Research to Literally Get Under the Skin of Things

Professor Aisling Ní Annaidh - UCD School of Mechanical and Materials Engineering

An unusual research topic for her doctoral thesis led Professor Aisling Ní Annaidh into the fascinating world of tissue biomechanics – the study of research into the mechanical and physical properties of tissue – and developing a particular focus on the skin. This has in turn led her and her team to undertake a wide range of research over the past decade with significant practical healthcare impacts. The outcomes include unexpected results leading to changes to EU standards for helmet testing, supporting innovation in Ireland’s world-leading medical devices sector and, most recently, a novel approach to the age-old challenge of customising wheelchairs for people who have a physical disability.

“There’s absolutely no point in having a sophisticated model that has no basis in reality. The experiments provide us with the information we need to create more sophisticated models – so they both have a place in our work and complement each other very well.”

Tissue Biomechanics has Widespread Applications

The opportunity to undertake research for a PhD in 2008 into the mechanics of stabbing provided Aisling Ní Annaidh with the opportunity to explore new avenues in what she candidly admits is the specialised niche area of tissue biomechanics. The Professor of Mechanical Engineering Design and her students now undertake a wide range of studies into how tissues in the body behave. Their work, a combination of experimentation and modelling, provides practical benefits for a range of individuals.

It all began when Prof. Ní Annaidh was looking for a thesis topic for her doctorate at UCD. Her Supervisor, Prof. Michael Gilchrist, suggested she respond to a request for help from the Irish State Pathologists Office, which wanted to understand the force required to stab someone and cause significant damage, with a view to determining criminal intent.

“We looked at parameters affecting this, such as the amount of clothing, speed and differences in the types and sharpness of knives. The topic caught people’s attention and it was interesting in itself. But more than this, at the end of the day it has also allowed me to specialise in the area of skin biomechanics. And that, in turn, has allowed me to develop my interests in different applications within this niche area,” she says.

The topic of skin biomechanics is not just niche, it is also complex, offering a variety of avenues for research that yield highly practical impacts. “The thickness of skin differs from person to person and age has a big effect on its material properties in terms of strength and composition; in an older person layers shrink and dehydration can become an issue,” Prof. Ní Annaidh adds. “As well as differing from person to person there’s also variation in the properties of skin in different parts of the body.”

From Cadavers to Non-Invasive Experiments

Unlike her initial research, which was conducted experimentally using cadavers, Prof. Ní Annaidh’s focus now is on finding ways to conduct non-destructive and painless experiments on living people. ‘If you are going to be undertaking surgery on someone, for example, and you want to predict how their skin is going to behave, then you really should not be using a one size fits all approach. So our focus now is on patient-specific measurements of tissue,” she says. In particular, Prof. Ní Annaidh’s group are now developing acoustic (ultrasound- type) devices to measure and predict an individual’s potential for skin growth. This work forms part of Prof. Ní Annaidh’s prestigious European Research Council funded project, BreastRecon. Within this 5 year project, the team will ultimately be working towards patient-specific tissue expansions which will be based on individual biomechanical measurements, offering a disruptive breakthrough in breast reconstructions and other reconstructive surgeries. To achieve this, the team will employ a combination of experiments and advanced modelling techniques.

“I try to do a combination of experiments and modelling in everything I do. There’s absolutely no point in having a sophisticated model that has no basis in reality. The experiments provide us with the information we need to create more sophisticated models – so they both have a place in our work and complement each other very well. By measuring the tissues themselves we can predict how they will behave in different scenarios, in extreme conditions such as a traffic or sporting accident or in surgery, for example.”

Unexpected Result Leads to New Helmet Standards

The output of this research is evident in a range of applications. Research by one of her PhD students, Dr. Antonia Trotta, for example, undertaken as part of a larger EU project to improve sports helmet design, looked at the level of friction created between a person’s scalp and the lining of their helmet in an accident.

Our work found that the friction and relative sliding between the head and the helmet is a key parameter in helmet impact testing. It is therefore critical to ensure motorcycle and sports helmets are safety tested under realistic friction conditions.  These findings have directly led to changes in European standards for helmet testing, with specific requirements now set for the amount of friction present in the dummy head. 

A Pain Free Future for Jabs?

UCD has been an active player in the development of one of the up-and-coming technologies transforming medicine today – microneedles. Prof. Ní Annaidh has contributed valuable technical expertise to the work in this area undertaken by the UCD Medical Device Design Group led by her colleague Dr. Eoin O’Cearbhaill, Director of the UCD Centre for Biomedical Engineering. The Group’s work has already led to the establishment of one spin out company to exploit its commercial potential in one application.

Microneedles, typically shorter than the thickness of a sheet of paper and about the width of human hair, penetrate the top layer of dead skin to reach the living layer, the epidermis, below. Avoiding contact with nerve endings, they do not cause pain normally associated with the delivery of drugs or vaccines by needles. They offer benefits, too, in diagnostics.

Dr. O’Cearbhaill acknowledges that a lot has been achieved but there is a lot more to do in this area. “There is some understanding of what’s involved but it is actually really complex and the field of microneedles depends on interdisciplinary research. We need the inputs from experts in drug formulation, engineers and vaccinologists and we really value the contribution of Prof. Ní Annaidh, who brings a deep understanding of the skin’s morphology and function to our work.”

Together with Dr. O’Cearbhaill, Prof. Ní Annaidh has ongoing projects examining the role of skin biomechanics in microneedle deployment and efficacy. Their previous doctoral student, Dr. Wenting Shu, used a combination of experiments and simulations to help understand how tissue mechanics affects drug diffusion in the dermis.

Addition is Better than Subtraction for WheelChair Users

In another project, Dr. Susan Nace, who was also an employee of non-profit disability services provider Enable Ireland, developed an improved way of designing custom-contoured wheelchairs for people with specialised requirements as part of her PhD studies.

The conventional approach to this is hand cutting and shaping of foam materials, a labour intensive and wasteful subtractive process. The new approach is a more efficient 3d printed one which facilitates designs with internal structures to create airflows through the chair and thus reduce the risk of pressure sores and improve skin comfort.

Research References

• Computational and Experimental Analysis of Drug‐Coated Microneedle Skin Insertion: The Mode of Administration Matters - Shu - 2025 - Advanced Materials Interfaces - Wiley Online Library
• A machine learning approach to predict in vivo skin growth | Scientific Reports
• A Gaussian process approach for rapid evaluation of skin tension - ScienceDirect
• Insights into the mechanics of solid conical microneedle array insertion into skin using the finite element method W Shu, H Heimark, N Bertollo, DJ Tobin, ED O’Cearbhaill, A Ní Annaidh Acta Biomaterialia 135, 403-413
• The presence of Wormian bones increases the fracture resistance of equine cranial bone, LA Zambrano M, D Kilroy, A Kumar, MD Gilchrist, A Ní Annaidh, PloS one 16 (4), 2021
• Mechanical Characterization and Modeling of the Porcine Cerebral Meninges, B Pierrat, L Carroll, F Merle, DB MacManus, R Gaul, C Lally, MD Gilchrist, A. Ní Annaidh, Frontiers in Bioengineering and Biotechnology 8, 801, 2020
• Biofidelic finite element modelling of brain trauma: Importance of the scalp in simulating head impact, A Trotta, JM Clark, A McGoldrick, MD Gilchrist, A. Ní Annaid, International Journal of Mechanical Sciences 173, 105448, 2020
• Manufacturing custom-contoured wheelchair seating: A stateof-the-art review, S Nace, J Tiernan, A Ní Annaidh, Prosthetics and orthotics international 43 (4), 382-395 3, 2019 Tension lines of the skin, A Ní Annaidh, M Destrade, Skin Biophysics, 265-280, 2019
• Effect of brain matter in torsion, V Balbi, A Trotta, M Destrade, A Ní Annaidh, Soft matter 15 (25), 5147-5153, 2019 Evaluation of the head-helmet sliding properties in an impact test, A Trotta, A Ní Annaidh, RO Burek, B Pelgrims, J Ivens, Journal of biomechanics 75, 28-34 22, 2018
• The importance of the scalp in head impact kinematics, A Trotta, D Zouzias, G De Bruyne, A Ní Annaidh, Annals of biomedical engineering 46 (6), 831-840 16, 2018
• Characterization of the anisotropic mechanical properties of excised human skin, A Ní Annaidh, K Bruyère, M Destrade, MD Gilchrist, M Otténio, Journal of the mechanical behavior of biomedical materials 5 (1), 139-148, 2012
• Automated estimation of collagen fibre dispersion in the dermis and its contribution to the anisotropic behaviour of skin, A Ní Annaidh, K Bruyère, M Destrade, MD Gilchrist, C Maurini, M Otténio, Annals of biomedical engineering 40 (8), 1666-1678, 2012

Media & Social Media References

• https://www.ucd.ie/research/impact/researchimpact/casestudies/pdf/CASE_STUDY_TROTTA.pdf
• (opens in a new window)https://www.irishexaminer.com/news/arid-30937482.html
• https://irishtechnews.ie/mechanics-of-a-twisted-brain-howside-impacts-to-the-head-can-be-as-damaging-as-frontalimpacts/
• (opens in a new window)https://www.engineersireland.ie/Engineers-Journal/News/the-mechanics-of-stabbing-assessing-stab-penetration-forces/
• (opens in a new window)https://soundcloud.com/michel-destrade/smallerinterviewmp3?fb_action_ids=315307898644348&fb_action_ types=soundcloud%3Apublish
• (opens in a new window)https://www.irishexaminer.com/news/arid-20290990.html
• https://www.technologyreview.com/2013/02/26/179675/experiments-on-cadavers-settle-100-year-old-puzzle-overhuman-skin-strength/

Funding acknowledgements

This research was / is supported by the HEADS project (Head protection: a European network for Advanced Designs in Safety), an Innovation Training Network funded under the European Commission’s Marie Sklodowska-Curie Programme; The Irish Research Council and Enable Ireland under the Irish Research Council’s Employment Based Postgraduate Programme; and the UCD-CSC (University College Dublin - China Scholarship Council) scholarship.

This work is supported by ERC grant BreastRecon (Project ID: 101171623 ). Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or the European Research Council Executive Agency. Neither the European Union nor the granting authority can be held responsible for them.

This work is supported in part by a Grant from Science Foundation Ireland under Grant Number 18/CRT/6049. The opinions, findings and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the Science Foundation Ireland.

The authors wish to acknowledge the Irish Centre for High-End Computing (ICHEC) for the provision of computational facilities and support.  This work is supported in part by Research Ireland under grant number 13/RC/2073_P2, CURAM Research Ireland Centre for Medical Devices, and grant number 16/RC/3872, I-Form Research Ireland Centre for Advanced Manufacturing, and by the Irish Research Council and Enable Ireland under the Irish Research Council’s Employment Based Postgraduate Programme (Grant No.: irc72e6e373cd8ee4981332f32b5e9773be).