Abstract: A method and system of monitoring changes in a body, the method comprising the steps of: (a) emitting microwave radiation from a set of spaced apart transmitters placed adjacent the body; (b) separately receiving a radiation pattern from the transmitters via at least one receiver; (c) analysing the differences between the separately received radiation patterns to determine changes in the body.

Abstract: A tunable auscultation system includes a heart sound acquirer for sensing heart sounds from at least one chest location of the patient. An initial conditioner then conditions the heart sounds through pre-amplification and anti-aliasing. The heart sounds are transduced into electrical signals by a signal processor. The electric heart signals are then tuned by an analysis tool. The analysis tool includes an interaction tuner, a processing tuner and an output tuner. The interaction tuner includes a preset tuning selector and a dynamic range tuning selector. The processing tuner includes a band pass filter and an algorithmic extraction engine which applies extraction algorithms to the electric heart signals, segments them and extracts signals of interest. Signals of interest may be correlated to specific pathologies. The output tuner includes a signal strength indicator, a diagnosis indicator, an overlapping cardiac cycle display and a display configuration engine. A display module provides output.

Abstract: A method and system for determining systolic time intervals, by analysis of radio frequency (RF) scatter patterns in conjunction with Electrocardiogram (ECG) data, is provided. An RF emitter is placed on the cardiac patient. The emitter includes two or more transmitting antennas which emit RF radiation into the cardiac patient, resulting in an RF scatter pattern. An RF sensor receives the scattered RF signals. The RF emitted from the antennas will differ spatially with regard to the RF sensor, causing the RF scatter patterns to differ from one another. A signal processor analyzes these differences to identify inhomogeneous structures, and to identify aortic valve motion, including aortic valve opening and closure. An electrocardiogram identifies the onset of the cardiac cycle. Systolic intervals are determined using the onset of the cardiac cycle and the aortic valve motion. Cardiac contractility also is determined by correlation to systolic intervals.

Abstract: A method and system of cardiac contractility analysis is provided. Cardiac contractility may include indices such as ejection fraction (EF) and rate of change in pressure (dP/dt) in a heart. Heart sounds may be measured and calibrated by attenuation. Likewise, a first acoustic peak in the first heart sound (S1), and a second acoustic peak of the second heart sound (S2) may be identified. The first heart sound (S1) may be calibrated by the second heart sound (S2). Amplitudes of calibrated heart sounds may be correlated to cardiac contractility. Electrical activity and acoustics of the heart are measured. The pre-ejection period of the cardiac cycle may be calculated. The left ventricular ejection time of the cardiac cycle may likewise be calculated. Then a ratio of pre-ejection period over left ventricular ejection time may be calculated and correlated to cardiac contractility. Pressure on the acoustic sensor may be used to calibrate acoustic data.

Abstract: An auscultation system includes a transducer for generating an acoustic signal at a transducing location of the subject, and a sensor for receiving an attenuated acoustic signal at a sensing location of the subject. The attenuated signal received at the sensing location is digitized, and may be analyzed in the frequency and/or time domain. The comparison of the digitized attenuated signal against the initial transduced signal allows for the computation of the degree of acoustic attenuation between the transducing and sensing locations. Acoustic attenuation may be utilized to generate an intensity ratio. The ejection fraction of the heart subject may then be computed by correlation to the intensity ratio. Pulse echo methods are also disclosed. The echo transducer is oriented on the subject and generates a series of signal pulses. The return echo on the pulse is then received and a brightness encoded image is produced.