| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 600507000 | By detecting volume of body portion | 9 |
| 20080287815 | Photoplethysmography apparatus and method employing high resolution estimation of time-frequency spectra - A photoplethysmography apparatus and method is provided for high resolution estimating of Time-Frequency Spectra (TFS) and associated amplitudes using Variable Frequency Complex Demodulation (VFCDM), in a two-step procedure using a Time-Varying Optimal Parameter Search (TVOPS) technique to obtain TFS, followed by VFCDM to obtain even greater TFS resolution and instantaneous amplitudes associated with only specific frequencies of interest, via the combined TVOPS and VFCDM. | 11-20-2008 |
| 20090326396 | DUAL BODY PLETHYSMOGRAPHY APPARATUS AND PROCESS FOR MEASURING BLOOD FLOW BETWEEN THE THORAX AND ABDOMEN (THE TRUNK) AND THE BODY PERIPHERY - An apparatus is described ( | 12-31-2009 |
| 20100016739 | Method of Assessing Blood Volume Using Photoelectric Plethysmography - A method and system for assessing blood volume within a subject includes generating a cardiovascular waveform representing physiological characteristics of a subject and determining blood volume of the subject by analyzing the cardiovascular waveform. The step of analyzing includes generating a first trace of the per heart-beat maximums of the cardiovascular waveform, which is representative of the systolic pressure upon the cardiovascular signal, generating a second trace of the per heart-beat minimums of the cardiovascular waveform, which is representative of the diastolic pressure upon the cardiovascular signal, and comparing the respective first trace and the second trace to generate an estimate of relative blood volume within the subject. In accordance with an alternate method of analyzing harmonic analysis is applied to the cardiovascular waveform, extracting a frequency signal created by ventilation and applying the extracted frequency signal in determining blood volume of the subject. | 01-21-2010 |
| 20100228136 | SYSTEMS AND METHODS FOR MONITORING DP, IVRT, DiFT, DIASTOLIC FUNCTION AND/OR HF - Implantable systems, and methods for use therewith, are provided for monitoring a patient's diastolic function and/or heart failure (HF) condition. A signal indicative of changes in arterial blood volume and a signal indicative of electrical activity of the patient's heart are obtained. Beginnings of diastolic periods can be detected based on a feature of the signal indicative of changes in arterial blood volume. Ends of the diastolic periods can be detected based on a feature of the signal indicative of electrical activity of the patient's heart, or on the signal indicative of changes in arterial blood volume. Diastolic periods (DPs), isovolumic relaxation times (IVRTs) and/or diastolic filling times (DiFTs) can be estimated based on the detected beginnings of the diastolic periods and detected ends of the diastolic periods. The patient's diastolic function and/or HF condition (and/or changes therein) can be monitored based on the estimates of DP, IVRT and/or DiFT. | 09-09-2010 |
| 20100292592 | System and method of measuring changes in arterial volume of a limb segment - A medical diagnostic device performs diagnostics for assessing the ability of the arteries to respond to an increase in blood flow. The medical diagnostic device determines relative changes in arterial volume of the limb segment during a time period after a stimulus relative to the arterial volume of the limb segment during a baseline period using the amplitudes or other portions of the component pulse waves (such as early systolic components) of volume pulse waves during the baseline period and after the stimulus. | 11-18-2010 |
| 20120197142 | Method And System For Determining Vascular Changes Using Plethysmographic Signals - Embodiments of the present disclosure relate to determining changes in a vasculature by analyzing changes in one or more attributes of a plethysmographic signal. According to certain embodiments, an apparatus may obtain plethysmographic signals prior to and subsequent to the administration of a vasoactive stimulus. The apparatus may include a processing unit configured to analyze and to compare attributes of the plethysmographic signals. The processing unit may correlate any changes in signal attributes to a change in a physiological condition of the vasculature (e.g., vascular tone/compliance). The apparatus may also include a display unit configured to present any changes in the vasculature as well as any alarms in response to a trigger from the processing unit. | 08-02-2012 |
| 20120253211 | SYSTEMS AND METHODS FOR VARYING BLOOD FLOW TO IDENTIFY AUTOREGULATORY RANGES IN A PATIENT - A method may include controlling a bypass pump to introduce blood flow variations to a patient. The method may also include analyzing blood volume in the brain of the patient with respect to the blood flow variations and determining, based on the analyzing, whether an autoregulatory mechanism associated with the brain is operating properly. | 10-04-2012 |
| 20130324866 | INDICATIONS OF CROSS-SECTION OF SMALL BRANCHED BLOOD VESSELS - Systems and methods of extracting information relating to diameter and/or diameter changes in small blood vessels such as arterioles. This information may be used to assess a degree of vasoconstriction and/or vasodilatation. In one method, changes in vessel cross-section due to pulse wave arrival is assessed in both arterioles and in larger arteries. A time delay between the changes and/or a change in time delay is optionally associated with arteriole cross-section and/or changes therein. | 12-05-2013 |
| 20150133801 | SYSTEM AND METHOD FOR LOW POWER SAMPLING OF PLETHYSMOGRAPH SIGNALS - A method for generating a sampled plethysmograph data, includes measuring a plethysmograph waveform indicative of a first cardiac cycle and a second cardiac cycle, each cycle including a systolic waveform and a diastolic waveform. The method further includes estimating a first start time and a first duration for the systolic waveform of the first cardiac cycle and computing a plurality of amplitudes at a plurality of time instants for the first duration. The method further includes determining a second start time and a second duration of the systolic waveform of the second cardiac cycle. The method also includes assigning the second cardiac cycle, the second start time, and the second duration to the first cardiac cycle, the first start time, and the first duration respectively. The method further includes iteratively performing the steps of measuring, estimating, computing, determining and assigning for the plurality of cardiac cycles acquired sequentially in time. | 05-14-2015 |
