📋 Summary

This study by Ip, B. C. et al was published in 2018. It utilized Microtissues 3D Petri Dish® micro-molds for 3D cell culture, contributing to advances in developmental biology research.

🔬 Developmental Biology

Perfused Organ Cell-Dense Macrotissues Assembled from Prefabricated Living Micro

2018 — Ip, B. C. et al
Citation:
Ip, B. C. et al. Perfused Organ Cell-Dense Macrotissues Assembled from Prefabricated Living Microtissues. Advanced Biosystems 2, 1800076 (2018). --- PAGE 23 ---

Research Overview

This publication by Ip, B. C. et al represents important research in the field of developmental biology. Published in 2018, 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 developmental biology 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 developmental biology studies.