The role of resistance exercise-induced local metabolic stress in mediating systemic health and functional adaptations: could condensed training volume unlock greater benefits beyond time efficiency?

Frontiers in Physiology, Journal Year: 2025, Volume and Issue: 16

Published: April 17, 2025

The majority of "specialised" exercise configurations (e.g., supersets, drop sets, blood flow restriction) are being assessed as "shortcuts" to hypertrophy and strength improvements. However, these advanced training techniques may also offer significant benefits for systemic health functional outcomes across recreational clinical populations via locally induced metabolic responses. Stress-regulating mechanisms known enhance the body's resilience by facilitating allostasis, process coordinating adaptive processes in reaction stressors such physical training. Yet, role local stress provoked resistance has not gained much research attention despite its wide potential. Positive effects only linked improved muscular endurance, primary secondary mechanisms, but release myokines, hormones, microRNAs, immune factors, inflammatory substances other endocrine molecules that initiate numerous health-promoting modifications on a level. Resistance strategies maximise accumulation metabolites well defined, although high volume, close proximity failure shorter rests seem be necessity. Additionally, restriction provides potent alternative inducing acidosis, thereby triggering several pathways associated with immunity function even remote muscle tissues. Future is warranted further explore techniques, approaches comparable mental those seen forms high-intensity interval heavy

Language: Английский

An in vitro model for studying crosstalk between muscle cells and neurons

Device, Journal Year: 2025, Volume and Issue: 3(1), P. 100655 - 100655

Published: Jan. 1, 2025

Language: Английский

Magnetic Actuation for Mechanomedicine

Advanced Intelligent Systems, Journal Year: 2024, Volume and Issue: unknown

Published: Nov. 20, 2024

In the perspective of this article, emergence materials and systems for magneto‐mechanical actuation in field mechanobiology is presented, their potential to promote advance biomedical research discussed. These materials, ranging from single particles compliant 2D substrates 3D scaffolds, enable mechanical modulation cells a remote, dynamic, reversible fashion. features represent major enabling researchers reproduce time‐evolving physiological pathological processes vitro transmit forces deformations activate cellular responses or directed cell migration. As smart platforms, magneto‐responsive may accelerate discovery mechanically mediated mechanisms as therapeutic targets. addition, low magnetic susceptibility biological tissues facilitate translation approaches vivo settings, opening new routes applications.

Language: Английский