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This collection contains presentations by Jeffery A. Steevens, Ph.D., Senior Scientist at the US Army Engineer Research and Development Center in Vicksburg, MS, Andrew J. Steckl, Professor of Solid State Electronics at the University of Cincinnati, Mounir Zok, Director of Technology and Innovation at the United State Olympic Committee, Charles L. Geraci, Ph.D., Associate Director for Nanotechnology at the National Institute for Occupational Safety and Health, Douglas J. Casa, Ph.D., Chief Executive Officer at the Korey Stringer Institute, and William Adams, Ph.D., Lesley Vandermark, Ph.D., and Luke Belval of the University of Connecticut, Bill Casebeer, Research Area Manager, Human Systems & Autonomy (HSA) at Lockheed Martin Advanced Technology Laboratories, Christopher M. Hartshorn, Ph.D., Program Director of the Center for Strategic Scientific Initatives at the National Cancer Institute, and Christian Whitchurch, Chief Scientist at the Defense Threat Reduction Agency, which were given during the Blood, Sweat and Tears II Workshop, hosted by the Nano-Bio Materials Consortium (NBMC), a SEMI Strategic Association Partner, in May 2016 in Dayton, OH.

A Risk-Based Framework to Guide the Safe and Rapid Development of Army Nanotechnologies” describes a framework incorporated into the DoD acquisition process to commercialize wearable technology. Risk assessments and case studies are also supplied. The ERDC provides research in civil works, water resources, environmental quality/installations, military engineering, and geospatial research and engineering.

Microfluidics on Paper” discusses paper electronics, R2R vs. wafer lithography, . Notably, point-of-care medical screening tests using biological fluids on paper are like “labs-on-paper” with the following qualities: good function, low material cost, low fabrication cost, stable, disposable, light-weight, easy to use, fast response time, easy to read, and output that’s easy to interpret. Many charts and graphs are supplied, along with potential applications, including tears, saliva, and blood.

Athlete to Superhero: How Wearables Will Shape the Future of Sports” shows how wearable devices can be used to measure, analyze, and perform, as improvements have been made over the years in battery life, wireless distance, and data processing location, offering real-time analytics thanks to the IoT. Many hypothetical products are shown in vibrant pictures.

The NIOSH Nanotechnology Research Program – The Need for Advanced Sensors for Worker Exposure Evaluation” discusses critical areas of research that involve advanced sensors and monitoring, such as toxicology, exposure, and epidemiology. This includes environmental monitoring, like contaminant detection. NIOSH’s mission is to develop new knowledge in the field of occupational safety and health and transfer that knowledge into practice. The NIOSH Nanotechnology Research Center’s mission is to provide national and world leadership for research and guidance on the implications and applications of nanomaterials on occupational safety and health.

Thriving During Physical Activity in the Heat – How Can Technology Help?” discusses the need for a non-invasive, real-time hydration assessment and body temperature assessment as a key for maximizing athletic performance in the heat, factoring in hydration, heat acclimatization, body cooling, environmental conditions, and clothing/equipment. An integrated model of human thermoregulation and many graphs on the effects of dehydration are included, among others. Heat stroke fatalities continue to be on the rise.

Sensor Interpretation – Understanding Blood, Sweat, Tears and Human Performance” discusses the sense, assess, and augment model. Lockheed Martin’s Algorithm & Software Development (ATL) boasts a full neurophysiology lab, autonomy research area, human-robot interaction area, human systems analysis expertise, simulation environments, and access to other resources.

Wearable Technologies – Their Future in Patient / Clinician Decision Making” discusses some wearable technologies NIH has worked on, such as pediatric environmental exposures, physiological signals, activity, and/or behavior in a natural environment to gain new insights into environmental determinants of asthma, at home patient monitoring, auto-reporting to ER, and measuring blood alcohol levels in real-time. Many graphs are supplied. NIH’s mission is to fund extramural/intramural R&D to obtain fundamental knowledge about the nature and behavior of living systems and the application of that knowledge to enhance health, lengthen life, and reduce illness and disability.

Wearable Technology for CB Exposure Monitoring” discusses chemical and biological threats, the evolution of “wearable,” and a proposed strategy to leverage advances in wearable sensor technology to increase survivability to CB events. DTRA’s mission is to safeguard the US and its Allies from Weapons of Mass Destruction (Chemical, Biological, Radiological, and Nuclear) and High-Yield Explosives by providing capabilities to reduce, eliminate and counter the threat, and mitigate its consequences.

 

Keywords: Wearable Devices, Military, Substrate, Fabrication, Lithography, R2R, Medical, Healthcare, Nanotechnology, Environmental, Robotics, Microfluidics, Wireless, Safety