Andre R Montes scite author profile

Andre R Montes

2Publications

2Citation Statements Received

207Citation Statements Given

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192

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University of California, Berkeley

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Design of a flexing organ-chip to model in situ loading of the intervertebral disc

McKinley

Montes

Wang

et al. 2022

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The leading cause of disability of all ages worldwide is severe lower back pain. To address this untreated epidemic, further investigation is needed into the leading cause of back pain, intervertebral disc degeneration. In particular, microphysiological systems modeling critical tissues in a degenerative disc, like the annulus fibrosus (AF), are needed to investigate the effects of complex multiaxial strains on AF cells. By replicating these mechanobiological effects unique to the AF that are not yet understood, we can advance therapies for early-stage degeneration at the cellular level. To this end, we designed, fabricated, and collected proof-of-concept data for a novel microphysiological device called the flexing annulus-on-a-chip (AoC). We used computational models and experimental measurements to characterize the device’s ability to mimic complex physiologically relevant strains. As a result, these strains proved to be controllable, multi-directional, and uniformly distributed with magnitudes ranging from [Formula: see text]% to 12% in the axial, radial, and circumferential directions, which differ greatly from applied strains possible in uniaxial devices. Furthermore, after withstanding accelerated life testing (66 K cycles of 10% strain) and maintaining 2000 bovine AF cells without loading for more than three weeks the AoC proved capable of long-term cell culture. Additionally, after strain (3.5% strain for 75 cycles at 0.5 Hz) was applied to a monolayer of AF cells in the AoC, a population remained adhered to the channel with spread morphology. The AoC can also be tailored for other annular structures in the body such as cardiovascular vessels, lymphatic vessels, and the cervix.

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Multiscale Computational Framework to Investigate Integrin Mechanosensing and Cell Adhesion

Montes

Gutiérrez

Tepole

et al. 2023

Preprint

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Integrin mechanosensing plays an instrumental role in cell behavior, phenotype, and fate by transmitting mechanical signals that trigger downstream molecular and cellular changes. For instance, force transfer along key amino acid residues can mediate cell adhesion. Disrupting key binding sites within α5β1 integrin's binding partner, fibronectin (FN) diminishes adhesive strength. While past studies have shown the importance of these mechanosensing residues, the molecular dynamics by which they maintain adhesion locally and throughout the cell remains less explored. Here, we present a multiscale mechanical model to investigate the mechanical coupling between integrin nanoscale dynamics and whole-cell adhesion dynamics. The model's force outputs were consistent with past atomic force microscopy and fluorescence resonance energy transfer measurements from literature. The model also confirmed past studies that implicate two key sites within FN that maintain cell adhesion: the synergy site and RGD motif. Our study contributed to our understanding of molecular mechanisms by which these sites collaborate to mediate whole-cell integrin adhesion dynamics. Specifically, we showed how FN unfolding, residue binding/unbinding, and molecular structure contribute to α5β1-FN's nonlinear force-extension behavior during stretching. These dynamics could be used to understand cell differentiation via mechanosensitive sites or limit the spread of metastatic cells through targeted protein design.

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Andre R Montes

Design of a flexing organ-chip to model in situ loading of the intervertebral disc

Multiscale Computational Framework to Investigate Integrin Mechanosensing and Cell Adhesion

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