# Exploring New Ways to Analyze Data on the Spontaneous Physical Activity of Rodents Through a Weighing Balance

**Authors:** Pedro Paulo Menezes Scariot, Ivan Gustavo Masselli dos Reis, Walter Aparecido Pimentel Monteiro, Maria Clara dos Reis, Vanessa Bertolucci, Fulvia Barros Manchado-Gobatto, Claudio Alexandre Gobatto, Leonardo Henrique Dalcheco Messias

PMC · DOI: 10.3390/s25113290 · Sensors (Basel, Switzerland) · 2025-05-23

## TL;DR

Researchers built a low-cost system using Arduino to measure rodent activity and found new ways to analyze the data, which could improve research and veterinary practices.

## Contribution

A novel, low-cost system for measuring rodent spontaneous physical activity and new analytical methods for interpreting the data.

## Key findings

- A cost-effective weighing balance using Arduino and iron plates successfully measured rodent spontaneous physical activity.
- New analytical methods like Mean of Weight Changes (MWC) and coefficient of variation in weight changes proved valid for SPA assessment.
- SPA domains classified based on activity levels aligned with expected patterns during dark and light phases.

## Abstract

What are the main findings?
We showed that it is possible to develop a cost-effective and robust SPA measurement system using user-friendly Arduino-based instrumentation.We analyzed SPA data in ways never explored before, adapting mathematical strategies, exploring SPA on a minute-by-minute basis, and classifying it into four distinct domains.

We showed that it is possible to develop a cost-effective and robust SPA measurement system using user-friendly Arduino-based instrumentation.

We analyzed SPA data in ways never explored before, adapting mathematical strategies, exploring SPA on a minute-by-minute basis, and classifying it into four distinct domains.

What are the implications of the main finding?
By offering a measurement method based on accessible instrumentation, we are contributing to the advancement of SPA-related research.Our expectation is that constant SPA monitoring could become a standard practice in both scientific research and veterinary settings.

By offering a measurement method based on accessible instrumentation, we are contributing to the advancement of SPA-related research.

Our expectation is that constant SPA monitoring could become a standard practice in both scientific research and veterinary settings.

Background: Weight-based methods can be cost-effective and practical for measuring spontaneous physical activity (SPA) in laboratory animals, but their adoption and exploration of analyses remain limited. Methods: We demonstrate the construction of a balance using accessible components (iron plates and open-source Arduino® electronics) and provide detailed instructions to enable others to build their own systems. Additionally, we propose new analytical strategies, such as using the Mean of Weight Changes (MWC), assessing the dispersion of weight changes, and classifying SPA into domains, to enhance data interpretation. Results: The construction of the weighing balance using accessible components proved to be feasible, and the balance demonstrated sensitivity in distinguishing high SPA under experimental conditions known to modulate it (dark/light phases and small vs. large cages). Regarding the analyses, we were able to confirm that MWC analysis is a valid measure of SPA. Furthermore, the coefficient of variation in weight changes could be used as a complementary analysis to MWC. The proposed SPA domains also proved to be valid, as they aligned with the understanding that rodents spend a greater proportion of time in the higher SPA domains during the dark phase, while lower SPA domains predominate during the light phase. Conclusions: Our findings reinforce the robustness and validity of our weighing balance, designed using a low-cost setup based on iron plates and open-source Arduino® electronics.

## Full-text entities

- **Chemicals:** iron (MESH:D007501)

## Full text

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## Figures

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## References

49 references — full list in the complete paper: https://tomesphere.com/paper/PMC12157805/full.md

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Source: https://tomesphere.com/paper/PMC12157805