organ-Chip Consumable

Chip-S1® Stretchable Chip

The pioneering Organ-Chip design that started a revolution in human-relevant in vitro modeling

Overview

Recreate a more human-relevant microenvironment

Chip-S1 enables researchers to recreate the natural physiology and mechanical forces cells experience within the human body, such as blood flow and peristalsis.

Key Benefits

Tissue Crosstalk

Separate cell compartments enable seeding and media delivery for two different tissue types, while the porous membrane permits compartment crosstalk and cell migration.

Dynamic Fluid Flow

Fluid flow through the channels creates shear stress that drives cell maturation and improves functionality.

Cyclic Stretch

Tunable cyclic stretch recreates dynamic biomechanical functions, such as breathing and peristalsis.

Air-Liquid Interface

With independent control of flow in both channels, users can easily create an air-liquid interface for models such as lung or skin.

Diagram of Chip-S1

Overview Video

Get to Know Chip-S1

Learn how Chip-S1 enables users to model epithelial-endothelial interfaces with appropriate biomechanical forces such as fluid flow and stretch.

Chip-S1 Use Cases

Vagina-Chip

Understanding the Role of the Microbiome in Vaginal Health

Bacterial vaginosis (BV) is difficult to study under static cell culture conditions due to overgrowth of bacteria. By maintaining media flow, Organ-Chips enable the co-culture of epithelial cells and bacteria without leading to bacterial overgrowth. Additionally, the two-channel configuration enables the creation of an epithelial-stromal interface to enhance tissue maturation. Learn how researchers created a Vagina-Chip model that has the potential to be used as a preclinical tool in the validation of vaginal therapeutics for conditions such as BV.

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Lymphoid Follicle-Chip

Improving Vaccine Development

From discovery to licensure, vaccine development costs billions of dollars and has an average 94% chance of failure. Organ-Chips can help reduce this failure rate by enabling researchers to create a human-based model that incorporates peripheral immune cells, thus avoiding species translation issues. Additionally, researchers demonstrated that a Lymphoid Follicle-Chip can capture donor variability in antibody response to vaccination.

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Bone Marrow-Chip

Understanding Bone Marrow Pathophysiology

The inaccessibility of living bone marrow makes it difficult to study its pathophysiology and responses to stressors such as drugs, radiation, or genetic mutations. Organ-Chips provide researchers a window into this living niche environment. Researchers who used the Chip-S1 to create a Bone Marrow-Chip found that vascularization of the bone marrow tissue supported the differentiation and maturation of multiple blood cell lineages over 4 weeks while improving CD34+ cell maintenance for improved recapitulation of bone marrow injury.

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Part of the Human Emulation System®

The Human Emulation System is comprised of instruments, consumables, and software in a flexible, open format. The user-friendly platform gives researchers a window into the inner workings of human biology.

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FEATURED RESOURCE

Emulate Community Publications Digest: Summer 2024 Issue

Explore the myriad ways Chip-S1 has been used by the Emulate Community to develop novel models.