Biography

Biography

Wearable sensors can enable continuous collection of physiologic signals to measure physiologic parameters or identify signatures of disease. The combination of wearable sensors and artificial intelligence to continuously analyze data provides new approaches to patient monitoring at all levels of care. This talk will outline some of the factors that can affect the safety and performance of wearable patient monitoring systems from sensors to data-driven applications and discuss regulatory science approaches we are taking to address the challenges in their evaluation.

Biography

Studying the cyber kinetic effects of medical IoT devices for intelligence purposes and warfighter situational awareness.

Biography

In recent years, human wearable technologies have grown to include smart watches, fitness trackers, smart shirts, smart shoes, and more. While there seems to be overwhelming agreement that the data available from these devices [are useful], may radically improve healthcare decision making, and could pave the way toward a true, integrated care continuum, there is little acknowledgement of the complexity and cost of collecting, compiling, and presenting those data to allow healthcare providers and researchers to draw meaningful conclusions.

Despite a focus on personalized learning and readiness within the Air Force, the Performance-Enabled Operational Training Environments (PEOTE) work may emerge as an adaptable [system architecture] model for healthcare information technology and informatics systems to overcome these data proliferation challenges.

PEOTE, in development at Air Force Research Laboratory, is an approach to architecting information networks, by leveraging existing operational communications and data infrastructure and applying these pathways to training. The technologies and the methods in development enable the most flexible data collection and analysis capabilities by creating and leveraging standards-based data architectures, infrastructure capabilities, and data structures. When applied to a training scenario, this framework enables the use of biodata, not as human performance indicators, but as mission performance indicators.

This talk covers the networked training environment, how our team is developing performance measures, and some of the use cases we are exploring, including using the Survival Health Awareness Responder Kit (SHARK) data within Air Force Combat Search and Rescue mission training and large-force exercises.

In this presentation, a review of wearable EEG, EOG, and EMG state-of the-art medical devices with clearance for US marketing will be discussed. A team comprising of researchers from NextFlex evaluated 510(k) cleared, de Novo granted, and PMA approved wearable medical devices by searching through various US FDA databases. Additionally, the team also examined adverse events reported through the Manufacturer and User Facility Device Experience database that houses medical device reports submitted to the FDA. Wearable EEG, EOG, and EMG medical device profiles will be presented discussed on usability for detecting decrement in human performance due to cognitive stress and/or cognitive fatigue.

Biography

Biography

The United States has executed Aeromedical Evacuation (AE) for over 100 years. Originating with the first crude attempts at evacuating patients on biplanes in 1918. AE has evolved directly in line with the medical capabilities and advancements in aircraft. AE now provides the United States Air Force (USAF) with a global reach on various cargo and refueling aircraft. In the late 1980s, specialized Critical Care Air Transport Teams (CCATTs) developed to augment AE crews. CCATTs drastically changed medical care provided in our nation’s battlespaces. They allowed for more agile far forward casualty care and forged the En Route Care (ERC) systems. ERC is the backbone ensuring the survival of our wounded warriors and bringing them home to their families. The challenges abound when functioning in the ERC system to include the environment, the available resources, and personnel limitations. Exploring and targeting these challenge areas will continue to allow ERC to keep in step with our ever‐changing mission requirements and progress the impressive legacy of bringing heroes home.

Biography

As compared to conventional, rigid, bulky physiological monitoring tools, emerging onskin wearable biomedical devices are ultrathin, lightweight, and small footprint and can find wide applications in point of care diagnostics because of their easy deployment outside the hospital settings. At present, on-skin wearables are usually fabricated by patterning conventional inorganic materials, novel organic materials, or emerging nanomaterials on continuous (i.e., non-porous) flexible supporting substrates. Consequently, the state-of-the-art on-skin wearables often suffer from expensive precursor materials, costly fabrication facilities, complex fabrication processes, and limited functionalities and disposability. By using widely accessible pencils and papers as the fabrication tools, we have developed a rich variety of cost-effective and disposable on-skin bioelectronic devices, ranging from biophysical sensors and sweat biochemical sensors to thermal stimulators, humidity energy harvesters, and transdermal drug delivery systems. The enabled devices can find wide applications in point of care diagnostics, particularly in low-resource environments owing to their low-cost resources, handy operation, time-saving fabrication, and abundant potential designs. Besides, by using judiciously engineered porous elastomer as supporting substrates, on-skin wearable devices with high breathability and self-cooling capability can be achieved.

Biography

An overview of the DHA virtual health program including driving factors, high level requirements, and pathway forward. The presentation will also provide an update on the DoD virtual health COVID-19 response and the value provided to patient care through virtual health.

Biography

Wireless wearable devices can continuously assess and communicate the condition of patients and are crucial components of the are crucial components of the move towards digital, mobile health monitoring. We envision that widespread adoption of disposable wireless devices has the potential to radically transform care-giving in clinical settings. Implementation of continuous patient monitoring could make practices such as spot-checking patient vital signs during hospitalization obsolete. Furthermore, earlier patient discharge may become possible through earlier and safer patient mobilization enabled by wireless monitoring. In this talk, we will discuss flexible hybrid electronic manufacturing opportunities and challenges to create low cost, high performance wireless sensor systems for patient monitoring. These single use devices will support 3-Lead ECG, reflective SpO2, respiration rate and core body temperature sensing on a continuous basis for 72 hours.

Biography

Biography

There is an entire field of research dedicated to the chemical analysis of exhaled breath, and the enticing promise of non-invasive medical diagnostics and monitoring. Interestingly, we know that sampling plays a key role in the metabolite content in this complex sample, and biomarker detection and identification in breath may rest on appropriate sampling and analysis protocols. There is also some evidence on how breath chemicals change over time and in response to illness, diet, overall health and exposures. There are also studies that show exogenous drugs measured in breath as well. This talk with highlight our own basic research in this area.

Jennifer's Biography | Sean's Biography

Historically, biomarker discovery efforts have focused on developing sensing strategies for disease diagnosis and prognosis. More recently, the Department of Defense has made a significant investment in wearable sensor and data analytics methods to predict physiologic and cognitive detriment with the goal of improving personnel readiness and augmenting human performance. During this presentation, a broad overview of not only biomarker discovery approaches within Air Force Research Laboratories will be provided, but also future trends and technology gaps limiting fielding of wearable devices, outlining the underpinning for potential external collaborations.

Biography

There are several compounds that interfere with accurate sensing of metabolic analytes in the subcutaneous space, including drugs and endogenous compounds. In addition, when a glucose sensor is exposed to a delivered insulin formulation, there are additional interference issues. Methods of overcoming these threats to accurate sensing will be discussed.

Abstract & Biography

FEATURED SPEAKER
Biography

Biography

Biography

Dimitrios Damianos, PhD joined Yole Développement (Yole) as a Technology and Market Analyst and is working within the Photonics, Sensing & Display division.

Dimitrios is daily working with his team to deliver valuable technology & market reports regarding the imaging industry including photonics & sensors.

After his research on theoretical and experimental quantum optics and laser light generation, Dimitrios pursued a Ph.D. in optical and electrical characterization of dielectric materials on silicon with applications in photovoltaics and image sensors, as well as SOI for microelectronics at Grenoble’s university (France).

Chenmeijing Liang works as a Technology & Market Analyst within the Photonics, Sensing & Display Division at Yole Développement (Yole).

As part of the Imaging team, Chenmeijing contributes analyses of CIS markets, related technologies and market strategies of the leading semiconductor companies, as well as the quarterly reports.

Prior to Yole, she was engaged in the development of R&D projects: Chenmeijing was a member of Group PSA R&D department where she worked on Vehicle 3D Imaging projects. In addition, she assisted with various technical and commercial projects.

Biography

Biography

Biography

Biography