Grayson Minnick scite author profile

Cell–cell adhesions are often subjected to mechanical strains of different rates and magnitudes in normal tissue function. However, the rate-dependent mechanical behavior of individual cell–cell adhesions has not been fully characterized due to the lack of proper experimental techniques and therefore remains elusive. This is particularly true under large strain conditions, which may potentially lead to cell–cell adhesion dissociation and ultimately tissue fracture. In this study, we designed and fabricated a single-cell adhesion micro tensile tester (SCAµTT) using two-photon polymerization and performed displacement-controlled tensile tests of individual pairs of adherent epithelial cells with a mature cell–cell adhesion. Straining the cytoskeleton–cell adhesion complex system reveals a passive shear-thinning viscoelastic behavior and a rate-dependent active stress-relaxation mechanism mediated by cytoskeleton growth. Under low strain rates, stress relaxation mediated by the cytoskeleton can effectively relax junctional stress buildup and prevent adhesion bond rupture. Cadherin bond dissociation also exhibits rate-dependent strengthening, in which increased strain rate results in elevated stress levels at which cadherin bonds fail. This bond dissociation becomes a synchronized catastrophic event that leads to junction fracture at high strain rates. Even at high strain rates, a single cell–cell junction displays a remarkable tensile strength to sustain a strain as much as 200% before complete junction rupture. Collectively, the platform and the biophysical understandings in this study are expected to build a foundation for the mechanistic investigation of the adaptive viscoelasticity of the cell–cell junction.

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Nanosensors for single cell mechanical interrogation

Hang

Dong

et al. 2021

Biosensors and Bioelectronics

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Two‐Photon Polymerized Shape Memory Microfibers: A New Mechanical Characterization Method in Liquid

Minnick

Safa

Rosenbohm

et al. 2022

Adv Funct Materials

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Two-photon polymerization (TPP) is widely used to create 3D micro-and nanoscale scaffolds for biological and mechanobiological studies, which often require the mechanical characterization of the TPP fabricated structures. To satisfy physiological requirements, most of the mechanical characterizations need to be conducted in liquid. However, previous characterizations of TPP fabricated structures are all conducted in air due to the limitation of conventional micro-and nanoscale mechanical testing methods. In this study, a new experimental method is reported for testing the mechanical properties of TPP-printed microfibers in liquid. The experiments show that the mechanical behaviors of the microfibers tested in liquid are significantly different from those tested in air. By controlling the TPP writing parameters, the mechanical properties of the microfibers can be tailored over a wide range to meet a variety of mechanobiology applications. In addition, it is found that, in water, the plasticly deformed microfibers can return to their predeformed shape after tensile strain is released. The shape recovery time is dependent on the size of microfibers. The experimental method represents a significant advancement in mechanical testing of TPP fabricated structures and may help release the full potential of TPP fabricated 3D tissue scaffolds for mechanobiological studies.

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Two‐Photon Polymerized Shape Memory Microfibers: A New Mechanical Characterization Method in Liquid (Adv. Funct. Mater. 3/2023)

Minnick

Safa

Rosenbohm

et al. 2023

Adv Funct Materials

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Shape Memory Microfibers In article number 2206739, Lavrik, Gao, Yang, and co‐workers develop a new testing method for characterizing the mechanics and the shape memory dynamics of microstructures fabricated with two‐photon polymerization in a liquid environment. Testing results show that fabricated microfibers exhibit different mechanical properties and shape recovery in liquid and air environments, and these properties can be tuned by controlling the writing parameters.

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Grayson Minnick

High Throughput and Highly Controllable Methods for In Vitro Intracellular Delivery

Characterization of the strain-rate–dependent mechanical response of single cell–cell junctions

Nanosensors for single cell mechanical interrogation

Two‐Photon Polymerized Shape Memory Microfibers: A New Mechanical Characterization Method in Liquid

Two‐Photon Polymerized Shape Memory Microfibers: A New Mechanical Characterization Method in Liquid (Adv. Funct. Mater. 3/2023)

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