyloid fibrils. D, Scanning electron micrograph at high magnification

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showing the fibrillar structure of the pore walls of the fibrillar aerogel scaffolds. E, Scanning

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electron micrograph of a dry 2 wt% amyloid fibril aerogel scaffold prepared using a -196 °C

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freezing gradient.

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The solid-state cross-linking reaction used here has the advantage of requiring a minimum

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amount of post treatment (only short heat treatment) of the already formed amyloid aerogel

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scaffolds. Therefore, the ice-templated pore morphology is intact and the cross-linking as such

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does not influence the resulting macro-gel structure. From the re-dispersibility tests (Figure S1–

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S2), it is already evident that the cross-linking has a clear stabilizing effect on the amyloid

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aerogel scaffolds. In fact, at sufficient amount of cross-linker relative to fibril (≥ 1:0.2) and heat

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curing time (≥ 60 s), the scaffolds are stable in water for more than two years. FT-IR in

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attenuated total reflection (ATR) mode was performed to further verify the cross-linking

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mechanism. In Figure 2A, the spectra of an amyloid fibril scaffold is compared to BTCA cross-

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linked scaffolds for an increasing amount of heat treatment in the full wavenumber range

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considered in the experiment. Upon cross-linking, the most clearly seen differences occur in the

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lower wavenumber region between 1200 and 800 cm-1. Assigning the low wave number peaks

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first, the vibration at 810 cm-1 represents the H-P-H wagging mode of the SHP and the vibrations

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at 1040 cm-1 and 1080 cm-1 represent C-O-C stretching vibrations of the cyclic anhydride formed

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as an intermediate during the BTCA cross-linking reaction.32,33 The other bands are overlapping

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with the bands from the protein, and are therefore difficult to uniquely assign. In order to observe

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the spectroscopic differences more clearly, Figure 2B compares the reference sample with the

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sample used in this study (3 min heat treatment) before and after washing, where data is in the

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range 1800 to 600 cm-1 and normalized by the intensity of the common peak around 1635 cm-1.

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Firstly, it is noted that the washing step effectively removes the peaks related to the SHP and

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intermediate structures of BTCA still remaining in the sample. These results are, however, not

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quantitative and while BTCA has been found non-toxic up to an intake of 500 mg/kg/day based

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on in vivo studies in rats34 and SHP is frequently used as a food additive, further work using

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NMR should be performed to verify the absence of residual chemicals before advancing the use

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of the materials in vivo. An increased intensity shoulder for the vibrations at 1720 cm-1 is also

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observed, representing the ester carbonyl bands formed as a result of the cross-linking reaction.35

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To resolve this peak more clearly, the difference spectra of the cross-linked samples and

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reference sample are plotted in Figure 2C. From this, a gradual increase in intensity for

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increasing heat treatment time can be seen around 1700 cm-1, indicating an increasing

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concentration of carboxylic acid groups35 resulting from the attached BCTA crosslinker

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molecules. Still, considering the sufficient integrity in the re-dispersibility tests, 3 min heat

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treatment was used for the samples in this study to also minimize the potential degrading effects

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of the heat treatment on the amyloid fibrils.

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Figure 2. FTIR spectra of amyloid fibrils before and after cross-linking with BTCA. A, FTIR

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spectra in the range 4000–600 cm-1 with broken axis at the spectral region blocked by the ATR

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crystal for untreated amyloid fibrils (black line) and BTCA cross-linked amyloid fibrils with

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increasing heat curing times. B, FTIR data normalized by the 1635 cm-1 peak for amyloid fibrils

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before (black line), after cross-linking (red line) and after cross-linking and washing (dotted red

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line). C, Difference FTIR spectra in the range 1800–1650 cm-1 for increasing heat curing times.

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The mechanical performance of the amyloid fibril aerogel scaffold was furthermore evaluated

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using compression tensile testing. Figure 3A shows representative compressive stress strain

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curves for the two different freezing gradients. Interestingly, at the same total fibril concentration

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these curves display a different behavior. The Amyloid-20 sample has a higher stiffness than the

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Amyloid-196 sample, and follows a qualitatively different compression pattern. This is attributed

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to the differences in microstructure between the samples (Figure 1B,E) where the more evenly

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distributed cellular like structure of Amyloid-20 is expected to be more efficient in distributing

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the initial load on the sample, deforming first by cell wall bending (initial linear region) followed

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by cell wall buckling (plateau like region).36 This behavior is different compared to the more

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sheet like morphology of the Amyloid-196 samples allowing an easy compression of the parallel

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layers. At sufficient compression, however, the initial microstructure no longer matters and the

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two samples follow a similar slope defined by the amount of fibrils present in the materials,

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indicating a similar compressed microstructure in the two samples. Figure 3B shows the elastic

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modulus for the different sample types as a function of aerogel density, ρ. For both samples, the

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stiffness increases with the increased concentration of fibrils as expected. The increase follows a

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general scaling behavior, ‫ߩ~ܧ‬ఈ , where an exponent α of ∼1 and ∼1.8 was found for Amyloid-20

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and Amyloid-196 respectively. There are, to our knowledge, no comparable data for amyloid

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fibrils, however the same exponent of 1.8 was previously observed for liquid nitrogen frozen and

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freeze-dried nanocellulose foams.37 To evaluate the mechanical performance of these samples at

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conditions more relevant for biological applications, mechanical compression measurements

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were also performed in PBS buffer solution, see Figure 3C. The elastic modulus was evaluated

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from the stress-strain curves after a 24 h equilibration in PBS buffer. For all fibril concentrations,

17

a lower stiffness was obtained, as expected, based on the plasticizing effect of the water. The

18

data also indicate a slight difference in the scaling exponent of the modulus as a function of

19

density for the two sample types, where α of ∼1.3 and ∼1.7 was found for Amyloid-20 and

20

Amyloid-196 respectively. Even though these differences should be treated cautiously based on

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the limited amount of data points available, the behavior is interesting since it suggests that the

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microstructural differences observed in the dry state also lead to different trends in how the

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modulus scales with fibril concentration in the wet state. Overall, the different sample

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morphologies and fibril concentrations investigated here clearly show that it is possible to

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control the stiffness of the scaffold, and attain values varying within one order of magnitudes

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from ~4 to ~40 kPa. This range matches well to that of stiffer tissues such as fibrotic wound

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tissue, muscle and cartilage suggesting good mechanical compatibility to these biological

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systems.38

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Figure 3. Mechanical properties of the amyloid fibril aerogel scaffolds. A, Compressive stress

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strain curves representative for the amyloid fibril scaffolds in dry state prepared using a -20 °C

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(black line) and -196 °C (red line) freezing gradient. B–C, Young's moduli extracted from the

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slope of the initial linear part of the compressive stress strain curves for varying amyloid fibril

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concentrations measured in dry state and equilibrated in PBS solution respectively. The data is

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presented as arithmetic means and standard deviations (n=3).

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To evaluate the performance of the amyloid aerogel scaffolds for cell growth, Caco-2 human

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epithelial colorectal adenocarcinoma and HT29 human colorectal adenocarcinoma monolayer

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cells were seeded into the aerogel scaffolds and incubated for 4 days. Confocal microscopy using

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live/dead staining (Calcein AM and Ethidium homodimer-1 fluorophore for live and dead cells

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respectively) was thereafter used to qualitatively monitor the cell viability (see Figure 4). From

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the surface images in Figure 4A,B it is clear that the majority of cells thrived in these conditions

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as shown by the live stain (green channel), and only in rare occasions do we see single dead cells

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(red channel). To investigate cell viability in the bulk of the samples, confocal images were

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acquired at different sample depths measured from the sample surface plane, see Figure 4C and

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Supporting Information Figure S5. From these images, where the transmitted channel is overlaid

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onto the green and red fluorescent channels, it is clear that cells are also alive at depths down to

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~250 µm in the sample after which it becomes difficult to filter out the fluorescence signals from

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the cells. This observation is consistent with the average size of the two cell types considered

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here (see further discussion below) being smaller than the average pore sizes of the scaffolds, i.e.

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the cells have room to penetrate into the interior of the scaffolds.

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Biomacromolecules

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Figure 4. Laser scanning confocal microscopy of the amyloid fibril scaffolds following cell

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growth. A–B, Surface images of Caco-2 (A) and HT29 (B) cells grown on the Amyloid-20 2wt%

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scaffold. C, Slices of the scaffold at different depths from the surface showing growth of HT29

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cells in the bulk of an Amyloid-20 1 wt% scaffold. The cells were stained using a Live/Dead

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staining kit and pixels presented as green and red corresponds to living and dead cells

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respectively. In C the green and red channel are overlaid on a channel showing the light

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transmitted through the sample.

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To quantitatively evaluate the amount of living cells in the different amyloid fibril aerogel

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scaffolds, cell viability was investigated utilizing a lactate dehydrogenase (LDH) assay and the

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results were expressed as the amount of living cells compared to cellular growth within the well

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Biomacromolecules

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in the absence of the amyloid fibrils on the cell culture plate, see Figure 5. The results show that,

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in general, a high number of cells thrived when incubated within the scaffolds, with on average,

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a better performance for the Caco-2 cells compared to the HT29 cells was observed. This may be

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attributed to the differences in size and ultrastructural features of the two colorectal

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adenocarcinoma cell lines. The average size of HT29 and Caco-2 cells are 16.6 ± 0.17 µm39 and

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12.4 ± 0.4 µm40 respectively. Additionally, both cell lines form epithelial monolayers in vitro,

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and tumors in vivo,41 however, enterocytic differentiation of the cells results in different external

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features, specifically, HT-29 cells excrete mucin whereas Caco-2 cells do not, which could also

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affect the attachment of the cells to the amyloid scaffolds. Nonetheless, for all scaffolds a cell

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survival rate above 80% was achieved, demonstrating a good biocompatibility with these

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epithelial cell lines. We also note that there are small variations within the different scaffolds, in

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particular, in the growth of HT29 cells, where growth in the Amyloid-20 4wt% is significantly

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greater than the 1wt% Amyloid-20 and 196 scaffolds. The increasing cell survival observed for

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the HT29 cell growth in Amyloid-20 furthermore indicates that appropriate scaffold pore sizes

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were maintained at all fibril concentrations in these samples in contrast to the Amyloid-196

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samples where this trend was absent.

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These cross-linked nanomaterials have potential as scaffolds for tissue engineering. To date,

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proposed materials have been based on natural and synthetic polymers, materials that have been

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designed to induce molecular biorecognition as the cells respond to their microenvironment.42

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These nanostructured materials need to permit cell penetration and proliferation, nutrient and

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waste product permeation and new capillary network formation as directed by the exposed

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surface area and porosity of the materials.43 Every tissue requires a defined structure matrix

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design with specific material properties, thus the development of materials whose mechanical

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Biomacromolecules

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and chemical properties can be tuned on the time and length scales of cell development,

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exogenously by the user, or endogenously by the cells are desired for the investigation of cellular

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processes. This research demonstrates the first instance of using cross-linked amyloid fibril

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aerogel materials as stable, cost effective and biocompatible scaffolds for cell culture. As these

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nanomaterials are formed by hydrolyzable elements,44 it is expected that the amyloid fibril

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aerogels will be affected by biological components; cells will produce and secrete enzymes and

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other proteins that could modify the fibril microstructure. Ideally, materials used as 3D cell

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culture scaffolds will allow cells to adhere and communicate with one another, and eventually

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degrade and shape according to their final location. In this short term study, the microstructure of

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the fibrils has allowed for cellular proliferation, however, more long term studies would be

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required to determine the effect of biological interactions upon these aerogels in order to fully

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assess their usability as 3D cell culture scaffolds when integrated in vivo. It was also found that

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changing the fibril concentration and freezing rate during preparation furthermore allows tuning

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the pore morphology, density and consequently mechanical stiffness of the scaffolds. This work

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hence provides a route forward for the continued exploration of amyloid fibril aerogels with

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tailored physical properties as scaffolds for cell growth.

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Figure 5. Cell survival data for cells grown within the cross-linked amyloid fibril scaffolds. A–

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B, Cell survival presented as percentage of living cells compared to a PBS buffer reference for

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Caco-2 and HT29 cells respectively (data are n=3,± SEM). Overall, there is significantly greater

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cellular growth of the Caco-2 cells than the HT29 cells in the scaffolds (p