📋 Summary

This study by Calvao, D. J. et al was published in Scientific Reports, 2025. It utilized Microtissues 3D Petri Dish® micro-molds for 3D cell culture, contributing to advances in neuroscience research.

🧠 Neuroscience

A brain cancer microtissue model for studying tumor cell and neural cell interac

Scientific Reports, 2025 — Calvao, D. J. et al
Citation:
Calvao, D. J. et al. A brain cancer microtissue model for studying tumor cell and neural cell interactions. Scientific Reports 2025

Research Overview

This publication by Calvao, D. J. et al represents important research in the field of neuroscience. Published in Scientific Reports, 2025, this work employed 3D Petri Dish® micro-mold technology from Microtissues to create uniform, reproducible 3D microtissues for their experimental studies.

🔬 3D Culture Approach

  • Utilized Microtissues 3D Petri Dish® micro-molds for reproducible 3D spheroid formation
  • Enabled physiologically relevant cell-cell interactions in a controlled 3D environment
  • Supported the study of complex biological processes that cannot be replicated in traditional 2D culture

How 3D Petri Dish® Enabled This Research

🟢 3D Petri Dish® Application

The researchers chose Microtissues 3D Petri Dish® micro-molds to generate uniform 3D microtissues, enabling more physiologically relevant experimental conditions compared to traditional 2D cultures.

  • Non-adhesive hydrogel micro-molds promoted self-assembly of cells into 3D spheroids
  • Uniform microtissue size ensured experimental reproducibility
  • Compatible with standard cell culture workflows and imaging techniques

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FAQs

What are 3D Petri Dish® micro-molds?

3D Petri Dish® micro-molds are non-adhesive hydrogel molds that allow cells to self-assemble into uniform, reproducible 3D microtissues (spheroids). They are compatible with standard cell culture protocols and support a wide range of cell types and applications.

Why use 3D cell culture for neuroscience research?

3D cell culture provides a more physiologically relevant environment compared to traditional 2D culture. Cells in 3D form natural cell-cell interactions, develop gradients of nutrients and oxygen, and better mimic in vivo tissue architecture — all critical for neuroscience studies.