Your search keyword '"John Larison"' showing total 2 results

1. Inherent interfacial mechanical gradients in 3D hydrogels influence tumor cell behaviors.

Author

Shreyas S Rao, Sarah Bentil, Jessica DeJesus, John Larison, Alex Hissong, Rebecca Dupaix, Atom Sarkar, and Jessica O Winter

Subjects

Medicine, Science

Abstract

Cells sense and respond to the rigidity of their microenvironment by altering their morphology and migration behavior. To examine this response, hydrogels with a range of moduli or mechanical gradients have been developed. Here, we show that edge effects inherent in hydrogels supported on rigid substrates also influence cell behavior. A Matrigel hydrogel was supported on a rigid glass substrate, an interface which computational techniques revealed to yield relative stiffening close to the rigid substrate support. To explore the influence of these gradients in 3D, hydrogels of varying Matrigel content were synthesized and the morphology, spreading, actin organization, and migration of glioblastoma multiforme (GBM) tumor cells were examined at the lowest (500 µm) gel positions. GBMs adopted bipolar morphologies, displayed actin stress fiber formation, and evidenced fast, mesenchymal migration close to the substrate, whereas away from the interface, they adopted more rounded or ellipsoid morphologies, displayed poor actin architecture, and evidenced slow migration with some amoeboid characteristics. Mechanical gradients produced via edge effects could be observed with other hydrogels and substrates and permit observation of responses to multiple mechanical environments in a single hydrogel. Thus, hydrogel-support edge effects could be used to explore mechanosensitivity in a single 3D hydrogel system and should be considered in 3D hydrogel cell culture systems.

Published

2012

2. Inherent interfacial mechanical gradients in 3D hydrogels influence tumor cell behaviors

Author

Sarah A. Bentil, Rebecca B. Dupaix, Atom Sarkar, Jessica O. Winter, John Larison, Alex Hissong, Jessica DeJesus, and Shreyas S. Rao

Subjects

Tumor Physiology, Cell Culture Techniques, 02 engineering and technology, Mechanotransduction, Cellular, Biochemistry, Extracellular matrix, Cell Movement, Molecular Cell Biology, Basic Cancer Research, Tumor Cells, Cultured, Morphogenesis, Biomechanics, Mechanotransduction, Cytoskeleton, 0303 health sciences, Multidisciplinary, Cell migration, Hydrogels, Anatomy, 021001 nanoscience & nanotechnology, Cellular Structures, Extracellular Matrix, Drug Combinations, Cellular Microenvironment, Oncology, Self-healing hydrogels, Medicine, Proteoglycans, Collagen, 0210 nano-technology, Research Article, Biotechnology, Stress fiber, Materials science, Science, Biophysics, Biomedical Engineering, Bioengineering, Cell Migration, macromolecular substances, complex mixtures, 03 medical and health sciences, Elastic Modulus, Cell Adhesion, Humans, Cell adhesion, Cell Shape, Biology, Actin, 030304 developmental biology, Cell Proliferation, Matrigel, technology, industry, and agriculture, Proteins, Actins, Cytoskeletal Proteins, Glass, Laminin, Glioblastoma, Developmental Biology

Abstract

Cells sense and respond to the rigidity of their microenvironment by altering their morphology and migration behavior. To examine this response, hydrogels with a range of moduli or mechanical gradients have been developed. Here, we show that edge effects inherent in hydrogels supported on rigid substrates also influence cell behavior. A Matrigel hydrogel was supported on a rigid glass substrate, an interface which computational techniques revealed to yield relative stiffening close to the rigid substrate support. To explore the influence of these gradients in 3D, hydrogels of varying Matrigel content were synthesized and the morphology, spreading, actin organization, and migration of glioblastoma multiforme (GBM) tumor cells were examined at the lowest (500 µm) gel positions. GBMs adopted bipolar morphologies, displayed actin stress fiber formation, and evidenced fast, mesenchymal migration close to the substrate, whereas away from the interface, they adopted more rounded or ellipsoid morphologies, displayed poor actin architecture, and evidenced slow migration with some amoeboid characteristics. Mechanical gradients produced via edge effects could be observed with other hydrogels and substrates and permit observation of responses to multiple mechanical environments in a single hydrogel. Thus, hydrogel-support edge effects could be used to explore mechanosensitivity in a single 3D hydrogel system and should be considered in 3D hydrogel cell culture systems.

Published

2012