Organotypic Cultures of Adult Human Cortex as an <em>Ex vivo</em> Model for Human Stem Cell Transplantation and Validation

Sara Palma-Tortosa; Raquel Mart&#237;nez-Curiel; Constanza Aretio-Medina; Natalia Avaliani; Zaal Kokaia

doi:10.3791/64234

JoVE Journal
Neuroscience

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JoVE Journal Neuroscience

Organotypic Cultures of Adult Human Cortex as an Ex vivo Model for Human Stem Cell Transplantation and Validation

成人皮层的器官型培养作为人类干细胞移植和验证的离体模型

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07:16 min

December 9, 2022

DOI: 10.3791/64234-v

Sara Palma-Tortosa¹, Raquel Martínez-Curiel¹, Constanza Aretio-Medina¹, Natalia Avaliani², Zaal Kokaia¹

¹Laboratory of Stem Cells and Restorative Neurology, Lund Stem Cell Center,Lund University, ²Lund Stem Cell Center,Lund University

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Overview

This study details a novel methodology for long-term organotypic cultures of adult human cortex and ex vivo intracortical transplantation of induced pluripotent stem cell-derived cortical progenitors. The approach allows for the investigation of stem cell therapies in a human-to-human context, addressing challenges faced in prior animal model studies for neurodegenerative disorders.

Key Study Components

Area of Science

Neuroscience
Stem Cell Biology
Neurodegeneration

Background

Current therapies often fail in clinical translation due to species differences.
Organotypic cultures offer a platform for testing cellular interactions within a human system.
There is a critical need to enhance understanding of human neural circuitry.
Observations of functional recovery are necessary for therapeutic advancements.

Purpose of Study

To establish a methodology for studying grafted and host cell interactions.
To assess the viability and functionality of transplanted cells in a human model.
To ultimately improve functional recovery post-brain damage through enhanced therapy testing.

Methods Used

Organotypic cultures of adult human cortex were utilized.
Induced pluripotent stem cell-derived cortical progenitors were transplanted ex vivo.
Key procedures included tissue preparation, culture maintenance, and assessment of cellular function after transplantation.
Critical timelines involved immediate processing of tissue post-collection for optimal viability.
Detailed procedures for culturing and transplanting cells were followed to ensure successful integration.

Main Results

Successful transplantation resulted in the survival and maturation of grafted cells.
Grafted cells exhibited complex neuronal activity and integration into host tissue.
Post-transplantation, cells displayed membrane potentials and synaptic activity indicating functional integration.
Microglial response showed a transition from resting to activated states, influencing overall tissue health.

Conclusions

This study demonstrates the feasibility of using human organotypic cultures to investigate stem cell therapies.
The findings contribute to understanding neuronal mechanisms relevant to human brain damage and recovery.
Insights gained may inform future therapeutic strategies for neurodegenerative conditions.

Frequently Asked Questions

What are the advantages of using organotypic cultures?

Organotypic cultures allow for the assessment of human-to-human cellular interactions, providing insights that are more relevant than those obtained from rodent models.

How is the human adult cortex prepared for culture?

Tissue is collected from patients, equilibrated, and then sliced into coronal or sagittal sections for culture.

What outcomes can be measured from this model?

Outcomes include neuronal survival, differentiation, synaptic activity, and microglial response, reflecting the health of the tissue.

How can this method be applied to other studies?

The methodology can be adapted for various types of neuronal or glial cells and can be used to evaluate the efficacy of different therapeutic approaches.

What are the key limitations of this study?

Key limitations may include the variable preservation of tissue and the challenges associated with maintaining long-term culture viability.

What can be learned about human neuronal circuitry through this study?

The study enables a deeper understanding of human neural circuitry interactions and functionality, essential for advancing treatment approaches for neurodegenerative diseases.

该协议描述了成人皮层的长期器官型培养与诱导多能干细胞衍生皮质祖细胞的离体皮质内移植相结合，这提供了一种新方法来进一步测试基于干细胞的治疗人类神经退行性疾病。

迄今为止，人类成人皮层的器官型培养物是测试受损皮层干细胞疗法的唯一系统，可以研究人类移植细胞和人类宿主细胞之间的相互作用。由于啮齿动物和人类细胞之间的差异，在动物模型中测试的疗法在转化为临床环境时通常会失败。在这里，我们可以在人与人的环境中研究移植细胞、存活、分化和功能。

这种方法将帮助我们了解神经回路在人脑中的运作方式，并将刺激这些知识转化为临床环境，以改善脑损伤后的功能恢复。演示该程序的将是来自我实验室的博士生Raquel Martinez-Curiel和硕士生Costanza Aretio-Medina。首先，在通风罩下的细胞培养实验室中使用镊子将培养插入物放入六孔板中。

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