This article has been reviewed according to Science X's editorial process and policies. Editors have highlighted the following attributes while ensuring the content's credibility:

fact-checked

trusted source

proofread

New study could change assumptions about helmet safety

Study Could Change Assumptions about Helmet Safety
The model comprises different parts such as the skull, cerebrum, cerebellum, pituitary gland, and brain stem along with subarachnoid space and other cavities filled with fluid particles. Additionally, displayed is half of the skull to give better insight into its structure. The helmet included in the model has two layers; an outer hard-shell cover, colored blue, for protection, and inner padding, highlighted in yellow, for comfort purposes. Credit: Applied Sciences (2023). DOI: 10.3390/app13074544

A new study led by researchers at New York Institute of Technology College of Osteopathic Medicine (NYITCOM) could change public perceptions about helmet safety.

Helmets, which are proven to prevent and head wounds, are no doubt critical for safety. However, there is much debate about the extent to which they are capable of mitigating the effects of concussions. The hard-shelled, heavily padded used by many of today's athletes, , and industrial workers have been much adapted since early helmet models, which lacked inner padding. But do these design enhancements provide additional protection?

That's the question that NYITCOM researchers, led by biomedical engineer and Assistant Professor Milan Toma, Ph.D., address in a new study published in Applied Sciences.

During a concussion, forces from the initial hit cause the brain to move rapidly back and forth (oscillate) within the skull and make contact with skull bones. This brain-skull interaction can damage brain chemicals and tissues, especially if multiple interactions occur. Cerebrospinal fluid (CSF), which is found in the central brain cavities and space surrounding the brain and spinal cord, cushions the brain and protects it from hitting the skull. However, as one of Toma's previous studies indicated, if subsequent hits occur in quick succession, the fluid loses its protective abilities and the brain incurs more stress with each successive skull oscillation.

While no helmet can fully prevent a concussion, some researchers, including Toma, hypothesize that helmet design can play a role in limiting concussion severity. The latest advancements in helmet design have shifted away from the conventional hard-shell and extensively padded helmets. Instead, they employ inventive materials and construction methods, with an emphasis on minimizing forces caused by head rotations during and after impacts. Experts believe that these forces are primarily responsible for concussions, as also demonstrated by Toma's earlier studies. Nevertheless, conventional helmets continue to be widely used across various sports disciplines, especially recreational ones like cycling and skateboarding, due to the exorbitant cost of the newer designs.

"Our new study may have implications for future helmet design and calls into question current assumptions regarding the best way to protect soldiers and athletes from concussions," says Toma, whose research largely focuses on how fluids in the human body respond to forces.

Using 3D models, Toma and his fellow researchers, including NYITCOM students Faiz Syed and Elisabeth Frankini, as well as Research Technician Kelsi Hurdle, simulated brain-skull interactions under conditions resembling a low-speed, head-on collision. This force of impact is similar to the collisions experienced by athletes in contact sports and bicycle accidents. The simulation's conditions also accounted for CSF presence and the features found in many of today's helmets: a hard exterior with soft inner padding.

The simulations projected multiple direct brain-skull interactions following the initial hit. In other words, the current helmet design did little to limit severity. The CSF's ability to provide natural protection diminished with each successive skull oscillation, an outcome consistent with Toma's earlier research.

"These smaller back-and-forth motions may seem insignificant compared to the first one, however, we showed that they can still cause serious damage," the researchers write. "As these subsequent head movements occur, they compromise the ability of CSF inside the skull to prevent contact between the brain and skull bones."

Their findings also support a 2020 experimental study by another institution, which compared modern military helmets with the unpadded helmets used during World War I. Surprisingly, that study found that the historical helmets may have had an advantage in protecting from concussions when relying solely on .

The NYITCOM authors conclude their new research by calling for additional studies aimed at developing advanced helmet designs for better protection against concussions.

However, they make it known that using a helmet—even one with some limitations—is still better than not wearing any head protection at all.

Other co-authors include Jodan Garcia, D.P.T., of Byrdine F. Lewis College of Nursing and Health Professions at Georgia State University, and Rosalyn Chan-Akeley, M.D., of the Lang Research Center at New York-Presbyterian Hospital Queens.

More information: Faiz Syed et al, Cushioning Effect of Conventional Padded Helmets on Interaction between Cerebrospinal Fluid and Brain after a Low-Speed Head Impact, Applied Sciences (2023). DOI: 10.3390/app13074544

Citation: New study could change assumptions about helmet safety (2023, April 6) retrieved 30 May 2024 from https://medicalxpress.com/news/2023-04-assumptions-helmet-safety.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.

Explore further

How to prevent concussions in football? Better helmets

22 shares

Feedback to editors