# Active Force Dynamics in Red Blood Cells Under Non‐Invasive Optical Tweezers

**Authors:** Arnau Dorn, Clara Luque‐Rioja, Macarena Calero, Diego Herráez‐Aguilar, Francisco Monroy, Niccolò Caselli

PMC · DOI: 10.1002/advs.202514778 · Advanced Science · 2025-12-22

## TL;DR

A non-invasive method uses optical tweezers and microscopy to study the mechanical forces and energy in red blood cells, revealing how their metabolism affects their behavior.

## Contribution

A minimally invasive method to quantify active forces and energy in red blood cells using optical tweezers and high-speed imaging.

## Key findings

- Membrane softening increases fluctuations and energy dissipation in red blood cells.
- The method enables differentiation of metabolic and structural states via fluctuation-force signatures.
- The approach provides a framework for detecting biomechanical dysfunction in diseases.

## Abstract

Red blood cells (RBCs) sustain mechanical stresses associated with microcirculatory flow through ATP‐driven plasma membrane flickering. This is an active phenomenon driven by motor proteins that regulate interactions between the spectrin cytoskeleton and the lipid bilayer; it is manifested in RBC shape fluctuations reflecting the cell's mechanical and metabolic state. Yet, direct quantification of the forces and energetic costs underlying this non‐equilibrium behavior remains challenging due to the invasiveness of existing techniques. Here, a minimally invasive method that combines bead‐free, low‐power optical tweezers with high‐speed video microscopy is employed to track local membrane forces and displacements in single RBCs during the same time window. This independent dual‐channel measurement enables the construction of a mechano‐dynamic phase space for RBCs under different chemical treatments, which allows for differentiating between metabolic and structural states based on their fluctuation‐force signatures. Quantification of mechanical work during flickering demonstrates that membrane softening enhances fluctuations while elevating energy dissipation. The proposed optical tweezers methodology provides a robust framework for mapping the active mechanics of living cells, enabling precise probing of cellular physiology and detection of biomechanical dysfunction in diseases.

A non‐invasive method combines low‐power optical tweezers with high‐speed microscopy to simultaneously monitor local membrane forces and displacements in single human red blood cells. This dual‐channel approach reveals a mechano‐dynamic signature that correlates the cell's metabolic state with its mechanical activity. This energetic framework serves as an early, pre‐morphological biomarker for subclinical hematological disorders.

## Linked entities

- **Proteins:** beta-Spec (beta Spectrin)
- **Chemicals:** ATP (PubChem CID 5957)
- **Species:** Homo sapiens (taxon 9606)

## Full-text entities

- **Chemicals:** lipid (MESH:D008055), ATP (MESH:D000255)

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12915208/full.md

## References

40 references — full list in the complete paper: https://tomesphere.com/paper/PMC12915208/full.md

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Source: https://tomesphere.com/paper/PMC12915208