We live in an era of wearable sensing, where our movement through the world can be continuously monitored by devices. Yet, we lack a portable sensor that can continuously monitor muscle, tendon, and bone motion, allowing us to monitor performance, deliver targeted rehabilitation, and provide intuitive, reflexive control over prostheses and exoskeletons. Here, we introduce a sensing modality, magnetomicrometry, that uses the relative positions of implanted magnetic beads to enable wireless tracking of tissue length changes. We demonstrate real-time muscle length tracking in an in vivo turkey model via chronically implanted magnetic beads while investigating accuracy, biocompatibility, and long-term implant stability. We anticipate that this ...
MagnetoMyoGraphy (MMG) with superconducting quantum interference devices (SQUIDs) enabled the measur...
Magnetoelastic sensors, which undergo mechanical resonance when interrogated with magnetic fields, c...
In this paper we present a wearable high rate MIMU (magnetic-inertial measurement unit) based body t...
Human movement is accomplished through muscle contraction, yet there does not exist a portable syste...
Muscle tissue drives nearly all movement in the animal kingdom, providing power, mobility, and dexte...
Magnetic tracking systems have been widely investigated in biomedical engineering due to the transpa...
Objective: The quest for an intuitive and physiologically appropriate human-machine interface for th...
We recently introduced the concept of a new human-machine interface (the myokinetic control interfac...
Measurement of physiological deformations in specific tissues can provide significant information fo...
This thesis presents a new system of monitoring human motion and muscle activity concurrently, in pe...
Magnetism‐based systems are widely utilized for sensing and imaging biological phenomena, for exampl...
Signals produced by skeletal muscle can be utilised for monitoring and treatment of different moveme...
International audienceThe electrical activity of brain, heart and skeletal muscles generates magneti...
MagnetoMyoGraphy (MMG) with superconducting quantum interference devices (SQUIDs) enabled the measur...
Magnetoelastic sensors, which undergo mechanical resonance when interrogated with magnetic fields, c...
In this paper we present a wearable high rate MIMU (magnetic-inertial measurement unit) based body t...
Human movement is accomplished through muscle contraction, yet there does not exist a portable syste...
Muscle tissue drives nearly all movement in the animal kingdom, providing power, mobility, and dexte...
Magnetic tracking systems have been widely investigated in biomedical engineering due to the transpa...
Objective: The quest for an intuitive and physiologically appropriate human-machine interface for th...
We recently introduced the concept of a new human-machine interface (the myokinetic control interfac...
Measurement of physiological deformations in specific tissues can provide significant information fo...
This thesis presents a new system of monitoring human motion and muscle activity concurrently, in pe...
Magnetism‐based systems are widely utilized for sensing and imaging biological phenomena, for exampl...
Signals produced by skeletal muscle can be utilised for monitoring and treatment of different moveme...
International audienceThe electrical activity of brain, heart and skeletal muscles generates magneti...
MagnetoMyoGraphy (MMG) with superconducting quantum interference devices (SQUIDs) enabled the measur...
Magnetoelastic sensors, which undergo mechanical resonance when interrogated with magnetic fields, c...
In this paper we present a wearable high rate MIMU (magnetic-inertial measurement unit) based body t...