# Tension shapes memory: computational insights into neural plasticity

**Authors:** Ki Yun Lee, M. Taher A. Saif

PMC · DOI: 10.3389/fncom.2026.1737434 · Frontiers in Computational Neuroscience · 2026-02-11

## TL;DR

This paper explores how mechanical tension in neural networks affects learning and memory, showing that tension improves memory recall and cognitive functions.

## Contribution

A novel spiking neural network model integrating mechanical tension and synaptic plasticity to study cognitive functions.

## Key findings

- Increased tension improves memory recall speed by 67% and inter-regional synchrony by 17%.
- Reduced tension by 20% leads to a 31% decline in memory association performance.
- Optimal inhibition (20% inhibitory neurons) is crucial for tension-driven cognitive effects.

## Abstract

Mechanical forces have recently emerged as critical modulators of neural communication, yet their role in high-level cognitive functions remains poorly understood. Here, we present a biologically inspired spiking neural network model that integrates mechanical tension, vesicle dynamics, and spike-timing-dependent plasticity to examine how tension influences learning, memory, and cognitive operations such as pattern completion, projection, and association. We find that increased tension enhances synaptic efficiency by accelerating vesicle clustering and recovery, resulting in a 67% improvement in memory recall speed and a 17% increase in inter-regional synchrony during projection relative to relaxed states. Conversely, a 20% reduction in tension leads to a 31% decline in memory association performance, highlighting the tension-sensitive accessibility of stored information. The model further reveals that an appropriate balance of inhibition is essential for these tension-driven effects: networks with 20% inhibitory neurons achieve optimal spatial precision in memory encoding and recall, whereas insufficient inhibition allows tension-amplified excitation to spread uncontrollably and degrade recall fidelity. Together, these in silico findings position mechanical tension as a functional neuromodulator and suggest new directions for neuromorphic design and energy-efficient, living computing platforms.

## Full-text entities

- **Diseases:** Alzheimer's disease (MESH:D000544), amnesia (MESH:D000647), impaired memory recall (MESH:D008569), depression (MESH:D003866), dementia (MESH:D003704)
- **Chemicals:** glutamate (MESH:D018698), GABA (MESH:D005680), Ca2+ (-)
- **Species:** Mus musculus (house mouse, species) [taxon 10090], Drosophila melanogaster (fruit fly, species) [taxon 7227], Rattus norvegicus (brown rat, species) [taxon 10116], Homo sapiens (human, species) [taxon 9606]

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/PMC12932432/full.md

## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12932432/full.md

## References

63 references — full list in the complete paper: https://tomesphere.com/paper/PMC12932432/full.md

---
Source: https://tomesphere.com/paper/PMC12932432