Development of Next-Generation Protective Clothing and High-Performing Face Masks

There is an ongoing global threat of highly transmissible infectious disease outbreaks such as the COVID-19 pandemic. Consequently, the demand for effective, sustainable, and reusable personal protective equipment (PPE) is high for the protection of the frontline workers and community, especially with possible vaccine-resistant variants emerging. However, the commonly used PPE, especially protective clothing, and face masks, has several drawbacks and improvement areas. In this thesis, three state-of-the-art reviews (Chapters 2A, 2B, and 2C) identified the challenges and limitations of commonly used protective clothing and face masks. Potential new materials, technologies, and strategies were also addressed to overcome the limitations and challenges. Lastresort strategies were outlined to help people navigate their choices during mask shortages. In addition, it was revealed that the multifunctional performance of PPE could be significantly enhanced with the application of advanced materials such as graphene and metal nanoparticles (NPs). Accordingly, in Chapters 3 and 4, reduced graphene oxide (RGO) and copper (Cu)/silver (Ag) NPs incorporated cotton and silk fabrics were developed by a facile dip and dry method using a silane crosslinking agent followed by chemical reduction and vacuum heat treatment. The developed fabrics demonstrated excellent multifunctional activities such as hydrophobicity, electroconductivity, Joule heating capacity, heat dissipation, thermal stability, mechanical stability, UV shielding, and washing durability. Especially, the RGO- and Cu-NPs-embedded cotton and silk fabrics exhibited the best multifunctional performances with high washing durability among all other fabric samples. To further assess the potential of protective clothing, antimicrobial activity and biocompatibility of the developed fabrics were investigated in Chapter 5. The graphene and Cu/Ag NPs incorporated fabrics showed excellent activity against bacteria (Escherichia coli, Pseudomonas aeruginosa, and Staphylococcus aureus) and fungus (Candida albicans). On top of the antimicrobial activity, the developed fabrics showed low cytotoxicity, making them a potential candidate for application in next-generation PPE. During COVID-19, due to the massive global shortage of disposable masks/respirators, cloth masks became a mainstay and showed hope of being a sustainable alternative to medical masks. Chapter 6 provides a comprehensive study using violent respiratory events (sneeze) and evaluating all dimensions of protection (respiratory droplet blocking efficiency, water resistance, and breathing resistance) to develop a blueprint for the optimal design of a high-performing reusable cloth mask that can outperform a disposable surgical mask. The results reveal that droplet blocking efficiency increases by ∼20 times per additional fabric layer. A minimum of 3 layers with a combination of cotton/linen (hydrophilic) for the inner layer, blends for the middle–layer, and polyester/nylon (hydrophobic) for the outer–layer is required to resemble the performance of surgical masks. The fabrics' average thread count and porosity should be greater than 200 and less than 2 %, respectively. Overall, the developed graphene/NPs incorporated multifunctional fabrics, and face mask design proved to be a breakthrough to prevail over the limitations of the conventional PPE materials. They hold great promise to be applied to a broader range of PPE and could provide a sustainable PPE solution globally

Automated Laser Ablation of Inhomogeneous Metal Oxide Films to Manufacture Uniform Surface Temperature Profile Electrical Heating Elements

This paper presents automated laser ablation strategies to improve the temperature distribution across the surface of inhomogeneous Ni-Fe-Cr-NiO electrical heating elements during joule heating. A number of iterative closed-loop laser control algorithms have been developed and analyzed in order to assess their impact on the efficacy of the heating element, in terms of homogeneous temperature control, and on the implications for automated fabrication of inhomogeneous metal oxide films. Analysis shows that the use of the leading method, i.e. use of a temperature dependent variable power approach with memory of previous processes, showed a 68% reduction in the standard deviation of the temperature distribution of the heating element and a greater uniformity of temperature profile as compared to existing manual methods of processing

Transduction mechanisms, micro-structuring techniques, and applications of electronic skin pressure sensors: A review of recent advances

PD/BD/105876/2014Electronic skin (e-skin), which is an electronic surrogate of human skin, aims to recreate the multifunctionality of skin by using sensing units to detect multiple stimuli, while keeping key features of skin such as low thickness, stretchability, flexibility, and conformability. One of the most important stimuli to be detected is pressure due to its relevance in a plethora of applications, from health monitoring to functional prosthesis, robotics, and human-machine-interfaces (HMI). The performance of these e-skin pressure sensors is tailored, typically through micro-structuring techniques (such as photolithography, unconventional molds, incorporation of naturally micro-structured materials, laser engraving, amongst others) to achieve high sensitivities (commonly above 1 kPa−1), which is mostly relevant for health monitoring applications, or to extend the linearity of the behavior over a larger pressure range (from few Pa to 100 kPa), an important feature for functional prosthesis. Hence, this review intends to give a generalized view over the most relevant highlights in the development and micro-structuring of e-skin pressure sensors, while contributing to update the field with the most recent research. A special emphasis is devoted to the most employed pressure transduction mechanisms, namely capacitance, piezoelectricity, piezoresistivity, and triboelectricity, as well as to materials and novel techniques more recently explored to innovate the field and bring it a step closer to general adoption by society.publishersversionpublishe

Chapter 34 - Biocompatibility of nanocellulose: Emerging biomedical applications

Nanocellulose already proved to be a highly relevant material for biomedical applications, ensued by its outstanding mechanical properties and, more importantly, its biocompatibility. Nevertheless, despite their previous intensive research, a notable number of emerging applications are still being developed. Interestingly, this drive is not solely based on the nanocellulose features, but also heavily dependent on sustainability. The three core nanocelluloses encompass cellulose nanocrystals (CNCs), cellulose nanofibrils (CNFs), and bacterial nanocellulose (BNC). All these different types of nanocellulose display highly interesting biomedical properties per se, after modification and when used in composite formulations. Novel applications that use nanocellulose includewell-known areas, namely, wound dressings, implants, indwelling medical devices, scaffolds, and novel printed scaffolds. Their cytotoxicity and biocompatibility using recent methodologies are thoroughly analyzed to reinforce their near future applicability. By analyzing the pristine core nanocellulose, none display cytotoxicity. However, CNF has the highest potential to fail long-term biocompatibility since it tends to trigger inflammation. On the other hand, neverdried BNC displays a remarkable biocompatibility. Despite this, all nanocelluloses clearly represent a flag bearer of future superior biomaterials, being elite materials in the urgent replacement of our petrochemical dependence

Low Cost, Disposable and Wearable Body Warmer using RGO Sheets Coated on Cloth Substrate as Heating Element

Increase in customer demand for durable and functional fabric has been created an opportunity for nanomaterials to be integrated onto the textile substrates. We have fabricated a single step approach for electrically conductive textile for large scale production of reduced graphene oxide (RGO) nanosheets coated cotton cloth based films for heat generation application. It can be used as electro thermal wearable body warmer, in many industrial and laboratory applications. The RGO nanosheets aqueous dispersion was successfully prepared by solution mixing of RGO in N-Methyl-2-Pyrrolidone (NMP) using ultra sonication process. For the fabrication of RGO coated cotton cloth, the heating element film formation is carried out by dip coating method. The thickness of the heating element film is around 200 mu m. As-prepared RGO nanosheets and RGO coated textile (cotton) cloth were characterized using XRD, FE-SEM techniques for their structural and surface morphology analysis. The RGO coated cotton cloth based electro thermal film annealed at 80 degrees C temperature showed a good heating performance. Saturated temperature of around 52 degrees C was attained when 40V is applied for 1 min to the fabricated device. It has been observed that, the power drawn by the device at 40 V was 480mW. The nanomaterials offer wide potential applications when integrated with garments that can be used to sense and respond to external parameters like electrical, optical and physiological signals. Importantly, the direct use of the aqueous dispersion of RGO in NMP opens up a new window for the next generation innovative wearable textile electronic devices. However, the field of nanotechnology, by considering the features of the textiles due to light weight, corrosion free, chemical stability for biomedical, automobile, flexible electronics for wearable technology etc. applications

Proceedings of the 2018 Canadian Society for Mechanical Engineering (CSME) International Congress

Published proceedings of the 2018 Canadian Society for Mechanical Engineering (CSME) International Congress, hosted by York University, 27-30 May 2018