PEER-REVIEWED PUBLICATION

2009

Cellular interfacial and surface tensions determined from aggregate compression tests using a finite element model

A tensile test divider icon

Brodland GW, Yang J, et al.

HFSP Journal

University of Waterloo

RESEARCH SUMMARY
This pioneering study quantified cellular interfacial and surface tensions by compressing spherical embryonic tissue aggregates between parallel plates and interpreting the resulting force–time data using a 3D finite element model. The work introduced quantitative relationships that allowed estimation of cytoplasmic viscosity, cell–cell interfacial tension, and cell–medium surface tension. Tests on chick embryonic mesencephalon, neural retina, liver, and heart tissues demonstrated that surface and cytoplasmic tensions vary by cell type and are key to understanding cell rearrangement, morphogenesis, and self-organization.
CellScale hexagons, without text

CELLSCALE INSTRUMENT USED

MicroSquisher

The study employed a custom parallel-plate compression instrument—later commercialized as the CellScale MicroTester—to measure the mechanical response of living embryonic tissue aggregates under controlled deformation. The setup included a laser displacement sensor and a flexible cantilever beam to derive compressive forces, enabling accurate measurement of aggregate deformation and viscoelastic relaxation. This prototype formed the foundation for modern MicroTester systems.
AUTHORS

G. Wayne Brodland; Justina Yang; Jen Sweny.

PUBLICATION DETAILS
JOURNAL

HFSP Journal

YEAR

2009

INSTITUTIONS

University of Waterloo

COUNTRIES

Canada

INSTRUMENT USED

MicroSquisher

TESTING METHODS

Compression TestingHydrated and Temperature Controlled TestingMicro-Mechanical TestingStress Relaxation TestingViscoelastic & Time-Dependent Testing

RESEARCH APPLICATIONS

MechanotransductionMicrotissue and Spheroid Mechanics

Related Publications:

Instrument Used:
Year:
Testing Method:
Research Application:
Country:

Biomechanical properties of the capsule and extracellular matrix play a major role during the Wolffian/epididymal duct development

Oliveira ECS, Hu P, et al.

Andrology

MicroSquisher

Compression TestingHydrated and Temperature Controlled TestingMicro-Mechanical Testing

ECM & Decellularized Matrix MechanicsReproductive and Fetal Membrane Mechanics

2025

Splitting the Difference: Genetically-Tunable Mycelial Films Using Natural Genetic Variations in Schizophyllum commune

Whabi V, Xu J

Journal of Bioresources and Bioproducts

MicroSquisher

Micro-Mechanical TestingTensile Testing

Material Fatigue and DurabilityMembranes and Thin Films MechanicsPolymers and Elastomers Testing

2025

Sequential Angiogenic–Osteogenic Coupling via a Spatiotemporally Graded Hydrogel Enables Vascularized Bone Organoids for Critical-Sized Calvarial Defect Reconstruction

Lu X, Wang F, et al.

Composites Part B: Engineering

MicroSquisher

Compression TestingHydrated and Temperature Controlled TestingMicro-Mechanical Testing

Bone Tissue Engineering & MechanicsCell Laden HydrogelsHydrogel Mechanical TestingInjectable & Regenerative BiomaterialsOrganoid and Tissue Mimetic SystemsVascular Tissue Engineering & Mechanics

2025

Contact Sales

Product of Interest:
CellScale hexagon shapes