Surgery – Diagnostic testing – Cardiovascular
Reexamination Certificate
2000-04-10
2001-09-18
Schaetzle, Kennedy (Department: 3762)
Surgery
Diagnostic testing
Cardiovascular
C483S064000, C483S064000
Reexamination Certificate
active
06290651
ABSTRACT:
TECHNICAL FIELD OF THE INVENTION
The present invention pertains generally to the field of cardiovascular medicine, and more particularly, to an instrument for characterizing the status of the cardiovascular system using an electrical analog model thereof.
BACKGROUND OF THE INVENTION
The modified Windkessel electrical analog model of the arterial system is gaining increasing attention from the medical community as a clinically useful tool for characterizing the human vasculature for the purpose of diagnosing, treating and monitoring cardiovascular disease. A number of studies of the cardiovascular system using the modified Windkessel model have been conducted, and correlations between the model parameters and normal and disease states have been identified. For instance, U.S. patent application Ser. No. 07/250,315, entitled “Method for Diagnosing Hypertension,” discloses a method for utilizing the parameter C
2
of the modified Windkessel model to diagnose, treat and monitor the vascular disease condition underlying hypertension.
The modified Windkessel model of the arterial system is shown in FIG.
1
. In the model:
C
1
=proximal arterial compliance (ml/mm Hg);
C
2
=distal arterial compliance (ml/mm Hg);
L=inertence (mm Hg/ml/s
2
);
P
1
=proximal arterial (aortic) pressure (mm Hg);
P
2
distal arterial (brachial) pressure (mm Hg); and
R=peripheral resistance (dynes sec cm
−5
).
While the usefulness of the Windkessel model parameters for the diagnosis, treatment and monitoring of cardiovascular disease has become more apparent, they remain relatively difficult to use on a routine basis for two reasons. The first is the need to obtain a cardiac output measurement in order to determine the parameters. Conventional procedures for determining cardiac output, such as thermodilution and dye dilution, are surgically invasive, requiring catheterization of the patient. Physicians, in general, are reluctant to employ such procedures because of their cost, the discomfort and inconvenience to the patient, the risk of infection and other severe complications, and their relative level of complexity as compared to alternative noninvasive procedures. The second reason involves the difficulty with obtaining patient data for the modified Windkessel model from blood pressure waveforms, which also conventionally requires the insertion of an arterial catheter and the use of a transducer and other electronic equipment.
The present invention, as described hereinafter, provides an instrument which can noninvasively measure Windkessel parameters, or other impedance parameters which depend on cardiac output measurement, using a noninvasively obtained arterial blood pressure waveform of the patient. Accordingly, it is contemplated that the present invention will significantly facilitate widespread clinical use of the modified Windkessel model parameters, or other impedance model parameters, in the diagnosis, treatment and monitoring of cardiovascular disease. In particular, the invention allows for a quick, easy-to-use and noninvasive determination of the modified Windkessel parameters so that these parameters can be ascertained and used during routine physical examinations, and patient screening, treatment and monitoring. Given that the only existing practical and quick screening device for determining the status of the cardiovascular state is a blood pressure cuff (i.e., a sphygmomanometer) measurement, it is contemplated that the invention could provide a substantial and new diagnostic capability for physicians to use on a routine basis.
SUMMARY OF THE INVENTION
The present invention provides a vascular impedance parameter instrument comprising transducer means for converting a noninvasively obtained arterial blood pressure waveform signal to a corresponding analog electrical signal, means for digitizing the analog signal, means for processing the digitized signal and determining a cardiac output value based on characteristics of the arterial blood pressure waveform and on other noninvasively determined patient data, and means for utilizing the cardiac output value and for further processing of the waveform signal in order to determine one or more vascular impedance parameter measurements. The present invention recognizes that usable and useful Windkessel parameter measurements can be obtained even if the cardiac output value used to obtain the measurements are not particularly accurate. Accordingly, the present invention provides that cardiac output measurements be obtained noninvasively, using the same arterial blood pressure waveform used to obtain the Windkessel model parameter measurements.
REFERENCES:
patent: 4137910 (1979-02-01), Murphy
patent: 4289141 (1981-09-01), Cormier
patent: 4429701 (1984-02-01), Goor et al.
patent: 4807638 (1989-02-01), Sramek
patent: 4821735 (1989-04-01), Goor et al.
patent: 4834107 (1989-05-01), Warner
patent: 4899758 (1990-02-01), Finkelstein et al.
patent: 5031629 (1991-07-01), DeMarzo
patent: 5054493 (1991-10-01), Cohn et al.
patent: 5103828 (1992-04-01), Sramek
patent: 5241966 (1993-09-01), Finkelstein et al.
patent: 5316004 (1994-05-01), Chesney et al.
Alderman, E.L., et al., “Evaluation of the Pulse-Contour Method of Determining Stroke Volume in Man”,Circulation, 46, 546-558, (1972).
Alexander, R.S., et al., “Factors Determining the Contour of Pressure Pulses Recorded from the Aorta”, Federation Proceedings, 11, 738-749, (1952).
Beltran, A., et al., “Arterial Compliance Abnormality in Isolated Systolic Hypertension”,Circulation. 90, 67th Scientific Sessions of the American Heart Assn., Abstract No. 2726, I-506, (Oct. 1994).
Beltran, E.L., et al., “A Non-Invasive Method for Measuring Regional Peripheral Compliance”, IEEE Engineering in Medicine and Biology Society Proceedings, 11, 134-135, (1989).
Boehmer, R.D., “Continuous, Real-Time, Noninvasive Monitor of Blood Pressure: Penaz Methodology Applied to the Finger”,J. of Clin. Monitoring, 3(4).
Bourgeois, M.J., et al., “Characteristics of Aortic Diastolic Pressure Decay with Application to the Continuous Monitoring of Changes in Peripheral Vascular Resistance”,circulation Research, 35, 56-66, (1974).
Bourgeois, M.J., et al., “continous Determination of Beat-to-Beat Stroke Volume from Aortic Pressure Pulses in the Dog”,Circulation, 39, 15-24, (1976).
Braunwald, E., et al., “Determinants of Duration and Mean Rate of Ventricular Ejection”,Circulation Research, 6, 319-325, (1958).
Cardus, D., et al., “Systolic Time Intervals at Rest and During exercise”,Cardiology, 59, 133-153, (1974).
Caro, C.G., et al., “The Mechanics of the Circulation”,Oxford Medical Publications, 268-278, (1978).
Cinelli, P., et al., “Systolic Time Intervals During Isometric Exercise in Supine Position Should be Corrected Also for Arterial Pressure”,Acta Cardiological, 37(2), 93-103, (1982).
Cohn, J.N., “Drugs Used to Control Vascular resistance and Capacitance”,In: The Heart, Schlant, R. (ed.), 8th Ed., (1993).
Cohn, J.N., “Evaluation of Arterial Compliance”,In: Hypertension Primer, Izzo, J.L. and Black, H.R., (eds.), Pub. By Council on High Blood Pressure Research, American Heart Association, pp. 252-253, (1993).
Cohn, J.N., “Functional Impact of Structural or Tone Changes in Small and Large Arteries”,The Atherosclerotc Blood Vessel, Structural and Functional Assessment of the Atherosclerotc Blood Vessel, San Francisco, Jul. 1993, 15-16, (1993).
Cohn, J.N., “Methods of Evaluation of Arterial Compliance”,Hypertension Primer, J.L. Izzo et al. (eds.)Published by Council on High Blood Pressure Research, American Heart Association, 252-253, (1993).
Cohn, J.N., “Pharacologic Mechanisms of Nitrates in Myocardial Ischemia”,American Journal of cardiology, 70, 38G-42G, (Nov. 1992).
Cohn, J.N., “Structural Changes in Cardiovascular Disease”,Am. J. Cardiol., 76, 34E-37E, (1995).
Cohn, J.N., “The Role of Vascular Compliance in Abnormalities of Hypertension and Atherosclerosis”,Atherosclerosis Beyond Cholesteral, Monograph from Proceedings of a Symposium by the Council on Hypertension and Atherosclerosis Education, L
Chesney Charles F.
Cohn Jay N.
Finkelstein Stanley M.
Hypertension Diagnostics, Inc.
Schaetzle Kennedy
Schwegan, Lundberg, Woessner & Kluth, P.A.
LandOfFree
Vascular impedance measurement instrument does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Vascular impedance measurement instrument, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Vascular impedance measurement instrument will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-2454196