logo
搜索
菜单

Isolation, Culture, Characterization, and Differentiation of Human Muscle Progenitor Cells from the Skeletal Muscle Biopsy Procedure

作者: Brandon J. Gheller*1, Jamie Blum*1, Sharon Soueid-Baumgarten2, Erica Bender1, Benjamin D. Cosgrove2, Anna Thalacker-Mercer1 1Division of Nutritional Sciences,Cornell University, 2Meinig School of Biomedical Engineering,Cornell University
简介:

Overview

This article presents techniques for isolating and characterizing human primary muscle progenitor cells (hMPCs) from skeletal muscle biopsy tissue. These methods enable researchers to investigate human myogenesis and skeletal muscle regeneration.

Key Study Components

Area of Science

  • Neuroscience
  • Cell Biology
  • Regenerative Medicine

Background

  • Human muscle progenitor cells play a crucial role in skeletal muscle regeneration.
  • Isolating these cells allows for the study of regenerative processes while considering donor variability.
  • Techniques for cell isolation must be reproducible to ensure optimal yield and purity.
  • Visual observation of the isolation steps can enhance understanding.

Purpose of Study

  • To isolate human muscle progenitor cells for research on muscle regeneration.
  • To analyze the proliferation and differentiation capabilities of these cells.
  • To relate findings to the overall skeletal muscle regenerative process.

Methods Used

  • Isolation of hMPCs from skeletal muscle biopsy tissue.
  • Characterization of the isolated cells.
  • Phenotypic analysis using small cell quantities.
  • Tracking proliferation and differentiation capabilities.

Main Results

  • Successful isolation of hMPCs from minimal tissue samples.
  • Characterization of cells demonstrates their potential for research applications.
  • Reproducibility of the method ensures reliable results.
  • Insights into the regenerative process of skeletal muscle are gained.

Conclusions

  • The techniques presented are effective for isolating and studying hMPCs.
  • These methods can advance understanding of muscle regeneration.
  • Future research can build on these findings to explore therapeutic applications.

Frequently Asked Questions

What are human muscle progenitor cells?
Human muscle progenitor cells are cells that contribute to the regeneration of skeletal muscle.
Why is donor variability important in this research?
Donor variability allows researchers to understand how different genetic backgrounds affect muscle regeneration.
What challenges are associated with isolating hMPCs?
Ensuring reproducibility in the isolation process is crucial for optimizing yield and purity.
How can these techniques be applied in future research?
These techniques can be used to explore therapeutic strategies for muscle degeneration diseases.
What is the significance of phenotypic analysis?
Phenotypic analysis helps in understanding the characteristics and capabilities of the isolated muscle progenitor cells.
Can these methods be adapted for other cell types?
While designed for hMPCs, the methods may be adapted for isolating other progenitor cells with similar characteristics.

We present techniques for isolating, culturing, characterizing, and differentiating human primary muscle progenitor cells (hMPCs) obtained from skeletal muscle biopsy tissue. hMPCs obtained and characterized through these methods can be used to subsequently address research questions related to human myogenesis and skeletal muscle regeneration.

标签: Human Muscle Progenitor Cells,    Skeletal Muscle Regeneration,    Phenotypic Analysis,    Cell Proliferation,    Differentiation Capabilities,    Biopsy Procedure,    Sterile Conditions,    Digestion Medium,    Trituration,    CD56 Positive Cells,    Pax7 Positive Cells,    Cell Purification,    Muscle Biopsy,   
Adult Mouse Digit Amputation and Regeneration: A Simple Model to Investigate Mammalian Blastema Formation and Intramembranous Ossification 10.3791/59749-v 09:17 min
Adult Mouse Digit Amputation and Regeneration: A Simple Model to Investigate Mammalian Blastema Formation and Intramembranous Ossification
Development of Targeting Induced Local Lesions IN Genomes (TILLING) Populations in Small Grain Crops by Ethyl Methanesulfonate Mutagenesis 10.3791/59743-v 08:36 min
Development of Targeting Induced Local Lesions IN Genomes (TILLING) Populations in Small Grain Crops by Ethyl Methanesulfonate Mutagenesis
Injecting Gryllus bimaculatus Eggs 10.3791/59726-v 08:49 min
Injecting Gryllus bimaculatus Eggs
DNAzyme-dependent Analysis of rRNA 2’-O-Methylation 10.3791/59700-v
DNAzyme-dependent Analysis of rRNA 2’-O-Methylation
Generation of Induced Neural Stem Cells from Peripheral Mononuclear Cells and Differentiation Toward Dopaminergic Neuron Precursors for Transplantation Studies 10.3791/59690-v 12:13 min
Generation of Induced Neural Stem Cells from Peripheral Mononuclear Cells and Differentiation Toward Dopaminergic Neuron Precursors for Transplantation Studies
Use of Atomic Force Microscopy to Measure Mechanical Properties and Turgor Pressure of Plant Cells and Plant Tissues 10.3791/59674-v 11:18 min
Use of Atomic Force Microscopy to Measure Mechanical Properties and Turgor Pressure of Plant Cells and Plant Tissues
Fast and Efficient Expression of Multiple Proteins in Avian Embryos Using mRNA Electroporation 10.3791/59664-v 09:40 min
Fast and Efficient Expression of Multiple Proteins in Avian Embryos Using mRNA Electroporation
Mapping the Emergent Spatial Organization of Mammalian Cells using Micropatterns and Quantitative Imaging 10.3791/59634-v
Mapping the Emergent Spatial Organization of Mammalian Cells using Micropatterns and Quantitative Imaging
返回顶部