![Accelerate novel discoveries using RASTRUM™ 3D cell models](https://inventia.life/hubfs/Inventia_January2024/images/afce7b2d-9e73-423c-a00a-46ec60e2a5f2_multigel.webp)
Accelerate novel discoveries using RASTRUM™ 3D cell models
• Recapitulate complex tissue architectures containing multiple separate cell populations in a single well
• Perform cell signalling, interaction and migration assays easily and reproducibly
![Integrate RASTRUM™ 3D cell models with existing assays and protocols](https://inventia.life/hubfs/Inventia_January2024/images/2490e5ba-252b-4812-a83e-5b790b741477_martrigel_comparison.webp)
Integrate RASTRUM™ 3D cell models with existing assays and protocols
• No autofluorescence in RASTRUM™ Matrices, allowing for easy collagen I staining
• No 2D monolayer formation in RASTRUM™ 3D cell models
![Tune the extracellular matrix to create relevant cellular phenotypes](https://inventia.life/hubfs/Inventia_January2024/images/ba6c8794-1c00-4f27-832b-753f55744422_comparison_adhesion%2Bu87.webp)
Tune the extracellular matrix to create relevant cellular phenotypes
• Tune matrix stiffness, protein and peptide content in RASTRUM™ Matrices to recapitulate your target cellular phenotype
• Avoid uncontrolled fibroblast activation in RASTRUM™ Matrices, which is commonly observed in basement membrane extract
• No matrix batch-to-batch variability, resulting in meaningful, reproducible and standardised experiments
RASTRUM™ 3D cell models have been used by
![Peter Mac](https://inventia.life/hubfs/Inventia_January2024/images/Peter%20Mac.webp)
![Garvan](https://inventia.life/hubfs/Inventia_January2024/images/Garvan.webp)
![CCI](https://inventia.life/hubfs/Inventia_January2024/images/CCI.webp)
![Phenovista](https://inventia.life/hubfs/Inventia_January2024/images/Phenovista.webp)
![ANU CTD RGB](https://inventia.life/hubfs/Inventia_January2024/images/ANU%20CTD%20RGB.webp)
![RCSI University Of Medicine And Health Sciences](https://inventia.life/hubfs/Inventia_January2024/images/RCSI%20University%20Of%20Medicine%20And%20Health%20Sciences.webp)
Discover more
![Enabling high throughput drug discovery in 3D cell cultures through a novel bioprinting workflow](https://inventia.life/hubfs/Inventia_January2024/images/877c84d4-a149-428f-a986-f4ae3dfd6a57_SLAS%2Btechnology_Square_Preview.png)
Enabling high throughput drug discovery in 3D cell cultures through a novel bioprinting workflow
SLAS Technology | February 2022
![High throughput characterization of advanced 3D liver models for in vitro hepatotoxicity studies](https://inventia.life/hubfs/Inventia_January2024/images/1cfb37a8-6783-4cc4-8c5e-d2eb3abad209_Liver%2BPoster_Square_Preview.png)
High throughput characterization of advanced 3D liver models for in vitro hepatotoxicity studies
Poster
![Generation and analysis of 3D cell culture models for drug discovery](https://inventia.life/hubfs/Inventia_January2024/images/9e321e50-2923-40a7-a011-4d108ebd7549_Eur%2BJ%2B_Square_Preview.png)
Generation and analysis of 3D cell culture models for drug discovery
European Journal of Pharmaceutical Sciences | May 2021
![Orthogonal Projection Cyan](https://inventia.life/hs-fs/hubfs/Inventia_January2024/images/0287f236-ec43-48fc-8412-8f181673d5ea_ME20230311PE1-ABC2-6-50x-HS-01-Airyscan%2BProcessing-Stitching-Scene-6-TR6-C06-Orthogonal%2BProjection-cyan_c1-3.webp?width=2000&height=2000&name=0287f236-ec43-48fc-8412-8f181673d5ea_ME20230311PE1-ABC2-6-50x-HS-01-Airyscan%2BProcessing-Stitching-Scene-6-TR6-C06-Orthogonal%2BProjection-cyan_c1-3.webp)
Discuss your next project
Tell us how we can help