An electromagnetic wave sensor for determining a hydration status of a body tissue in vivo includes an electromagnetic wave transmitter, a waveguide, and an electromagnetic wave receiver. The electromagnetic wave transmitter is configured to emit an electromagnetic wave signal in a frequency range between 1 Hz and 1 THz. The waveguide is coupled to the electromagnetic wave transmitter. The waveguide is adapted to be arranged next to the body tissue such that a fringe field of the electromagnetic wave signal guided by the waveguide penetrates the body tissue. The electromagnetic wave receiver is coupled to the waveguide. The electromagnetic wave receiver is configured to receive the electromagnetic wave signal modified by the body tissue in dependence of a hydration status of the body tissue.

Methods of evaluating homeostatic capacity of a subject are provided. Aspects of the methods include obtaining dynamic biometric data from the subject and evaluating the homoeostatic capacity of the subject from the obtained dynamic biometric data. Also provided are devices configured for use in practicing the methods. The methods and devices described herein find use in a variety of applications, e.g., health monitoring applications, treatment applications, dynamic diagnostic applications, etc.

The disclosure provides NIR-II phosphorescent imaging probe and methods of using the NIR-II phosphorescent imaging probes for imaging tissues, such as cancerous tissues. NIR-II phosphorescent imaging probes of the present disclosure include CuInX.sub.2 nanotubes, where X is a chalcogen selected from S, Se, and Te, such as CuInSe.sub.2 nanotube.

Systems and methods for non-invasive fat reduction can include targeting a region of interest below a surface of skin, which contains fat and delivering ultrasound energy to the region of interest. The ultrasound energy generates a thermal lesion with said ultrasound energy on a fat cell. The lesion can create an opening in the surface of the fat cell, which allows the draining of a fluid out of the fat cell and through the opening. In addition, by applying ultrasound energy to fat cells to increase the temperature to between 43 degrees and 49 degrees, cell apoptosis can be realized, thereby resulting in reduction of fat.

Embodiments of tissue monitoring and therapy systems and methods are disclosed. In some embodiments, a monitoring and therapy system comprises collecting video images of a tissue site, amplifying said video images via Eulerian Video Magnification, and determining a treatment parameter from the amplified video images detectable by Eulerian Video Magnification. If the treatment parameter differs from a threshold, an alert may be generated.

Featured are intravaginal devices and methods of using the devices to observe the state of an individual's pelvic floor muscles in order to diagnose, treat, or prevent pelvic floor disorders (e.g., pelvic organ prolapse and incontinence) and their accompanying symptoms and methods of using the devices to treat or prevent vaginal disorders (e.g., skin laxity) in a subject using an energy transmitter (e.g., a radiofrequency transmitter). Also featured are algorithms to detect pelvic floor movements and physiological indicia from sensor data.

Systems and methods for high frequency impedance spectroscopy detection of daily changes of dielectric properties of the human body to measure body composition and hydration status. According to an aspect, a method at a computing device to determine a set of indirect dynamic human metabolism parameters includes using a sensor on an individual to acquire a set of electrical measurements. The method also includes combining a ratio technique with a canonical model form technique. The also includes performing a series of mathematical calculations on the acquired set of electrical measurements to determine the set of indirect dynamic human metabolism parameters for the individual based on the combined ratio technique and the canonical model form technique. The method further includes generating a trend regarding the set of indirect dynamic human metabolism parameters in response to performing the series of mathematical calculations on the acquired set of electrical measurements to determine the set of indirect dynamic human metabolism parameters for the individual.

An ultrasonic receiver receives ultrasonic waves reflected at a plurality of portions of the body of a person to be measured, and thus the person to be measured needs to input the approximate height of himself/herself. An electrostatic capacitance sensor includes a transmission electrode and a reception electrode. The electrostatic capacitance sensor measures a mutual capacitance between the transmission electrode and the reception electrode by a mutual capacitance method. A variable frequency pulse generator generates a pulse supplied to the transmission electrode. A control apparatus allows the variable frequency pulse generator to sweep the frequency of the pulse and allows the electrostatic capacitance sensor to measure the mutual capacitance to identify a frequency at which the measured mutual capacitance is minimized. The control apparatus obtains the height of a person to be measured on the basis of the identified frequency.

Aspects of the present disclosure are presented for a surgical instrument having one or more sensors at or a near an end effector and configured to aide in the detection of tissues and other materials and structures at a surgical site. The detections may then be used to aide in the placement of the end effector and to confirm which objects to operate on, or alternatively, to avoid. Examples of sensors include laser sensors used to employ Doppler shift principles to detect movement of objects at the surgical site, such as blood cells; resistance sensors to detect the presence of metal; monochromatic light sources that allow for different levels of absorption from different types of substances present at the surgical site, and near infrared spectrometers with small form factors.

An oximeter probe that takes into account tissue color (e.g., skin color or melanin content) to improve accuracy when determining oxygen saturation of tissue. Light is transmitted from a light source into tissue having melanin (e.g., eumelanin or pheomelanin). Light reflected from the tissue is received by a detector. A compensation factor is determined to account for absorption due to the melanin. The oximeter uses this compensation factor and determines a melanin-corrected oxygen saturation value.