Featuring: Mantarray Platform | iPSC-derived Skeletal Muscle Myoblasts | Neuromuscular Junction Model (Released February 2025)

• Dexamethasone induces dose-dependent, reproducible, and reversible reductions in force generation in engineered skeletal muscle tissues (EMTs).

• Both iPSC-derived and primary human EMTs showed significant atrophy, with primary cells losing all measurable contractile force at high doses.

• Recovery after dexamethasone removal was slow and incomplete over a 21-day period.

• The Mantarray Platform provides a robust model for studying atrophic signaling and testing potential therapeutic strategies.

Featuring: Mantarray Platform | iPSC-derived Skeletal Muscle Myoblasts | Neuromuscular Junction Model (Released February 2024)

This Application Note Covers:

• Easy creation of 3D iPSC-derived Neuromuscular Junction model with automated functional output.

• NMJ-specific inhibition of muscular contractility through BoNT activity.

• Dose-dependent response to BoNT with EC50 calculation for potency assay applications.

Featuring: Mantarray Platform | iPSC-derived Skeletal Muscle Myoblasts | Neuromuscular Junction Model (Released February 2024)

This Application Note Covers:

• Facile co-culture of iPSC-derived neurons & skeletal muscle into a 3D NMJ model.

• Scalable, reproducible & reliable formation of 3D human NMJs with long in vitro lifetimes.

• Turnkey, longitudinal collection of NMJ functional data, backed by histological evidence.

Featuring: Mantarray Platform (Released January 2024)

This Application Note Covers:

• Turnkey scalable production of human 3D engineered heart tissues.

• Label-free automated capture and analysis of functional data across 24 tissues in parallel.

• In vitro validation of clinical drug toxicity and efficacy using human cell models.

• Identification of optimal dosing regimens to minimize functional side-effects.

Featuring: NanoSurface Plates (Released December 2018)

In this application note, the differential impact of the chemical and structural components of the Extracellular Matrix (ECM) was investigated and compared to the structure and organization of HeLa cells.

Featuring: NanoSurface Plates (Released November 2018)

Nanotopographically patterned transparent multiwell microelectrode arrays (MEAs) were used to study neuronal structure, network connectivity, and sensitivity to synaptic blockers in cultured hPSCneuron monolayers.