Mechanical conditioning for mesenchymal stem cell rejuvenation

This technology uses mechanical force to rejuvenate aged stem cells. It enhances cell function, reduces aging markers, and improves DNA repair, making the cells more suitable for regenerative therapies.

Background

Mesenchymal stem cells (MSCs) hold immense promise for regenerative medicine due to their availability, multipotency, and immunomodulatory properties. They offer a potential solution for treating various diseases and repairing damaged tissues.

The demand for effective cell-based therapies is high, especially for patients with limited treatment options. However, the therapeutic efficacy of MSCs, particularly those derived from aged or diseased patients, is significantly hampered by cellular senescence. Senescent MSCs exhibit reduced proliferation, impaired differentiation potential, and diminished regenerative capacity.

Current approaches, including using allogeneic MSCs from young donors, are limited by immune rejection and the inherent challenges of senescence during in vitro expansion. Moreover, the molecular mechanisms driving MSC senescence are complex and multifactorial, making it difficult to develop targeted and effective interventions.

Technology description

This technology involves a method for rejuvenating mesenchymal stem cells (MSCs) obtained from older patients using a process called mechanical conditioning. This process involves applying controlled mechanical forces to the cells, mimicking the natural stretch experienced by the brachial artery.

Applying this specific physiological waveform at a 7.5% strain for several hours a week enhances cell proliferation and multipotency while reducing cellular senescence. This mechanical load triggers changes in gene expression, particularly activating proteins involved in managing oxidative stress and repairing DNA damage.

This technology differentiates itself by addressing a critical challenge in regenerative medicine: the decline in MSC functionality with age. Existing approaches often involve genetic manipulation or pharmaceutical treatments, which can have unpredictable side effects. This method offers a non-invasive, biophysical alternative by leveraging the cells’ natural mechano-transduction pathways.

The precise mechanical stimulation triggers specific cellular responses, leading to long-term improvements in MSC functionality without genetic or chemical alteration. This technology holds the potential to enhance the effectiveness of MSC-based therapies, particularly for older patients.

Benefits

• Rejuvenates mesenchymal stem cells (MSCs) from aged patients, improving their therapeutic potential
• Enhances MSC proliferation and overall cell culture expansion potential
• Improves MSC multipotency, increasing their ability to differentiate into other cell types
• Reduces cellular senescence in MSCs, mitigating age-related decline in regenerative properties
• Improves recognition and repair of damaged DNA, enhancing cellular health and stability
• Upregulates sirtuin expression, influencing pathways related to aging and senescence
• Enhances oxidative stress management, protecting cells from damage caused by reactive oxygen species
• Modifies chromatin accessibility and transcription factor binding, potentially reversing age-related gene expression patterns

Commercial applications

• Stem cell therapy
• Regenerative medicine
• Drug discovery
• Tissue engineering

Publication link

https://www.biorxiv.org/content/10.1101/2024.06.06.597781v1.full.pdf