Differential conductivity hemodynamic monitor

Electricity: measuring and testing – Determining nonelectric properties by measuring electric...

Reexamination Certificate

Rate now

  [ 0.00 ] – not rated yet Voters 0   Comments 0

Details

C324S439000, C324S445000, C324S450000, C604S030000, C604S065000, C604S218000, C604S004010, C073S861040, C073S861070, C073S861080, C210S096100, C210S646000

Reexamination Certificate

active

06452371

ABSTRACT:

FIELD OF THE INVENTION
This invention relates to measurement of multiple hemodynamic variables. More particularly, this invention relates to measurement of the hemodynamic variables during a medical procedure or for diagnostic purposes using a differential conductivity monitor to measure or detect at least one of recirculation efficiency, flow rate or the presence of air bubbles.
BACKGROUND OF THE INVENTION
In many medical situations it is desirable to quantitatively determine, or measure, various hemodynamic parameters, such as the recirculation rate or the recirculation efficiency of a biological or medical fluid to increase the benefits of, or decrease the time required for, a therapeutic treatment, or for diagnostic purposes. For example, hemodialysis (herein “dialysis”) is an inconvenient, expensive, and uncomfortable medical procedure. It is, therefore, widely recognized as desirable to minimize the amount of time required to complete the procedure and to achieve a desired level of treatment.
In dialysis, a joint is typically surgically created between a vein and an artery of a patient undergoing dialysis. The joint provides a blood access site where in inlet line to a dialysis apparatus and an outlet line from the dialysis apparatus are connected. The inlet line draws blood to be treated from the patient, while the outlet line returns treated blood to the patient.
The joint may be an arteriovenous fistula, which is a direct connection of one of the patient's veins to one of the patient's arteries. Alternatively the joint may be a synthetic or animal organ graft connecting the vein to the artery. As used herein, the term “fistula” refers to any surgically created or implanted joint between one of the patient's veins and one of the patient's arteries, however created.
In the fistula a portion of the treated blood returned to the patient by the outlet line may recirculate. Recirculating treated blood will co-mingle with untreated blood being withdrawn from the patient by the inlet line. This recirculation, and the resulting co-mingling of treated an untreated blood, is dependent, in part, on the rate at which blood is withdrawn from and returned to the patient. The relationship is typically a direct, but non-linear relationship. It can be readily appreciated that the dialysis apparatus will operate most effectively, and the desired level of treatment achieved in the shortest period of time, when the inlet line is drawing only untreated blood at the maximum flow rate capability of the dialysis apparatus consistent with patient safety. As a practical matter, however, as flow rate through the dialysis apparatus is increased, the proportion of recirculated treated blood in the blood being drawn through the inlet line is increased. In order to select the flow rate through the dialysis apparatus, it is desirable to know proportion of recirculated treated blood in the blood being withdrawn from the patient by the inlet line. This proportion is referred to herein as the “recirculation ratio”. The recirculation ratio can also be defined as the ratio between the flow of recirculated blood being withdrawn from the fistula to the flow of blood being returned to the fistula. Recirculation efficiency may then be defined by the relationship.
E=1−R (Equation 1)
where
E=Recirculation efficiency
R=Recirculation ratio
Alternatively, recirculation efficiency way be equivalently expressed as the ratio of blood flow being returned to the fistula, but not being recirculated, to the total blood flow being returned to the fistula. Knowing the recirculation efficiency, the dialysis apparatus operator can adjust the flow rate through the dialysis apparatus to minimize the time required to achieve the desired level of treatment.
In the prior art, quantitative determination of recirculation ratio or recirculation efficiency has typically required laboratory testing, such as blood urea nitrogen tests, which take considerable amounts of time and which require withdrawing blood from the patient, which is recognized as undesirable.
A method and apparatus for qualitatively detecting the presence or absence of recirculation in a fistula is described in “FAM 10 Fistula Flow Studies and their Interpretation” published by Gambro, Ltd. based on research performed in 1982. The Gambro method and apparatus injects a quantity of a fluid having an optical density less than the optical density of treated blood into the dialysis apparatus outlet line. A resulting change in the optical density of the blood being drawn through the dialysis apparatus inlet line is qualitatively detected as indicative of the presence of recirculation. The Gambro method and apparatus does not quantitatively determine or measure a recirculation ratio or recirculation efficiency.
Devices which qualitatively determine recirculation by thermal techniques are also known.
A quantitative measurement of the recirculation efficiency of a bodily or medical fluid is useful in other therapeutic and diagnostic procedures as well. For example, recirculation ratios and efficiencies are useful for determining cardiac output, intervascular recirculation, recirculation in non-surgically created access sites, and dialyzer performance from either the blood side or the dialysis side of the dialyzer, or both.
It is known that the electrical conductivity of a fluid in a closed non-metallic conduit can be measured without contact with the fluid by inducing an alternating electrical current in a conduit loop comprising a closed electrical path of known cross sectional area and length. The magnitude of the current thus induced is proportional to the conductivity of the fluid. The induced current magnitude may then be detected by inductive sensing to give a quantitative indication of fluid conductivity. A conductivity cell for measuring the conductivity of a fluid in a closed conduit without contact with the fluid is described in U.S. Pat. No. 4,740,755 entitled “Remote Conductivity Sensor Having Transformer Coupling In A Fluid Flow Path,” is issued Apr. 26. 1988 to Ogawa and assigned to the assignee of the present invention, the disclosure of which is hereby incorporated herein by reference.
It is further desirable to have a way of detecting the presence of air in a dialysis apparatus outlet line to minimize the probability of air being returned to a patient in the outlet line. It is further advantageouis to have a means of determining a volume flow rate of fluid flowing in the inlet and outlet tube of the dialysis apparatus.
Air bubble detectors which detect the presence of an air bubble soncially, ultrasonically or optically are knwon, but a more sensitive device that is not subject to sonic or optical shadows or distortion is desirable.
It is further desirable to measure a flow rate of a fluid in a tube, either as a part of a recirculation monitoring procedure, or as a separately measured hemodynamic parameter.
It is still further desirable to provide a hemodynamic monitoring device which is capable of monitoring more than one hemodynamic parameter, in order to reduce system cost and increase system flexibility.
It is against this background that the differential conductivity hemodynamic monitor of the present invention developed.
SUMMARY OF THE INVENTION
A significant aspect of the present invention is a method and an apparatus for accurately measuring a volumetric flow rate of a fluid flowing in a tube. In accordance with this aspect of the invention the fluid has an electrical conductivity and a corresponding concentration of conductivity producing ions. The electrical conductivity of the fluid is altered, as by injection of a bolus of hypertonic saline solution. The altered electrical conductivity is measured and integrated over time. The integrated value is then interpreted to determine flow rate.
Further in accordance with this apsect of the invention, fluid conductivity is measured by flowing the fluid through a conductivity cell with a continuous path configuration, inducing an electrical current in the flu

LandOfFree

Say what you really think

Search LandOfFree.com for the USA inventors and patents. Rate them and share your experience with other people.

Rating

Differential conductivity hemodynamic monitor does not yet have a rating. At this time, there are no reviews or comments for this patent.

If you have personal experience with Differential conductivity hemodynamic monitor, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Differential conductivity hemodynamic monitor will most certainly appreciate the feedback.

Rate now

     

Profile ID: LFUS-PAI-O-2828638

  Search
All data on this website is collected from public sources. Our data reflects the most accurate information available at the time of publication.