Abstract: A non-invasive blood pressure system is disclosed herein. The non-invasive blood pressure system includes a pressure transducer configured to obtain pressure data comprising a transient baseline effects component. The non-invasive blood pressure system also includes a processor adapted to receive the pressure data from the pressure transducer. The processor is configured to generate a transient baseline effects model, and to implement the transient baseline effects model to at least partially remove the transient baseline effects component of the pressure data. The removal of the transient baseline effects component from the pressure data eliminates a potential source of error and thereby enables a more accurate blood pressure estimate.

Abstract: A method of measuring blood pressure of a patient is provided. The method comprises inflating a blood pressure cuff to a user selectable target pressure and subsequently further inflating or deflating the blood pressure cuff in a stepwise manner by a predetermined pressure amount. At each pressure step in a first sequence of alternate steps of cuff pressure variation, the occurrence of at least two successive oscillometric pulses with matching pulse amplitude and other possible matching criteria is identified. The blood pressure cuff is inflated following the identification. Further a single oscillometric pulse is obtained at each pressure step in a second sequence of alternate steps of cuff pressure variation. The pattern of inflating, obtaining two matching oscillometric pulses, inflating, and obtaining a single oscillometric pulse is repeated until sufficient oscillometric envelope information is obtained for determining one or more blood pressure parameters of the patient.

Abstract: A method of measuring blood pressure of a patient is provided. The method comprises inflating a blood pressure cuff to a user selectable target pressure and subsequently further inflating or deflating the blood pressure cuff in a stepwise manner by a predetermined pressure amount. At each pressure step in a first sequence of alternate steps of cuff pressure variation, the occurrence of at least two successive oscillometric pulses with matching pulse amplitude and other possible matching criteria is identified. The blood pressure cuff is inflated following the identification. Further a single oscillometric pulse is obtained at each pressure step in a second sequence of alternate steps of cuff pressure variation. The pattern of inflating, obtaining two matching oscillometric pulses, inflating, and obtaining a single oscillometric pulse is repeated until sufficient oscillometric envelope information is obtained for determining one or more blood pressure parameters of the patient.

Abstract: A non-invasive blood pressure system is disclosed herein. The non-invasive blood pressure system includes a pressure transducer configured to obtain pressure data comprising a transient baseline effects component. The non-invasive blood pressure system also includes a processor adapted to receive the pressure data from the pressure transducer. The processor is configured to generate a transient baseline effects model, and to implement the transient baseline effects model to at least partially remove the transient baseline effects component of the pressure data. The removal of the transient baseline effects component from the pressure data eliminates a potential source of error and thereby enables a more accurate blood pressure estimate.

Abstract: A method and system for determining when to make a reversion to smaller cuff pressure steps during an oscillometric blood pressure measurement is disclosed. The method and system comprise comparing conformance of oscillometric envelope blood pressure data with previous blood pressure data, including measuring a shift between the oscillometric envelope blood pressure data and an oscillometric envelope derived from the previous blood pressure data. In addition, the method and system include making a reversion decision based on whether the shift exceeds an allowable threshold. Once a reversion decision is made a subsequent decision may be made as to the need for increasing the cuff pressure level.

Abstract: A method of operating a non-invasive blood pressure (NIBP) monitor that includes a blood pressure cuff and a pressure transducer. The method initially inflates the blood pressure cuff to a level above systolic pressure and begins to deflate the pressure cuff using a continuous or linear deflation technique. During the linear deflation of the pressure cuff, the oscillation pulses from the pressure transducer are obtained and compared to predicted pulse estimates. If the obtained oscillation pulses vary from the predicted pulse estimates, the linear deflation technique is interrupted and the pressure cuff is then deflated in a sequence of distinct pressure steps. During each pressure step, the oscillation pulses are obtained and the pressure cuff is not deflated to the next pressure step until the oscillation pulses correspond to each other.

Abstract: A blood pressure measurement system that utilizes a non-invasive blood pressure (NIBP) monitor having a blood pressure cuff and pressure transducer. The measurement system provides a plurality of separate processing techniques that each receive a plurality of oscillometric data values from the pressure transducer. Each of the processing techniques separately constructs an oscillometric envelope based upon the oscillometric data values. Based upon the plurality of separate oscillometric envelopes, the system compares the envelopes and develops a calculated blood pressure from the plurality of envelopes. The calculated blood pressure is then displayed by the NIBP system. The plurality of oscillometric envelopes can be compared and combined in different manners to calculate the patient's blood pressure from the plurality of different processing techniques.

Abstract: A blood pressure measurement system that utilizes both a non-invasive blood pressure (NIBP) monitor having a blood pressure cuff and a continuous non-invasive blood pressure (CNIBP) monitor. During operation of the NIBP monitor, the blood pressure cuff is inflated to an initial inflation pressure greater than the systolic blood pressure for the patient being monitored. The CNIBP monitor calculates an estimated blood pressure that is supplied to the NIBP monitor. The NIBP monitor utilizes the continuous, estimated blood pressure to select a target inflation pressure for the blood pressure cuff. During operation of the NIBP monitor, the size of the pressure steps from the initial inflation pressure to a final pressure can be varied based upon the continuous blood pressure estimate from the NIBP monitor.

Abstract: A method and technique for the continuous, non-invasive measurement of blood pressure. The blood pressure measurement technique of the present invention utilizes ultrasound measurements to determine the diameter of the blood vessel in which the blood pressure is being measured as well as the flow rate of blood at both an input point and an output point along the blood vessel. The system utilizes a transmission line model to relate various blood vessel measurements with electrical components. The transmission line model, in combination with data management techniques including state variable representations and Kalman filtering, is used to develop a blood pressure measurement in real time.

Abstract: A method and system for determining pulse rate of a patient are disclosed. The method and system include acquiring measured information for at least one pulse at a pressure step, determining and storing quality values for the at least one pulse at the pressure step, analyzing pulse matching criteria for the pressure step, and determining pulse rate based on the measured information, quality values, and pulse matching criteria.

Abstract: In a method and apparatus for measuring extreme blood pressure values during a single non-invasive blood measurement, the time intervals between sequential heartbeats are measured for a series of heartbeats in an oscillometric blood pressure measurement time period. Oscillometric blood pressure measurement data for the heartbeats of the series is obtained and associated with the heartbeat time intervals. An average time interval between heartbeats is also determined. A first data bin may be defined for blood pressure data associated with time intervals that are longer as compared to the average time interval. A second data bin is defined for blood pressure data with time intervals that are shorter as compared to the average time interval. The measured oscillometric blood pressure data is sorted into the data bins in accordance with the associated time intervals. The data in the first data bin is used to derive a high systolic blood pressure value and a low diastolic blood pressure value.

Abstract: A method and system for eliminating artifacts in an oscillation envelope are disclosed. The method and system comprise evaluating conformance of the oscillometric envelope blood pressure data with a predetermined expected pattern and excluding one or more data points of the oscillometric envelope blood pressure data based on non-conformance with the expected pattern. The expected pattern is based upon generally known physiological principles relating to oscillometric envelopes, a curve fit representing an oscillometric envelope from a previous determination, or other types of criteria.

Abstract: A technique for comparing pressure oscillations obtained during a blood pressure determination wherein two or more sets of matching criteria may be employed. The set of matching criteria to be employed is determined based on the heart rate variability or the presence of heart beat irregularities or arrhythmias as determined by an independent heart monitor, such as an ECG. The selected set of matching criteria may then be employed in determining the acceptability of the time interval between two oscillations and the equivalence of the two oscillations based upon one or more oscillation characteristics, such as peak amplitude. In this manner, non-consecutive oscillations may be matched and used in determining blood pressure.