The present invention relates to an apparatus for extracorporeal treatment of blood.
Extracorporeal blood treatment involves removing blood from a patient, treating the blood externally to the patient, and returning the treated blood to the patient. Extracorporeal blood treatment is typically used to extract undesirable matter or molecules from the patient's blood and/or add desirable matter or molecules to the blood. Extracorporeal blood treatment is used with patients unable to effectively remove matter from their blood, such as when a patient has suffered temporary or permanent kidney failure. These patients and other patients may undergo extracorporeal blood treatment to add or remove matter to their blood, to maintain an acid/base balance or to remove excess body fluids, for example.
Extracorporeal blood treatment is typically accomplished by removing the blood from the patient in e.g. a continuous flow, introducing the blood into a primary chamber, also referred to as blood chamber, of a filtration unit (such as a dialyzer or an hemofilter) where the blood is allowed to flow past a semipermeable membrane. The semipermeable membrane selectively allows matter in the blood to cross the membrane from the primary chamber into a secondary chamber and also selectively allows matter in the secondary chamber to cross the membrane into the blood in the primary chamber, depending on the type of treatment.
A number of different types of extracorporeal blood treatments may be performed. In an ultrafiltration (UF) treatment, undesirable matter is removed from the blood by convection across the membrane into the secondary chamber. In a hemofiltration (HF) treatment, the blood flows past the semipermeable membrane as in UF and desirable matter is added to the blood, typically by dispensing a fluid into the blood either before and/or after it passes through the filtration unit and before it is returned to the patient. In a hemodialysis (HD) treatment, a secondary fluid containing desirable matter is introduced into the secondary chamber of the filtration unit. Undesirable matter from the blood crosses the semipermeable membrane into the secondary fluid and desirable matter from the secondary fluid may cross the membrane into the blood. In a hemodiafiltration (HDF) treatment, blood and secondary fluid exchange matter as in HD, and, in addition, matter is added to the blood, typically by dispensing a fluid into the treated blood before its return to the patient as in HF.
Specific blood treatment apparatus have been developed for the treatment of acute patients mainly because:
In this situation, blood treatment apparatus have been developed presenting infusion lines for supplying fluid upstream or downstream the filtration unit, a fresh dialysis liquid line for supplying liquid to the dialysate chamber of the filtration unit, and a waste line receiving spent dialysis fluid and ultrafiltered fluid from filtration unit. In correspondence of each of the above lines, means for generating a flow rate is acting, such as a peristaltic pump which is rotated under the supervision of a control unit. Moreover, fluid containers supply fluid to the infusion lines and to the dialysate line, while a waste container or a waste handling system receives the spent liquid from the waste line. Typically, scales are used to weigh the fluid containers and to provide signals used by the control unit to control the pumps or other actuators on the fluid lines so that the apparatus achieves the fluid removal rate set by the user, and—depending upon the apparatus—any other rates through each line. In more sophisticated solutions, each of the above lines receives fluid from a respective container which, in use, is associated to a respective scale and cooperates with a respective pump. A user interface allows an operator entering the fluid loss rate and the fluid flow rates of each of the substitution lines and dialysate line such that the apparatus is capable of continuously keep under control the amount of fluid infused, the amount of fluid flowing through the dialysate line and the fluid loss rate.
Although the above solution results in a very efficient apparatus able to perform all necessary treatments and to accurately control the flows, the applicant has found ways to further improve known blood treatment apparatuses.
It is an object of the present invention to render available a blood treatment apparatus suitable for intensive care applications which can also be automatically able to deliver prescribed doses, without however compromising the operating philosophy of an intensive care apparatus.
Furthermore, it is an object of the invention an apparatus which is able to take into account the effective portions of the treatment procedure, possibly adapting one or more values of certain set-up parameters to account for machine stops, therapy delivery interruptions, machine downtimes, such as to deliver a prescribed doses during certain time intervals of reference.
A further object of the present invention is an apparatus for the performance of an extracorporeal blood treatment by automatically calculating, performing and monitoring the extracorporeal blood treatment based upon a choice of a treatment and of a prescription by the operator.
Another object is an apparatus capable of controlling all operating parameters in a safe manner.
Another object is to automatically ascertain whether certain prescription targets cannot be achieved and inform the operator accordingly.
Another object is to notify the operator of conditions requiring operator assistance.
At least one of the above objects is substantially reached by an apparatus according to one or more of the appended claims.
Apparatus and processes for the extracorporeal treatment of blood according to aspects of the invention are here below described.
A first aspect relates to an apparatus for extracorporeal treatment of blood comprising a filtration unit having a primary chamber and a secondary chamber separated by a semi-permeable membrane; a blood withdrawal line connected to an inlet of the primary chamber, and a blood return line connected to an outlet of the primary chamber said blood lines being designed to be connected to a patient cardiovascular system; a blood pump for controlling the flow of blood through the blood lines; an effluent fluid line connected to an outlet of the secondary chamber; at least one fluid line selected in the group comprising: one or more infusion fluid lines connected to one of the blood withdrawal line and the blood return line, and a dialysis fluid line connected to the inlet of the secondary chamber;
means for regulating the flow of fluid through said fluid lines, and a control unit configured to:
For instance, initial values can be set for the fluid flow rate (Qrep, Qpbp) through the infusion fluid line, the fluid flow rate (Qdial) through the dialysis liquid fluid line (if this line is present and used), and the fluid removal rate (Qpfr) from the patient. The effluent fluid flow rate can then be calculated as sum of the above flow rates. Then, based on the set dose, the set flow rates values are updated and the means for regulating controlled with the updated set values. As the patient treatment time may be unknown, the control procedure makes sure that the prescribed dose is achieved during time intervals of reference of a defined duration into which the entire treatment time gets progressively divided.
In a 2nd aspect according to the 1st aspect, said prescribed dose comprises one flow rate selected in the group including:
In a 3rd aspect according to any one of 1st or 2nd aspect, the control unit is configured to regularly, e.g. periodically or according to a predetermined time rule, execute said flow update procedure at check points (Ti) during treatment.
In a 4th aspect according to any one of 1st or 2nd or 3rd aspect, the flow update procedure comprises the following steps:
In a 5th aspect according to any one of the preceding aspects, the step of determining a dose need value at a check point (Ti) comprises computing the dose needed to be delivered over a next time period (Tprosp) following the check point (Ti) in order to reach the prescribed dose over a time interval (which is one of the mentioned reference time intervals) which is the sum of the time interval (Tretro) preceding check point (Ti) and the next time period (Tprosp).
In a 6th aspect according to the 5th aspect, the dose need value is calculated according to the formula:
where:
In a 7th aspect according to any one of the preceding aspects, the control unit can additionally be programmed to determine an effective portion (Teff) of said next time period. The effective portion of a time period is the portion during which the treatment is actually delivered to the patient, i.e. the period during which the blood pump and the pumps corresponding to the selected treatment actually run and circulate the respective fluids along the respective lines.
In a 8th aspect according to the 7th aspect the control unit is programmed or configure to calculate a corrected dose value (Dcomputed) as follows:
In a 9th aspect according to the 8th aspect, the control unit is configured to execute the flow update procedure also taking into account for said effective portion (Teff) to be expected over the next time period (Tprosp) by calculating the updated set of values for said fluid flow rates based on said corrected dose value (Dcomputed).
In a 10th aspect according to any one of the preceding aspects the control unit is programmed to allow selection (for instance through a user interface) of one of a plurality of treatment modes, said treatment modes comprising at least two of hemodialysis (HD), hemofiltration with pre-dilution (HFpre), hemofiltration with post-dilution (HFpost), hemofiltration with both pre-dilution and post-dilution (HFpre-post), hemodiafiltration with pre-dilution (HDFpre), hemodiafiltration with post-dilution (HDFpost), hemodiafiltration with both pre-dilution and post-dilution (HDFpre-post), ultrafiltration (UF), and to control the means for regulating based on the treatment mode selection.
In an 11th aspect according to any one of aspects from 2nd to 10th, wherein the control unit is configured to allow selection of one or more dose options (for instance through a user interface), each dose option specifying a respective one of said prescribed doses which a user can select to be the dose placed under control.
In a 12th aspect to claim the 11th aspect the calculation of said updated set of flow rate value or values is also based on said treatment selection and on said dose option selection. In other words depending upon the selected treatment, the control unit decides which are the specific pumps under control (for instance if the treatment is HF, then the dialysis pump is not used at all), and depending upon the dose option and set dose value Dset, the control unit is configured to update at time intervals the set of flow rates accordingly.
In a 13th aspect according to any one of the preceding aspects, the apparatus further comprises a user interface connected to said control unit, said control unit being configured to:
In a 14th aspect according to the 13th aspect the control unit is further configured to:
In a 15th aspect according to the 13th aspect the control unit is further configured to:
In a 16th aspect according to any one of the preceding aspects, said flow rate update procedure comprises:
In a 17th aspect according to the 16th aspect the update procedure includes the steps of checking if the user approved the updated set of flow rate values and, only if the user has approved the updated set of values, controlling said means based on said updated set of values for said flow rates. In other words the control unit may be configured to implement the updated values for the flow rates only after approval from the user.
In an 18th aspect according to any one of the preceding aspects, the control unit is further configured to start a treatment controlling said means for regulating based on said initial set of flow rates; and at time periods execute said flow rate update procedure or the control unit is further configured to execute the flow update procedure before treatment start and at time intervals after treatment start.
In a 19th aspect according to any one of the preceding aspects said control unit 10 is further configured to:
In a 20th aspect according to any one of the preceding aspects said one or more infusion fluid lines comprise a pre-dilution fluid line connected to the blood withdrawal line and/or a post-dilution fluid line connected to the blood return line; in this case, the means for regulating the flow of fluid through said fluid lines comprises at least an infusion pump for regulating the flow through said pre-dilution fluid line and/or through said post-dilution fluid line.
In a 21st aspect according to the 20th aspect the means for regulating the flow of fluid through said fluid lines comprises a pre-dilution pump for regulating the flow through said pre-dilution fluid line and a post-dilution pump for regulating the flow through said post-dilution fluid line.
In a 22nd aspect according to any one of the preceding aspects the apparatus comprises a dialysis fluid line connected to the inlet of the secondary chamber; in this case the means for regulating the flow of fluid through said fluid lines comprises at least a dialysis fluid pump for regulating the flow through said dialysis fluid line.
In a 23rd aspect according to any one of the preceding aspects said one or more infusion fluid lines comprise a pre-blood pump infusion line connected to the blood withdrawal line in a region of this latter which is positioned, in use, upstream the blood pump; in this case, the means for regulating the flow of fluid through said fluid lines comprises at least a pre-blood infusion pump for regulating the flow through said pre-blood pump infusion fluid.
In a 24th aspect according to any one of aspects from 20th to 23rd the step of calculating the updated set of values comprises calculating an updated infusion pump flow rate and an updated dialysis pump flow rate.
In a 25th aspect according to the 24th aspect said step of calculating the updated infusion pump flow rate and updated dialysis pump flow rate comprises changing the infusion pump flow rate and the dialysis fluid flow rate from their respective initial values by a same percentage.
In a 26th aspect according to any one of the preceding aspects the step of calculating the updated set of values comprises changing value of one of the infusion pump flow rate and the dialysis pump flow rate, without changing the value of the other.
In a 27th aspect according to any one of aspects from 20th to 26th calculating an updated infusion pump flow rate comprises calculating an updated pre-dilution pump flow rate and an updated post-dilution pump flow rate.
In a 28th aspect according to the 27th aspect the updated pre-dilution pump flow rate and the updated post-dilution pump fluid flow rate are calculated such as to differ from their respective initial values by a same percentage.
In a 29th aspect according to any one of aspects from 20th to 28th the step of calculating the updated set of values comprises maintaining the value of said pre-blood infusion pump flow rate unchanged to its initial set value.
In a 30th aspect according to any one of aspects from 20th to 29th the step of calculating the updated set of values comprises maintaining the value of said patient fluid removal rate unchanged to its initial set value.
In a 31st aspect according to any one of the preceding aspects the control unit is configured to receive an initial set value for the blood pump flow rate and to control said blood pump accordingly, and wherein the step of calculating said updated set of values comprises maintaining the value of the blood pump flow rate unchanged to its initial value.
In a 32nd aspect according to any one of the preceding aspects said control unit is configured to:
In a 33rd aspect according to any one of the preceding aspects herein wherein the control unit is configured to:
In a 34th aspect according to any one of the preceding aspects said flow rate update procedure further comprises:
In a 35th aspect according to the preceding aspect said flow rate update procedure includes calculating a maximum achievable dose within said safety criteria, and controlling said means for regulating to achieve said maximum achievable dose.
In a 36th aspect according to any one of the preceding aspects the control unit is configured to:
In a 37th aspect according to any one of the preceding aspects the apparatus further comprises:
In a 38th aspect according to any one of the preceding aspects the control unit is programmed to allow a user to:
enter a first value for the prescribed dose (e.g. hourly dose) to be delivered through the entire patient treatment (which can last few days).
In a 39th aspect according to the preceding aspect the control unit is configured to calculate, after receipt of said second value, the updated set of values based upon:
A 40th aspect relates to a process for controlling an apparatus for extracorporeal treatment of blood, the apparatus being of the type comprising a filtration unit having a primary chamber and a secondary chamber separated by a semi-permeable membrane; a blood withdrawal line connected to an inlet of the primary chamber, and a blood return line connected to an outlet of the primary chamber said blood lines being designed to be connected to a patient cardiovascular system; a blood pump for controlling the flow of blood through the blood lines; an effluent fluid line connected to an outlet of the secondary chamber; at least one fluid line selected in the group comprising: one or more infusion fluid lines connected to one of the blood withdrawal line and the blood return line, and a dialysis fluid line connected to the inlet of the secondary chamber; means for regulating the flow of fluid through said fluid lines. The process, which can for instance be executed by a control unit, includes the steps of:
The update set of flow rates is calculated such that during one or more reference time intervals across the treatment time the prescribed dose value is matched.
In a 41st aspect according to the 40th aspect the process comprises the step of controlling said means for regulating the flow of fluid based on said updated set values.
In a 42nd aspect according to the 40th or the 41st aspect, said prescribed dose comprises one flow rate selected in the group including:
In a 43rd aspect according to any one of 41st or 42nd aspect, the process comprises regularly, e.g. periodically or according to a predetermined time rule, executing said flow update procedure at check points (Ti) during treatment.
In a 44th aspect according to any one of 41st or 42nd or 43rd aspect, the flow update procedure comprises the following steps:
In a 45th aspect according to any one of the preceding aspects from 40th to 44th, the step of determining a dose need value at a check point (Ti) comprises computing the dose needed to be delivered over a next time period (Tprosp) following the check point (Ti) in order to reach the prescribed dose over a time interval which is the sum of the time interval (Tretro) preceding check point (Ti) and the next time period (Tprosp).
In a 46th aspect according to the 45th aspect, the dose need value is calculated according to the formula:
where:
In a 47th aspect according to any one of the preceding aspects from the 40th to the 46th, the process includes determining an effective portion (Teff) of said next time period
In a 48th aspect according to the 47th aspect the process comprises calculating a corrected dose value (Dcomputed) as follows:
In a 49th aspect according to the 48th aspect, the process comprises executing the flow update procedure also taking into account for said effective portion (Teff) to be expected over the next time period (Tprosp) by calculating the updated set of values for said fluid flow rates based on said corrected dose value (Dcomputed).
In a 50th aspect according to any one of the preceding aspects from 40th to 49th the process comprises allowing selection (for instance through a user interface) of one of a plurality of treatment modes, said treatment modes comprising at least two of hemodialysis (HD), hemofiltration with pre-dilution (HFpre), hemofiltration with post-dilution (HFpost), hemofiltration with both pre-dilution and post-dilution (HFpre-post), hemodiafiltration with pre-dilution (HDFpre), hemodiafiltration with post-dilution (HDFpost), hemodiafiltration with both pre-dilution and post-dilution (HDFpre-post), ultrafiltration (UF), and to control the means for regulating based on the treatment mode selection.
In an 51st aspect according to any one of aspects from 42nd to 50th, wherein the process comprises allowing selection of one or more dose options (for instance through a user interface), each dose option specifying a respective one of said prescribed doses which a user can select to be the dose placed under control.
In a 52nd aspect to the 51st aspect the calculation of said updated set of flow rate value or values is also based on said treatment selection and on said dose option selection. In other words depending upon the selected treatment, only specific pumps are under control (for instance if the treatment is HF, then the dialysis pump is not used at all), and depending upon the dose option and set dose value Dset, the process updates at time intervals the set of flow rates accordingly.
In a 53rd aspect according to any one of the preceding aspects from 40th to 52nd, the process executes said flow rate update procedure only if the user selects to enter in the dose control mode e.g. through an appropriate command on the user interface of the apparatus.
In a 54th aspect according to the 53th aspect the process comprises:
In a 55th aspect according to the 53th aspect the process comprises:
In a 56th aspect according to any one of the preceding aspects, said flow rate update procedure comprises:
In a 57th aspect according to the 56th aspect the update procedure includes the steps of checking if the user approved the updated set of flow rate values and, only if the user has approved the updated set of values, controlling said means based on said updated set of values for said flow rates. In other words the updated values for the flow rates are implemented only after approval from the user.
In an 58th aspect according to any one of the preceding aspects, the process comprises:
In an 59th aspect according to any one of the preceding aspects from 51st to 57th, the flow-rate update procedure is made before treatment start and at time intervals after treatment start.
In a 60th aspect according to any one of the preceding aspects from 40th to 59th the step of calculating the updated set of values comprises calculating an updated infusion pump flow rate and an updated dialysis pump flow rate. The updated infusion pump flow rate and updated dialysis pump flow rate can differ from their respective initial values by a same percentage or, alternatively by different percentages. In an option it is possible changing value of one of the infusion pump flow rate and the dialysis pump flow rate, without changing the value of the other.
In a 61st aspect according to any one of aspects from 40th to 60th calculating an updated infusion pump flow rate comprises calculating an updated pre-dilution pump flow rate and an updated post-dilution pump flow rate. The updated pre-dilution pump flow rate and the updated post-dilution pump fluid flow rate are calculated such as to differ from their respective initial values by a same percentage. Alternatively, said pre-blood infusion pump flow rate can be maintained unchanged to its initial set value.
In a 62nd aspect according to any one of aspects from 40th to 61st the step of calculating the updated set of values comprises maintaining the value of said patient fluid removal rate unchanged to its initial set value.
In a 63rd aspect according to any one of aspects from 40th to 62nd the step of calculating the updated set of values comprises receive an initial set value for the blood pump flow rate and to control said blood pump accordingly, and wherein the step of calculating said updated set of values comprises maintaining the value of the blood pump flow rate unchanged to its initial value.
In a 64th aspect according to any one of the preceding aspects from 40th to 62nd the process comprises:
In a 65th aspect according to any one of the preceding aspects from 40th to 64th the process comprises detecting if a treatment mode is selected where use is made of said/a pre-blood pump infusion line for infusing a regional anticoagulant (such as for instance a citrate based solution), and in the affirmative, preventing from entering in dose control mode.
In a 66th aspect according to any one of the preceding aspects from 40th to 65th said flow rate update procedure further comprises:
In a 67th aspect according to any one of the preceding aspects from 40th to 66th said flow rate update procedure further comprises:
calculating a maximum achievable dose within said safety criteria, and controlling said means for regulating to achieve said maximum achievable dose.
In a 68th aspect according to any one of the preceding aspects from 40th to 67th said process further comprises:
In a 69th aspect according to any one of the preceding aspects from 40th to 68th said flow rate update procedure further comprises:
In a 70th aspect according to the preceding aspect wherein, after receipt of said second value, the updated set of values is calculated based upon:
In a 71st aspect a data carrier including instructions executable by a control unit of a blood treatment apparatus is provided. The instructions are configured such that, when executed by the control unit, they cause execution of the process according to any one of the preceding aspects from 40th to 70th.
In a 72nd aspect according to the preceding aspect the data carrier can be any support suitable for storing data, such as by way of non-limiting example: a RAM, a ROM, an EPROM, an optical or a magnetic disc, an electromagnetic wave, a mass memory storage device such as an Hard Disk or a flash memory bank.
Aspects of the invention are shown in the attached drawings, which are provided by way of non-limiting example, wherein:
In fact, the apparatus 1 comprises a filtration unit 2 having a primary chamber 3 and a secondary chamber 4 separated by a semi-permeable membrane 5; depending upon the treatment the membrane of the filtration unit may be selected to have different properties and performances.
A blood withdrawal line 6 is connected to an inlet of the primary chamber 3, and a blood return line 7 is connected to an outlet of the primary chamber 3. In use, the blood withdrawal line 6 and the blood return line 7 are connected to a needle or to a catheter or other access device (not shown) which is then placed in fluid communication with the patient vascular system, such that blood can be withdrawn through the blood withdrawal line, flown through the primary chamber and then returned to the patient's vascular system through the blood return line. An air separator, such as a bubble trap 8 can be present on the blood return line; moreover, a safety clamp 9 controlled by a control unit 10 can be present on the blood return line downstream the bubble trap 8. A bubble sensor 8a, for instance associated to the bubble trap 8 or coupled to a portion of the line 7 between bubble trap 8 and clamp 9 can be present: if present, the bubble sensor is connected to the control unit 10 and sends to the control unit signals for the control unit to cause closure of the clamp 9 in case one or more bubbles are detected. As shown in
Going back to
The dialysis fluid pump 21, the infusion fluid pump 15 and the effluent fluid pump 17 are part of means for regulating the flow of fluid through the respective lines and, as mentioned, are operatively connected to the control unit 10 which controls the pumps as it will be in detail disclosed herein below. The control unit 10 is also connected to the user interface 12, for instance a graphic user interface, which receives operator's inputs and displays the apparatus outputs. For instance, the graphic user interface 12 can include a touch screen, a display screen and hard keys for entering user's inputs or a combination thereof.
The embodiment of
The apparatus of
Of course other configurations could be possible and the solutions of
In the present specification, dose is a flow rate or to a combination of flow rates. For example, one of the following magnitudes can be used as dose for the purpose of the present invention:
where: S (effective surface area) is dependent on the hemodialyzer (as filtration unit 2) in use; RT is total mass transfer resistance dependent of the hemodialyzer in use (membrane properties, filter design) and the solute of interest; and Qpwinlet is the plasma water flow rate at the inlet of the filtration unit 2.
where: S (effective surface area) is dependent on the hemodialyzer in use; Qfil=Qpbp+Qrep+Qpfr (again, Qpfr represents the patient fluid removal rate, Qrep is the flow rate through the infusion line or lines connected directly to the patient or connected to the blood circuit downstream the blood pump and Qpbp is the flow rate through the pre-blood pump infusion line); and Qpwinlet is the plasma water flow rate at the inlet of the filtration unit 2.
When referring to any one of the above defined doses a distinction is also over:
In the course of the following description reference will be made to the above dose definitions which are relating to doses not normalized to patient body weight (BW) or patient surface area (A). Of course the same principles and formulas below described could be normalized to body weight or patient surface area by dividing the dose value by either body weight BW or surface area A.
Normalized Dose=Dose/BW
or
NDose=Dose/A×1.73 (when normalised to a 1.73 m2 surface area patient)
Furthermore, the above defined doses could be corrected to take into account the predilution effect, when a fluid replacement line is present upstream the treatment unit, such as lines 15 and 22 in the enclosed drawings. Each of the above defined doses could be corrected multiplying the dose value times a dilution factor Fdilution:
Dosecorr
The dilution factor Fdilution can be defined according to one of the following:
Plasma dilution factor:
Plasma water dilution factor:
Where Qpre is the total predilution infusion rate (where two infusion lines are present upstream the treatment unit, as lines 15 and 22, Qpre combines PBP infusion 15 and pre-replacement infusion 22)
In practice, the effluent dose corrected for the predilution effect would be: Dosecorr
As to the urea dose, a first expression assumes that filter Urea clearance (K_urea) is more or less identical to effluent flow rate. As urea is distributed in whole blood and can transfer quickly through the red blood cells membrane, the most relevant correction factor to consider for predilution shall refer to whole blood. Accordingly:
Of course, more sophisticated equations could provide for a more accurate estimate of K_urea than Qeff, especially when operating with large flow rates or small filters (pediatric conditions).
As to the clearance dose an expression of dose based on the clearance of a given solute can be considered. Fdilution factor shall be selected according to the solute distribution and ability to move through red blood cell (RBC) membrane (example: creatinin has slow diffusion through RBC, thus plasma dilution factor Fdilution
Depending upon the design choice, the prescribed dose can be either entered by the operator at the beginning of the treatment or it can be calculated at the beginning of the treatment based on initial set values for one or more flow rates through the lines of the blood treatment machine
In one aspect, the control unit 10 is configured to display on the screen 12a of the user interface 12 a number of indicia, including: an indicium 30 prompting a user to select whether to enter in a “dose control mode”, one or more indicia 31 prompting the user to select among a plurality of “treatment modes” such as by way of non limiting example among one or more of hemodialysis (hereinafter HD), hemofiltration with pre-dilution (hereinafter HFpre), hemofiltration with post-dilution (hereinafter HFpost), hemofiltration with both pre-dilution and post-dilution (hereinafter HFpre-post), hemodiafiltration with pre-dilution (hereinafter HDFpre), hemodiafiltration with post-dilution (hereinafter HDFpost), hemodiafiltration with both pre-dilution and post-dilution (hereinafter HDFpre-post), ultrafiltration (hereinafter UF), etcetera. In practice, if the user interface comprises a touch screen 29, the indicia 30 and 31 can be selected touch sensitive areas or buttons on the touch screen surface. The control unit may be configured to allow first selection of the treatment and then selection as to whether or not entering in “dose control mode”. Of course the opposite sequence can be possible too. An exemplifying sequence of steps that the control unit is configured or programmed to execute is shown in
In a first alternative shown in
First alternative: the user enters the set flow rates through 3 of the 4 lines and the control unit calculates the set average dose and the set value for the 4th flow rate based on the 3 entered flow rate set values.
Assuming the user enters the following set values (step 42):
QB=200 ml/min
Qdial=2000 ml/h
Qrep=1000 ml/h
Qpfr=100 ml/h
Then, the control unit would calculate the set value for the effluent line (step 45):
Q
eff
=Q
dial
+Q
rep
+Q
pfr=3100 ml/h
The above value for Qeff would then be assigned as (step 44) the prescribed hourly effluent dose Dset eff to be delivered through the entire patient treatment which can last few days.
In a second alternative (the differences with respect to the first alternative are represented in FIG. 3 with dashed lines), after steps 40 and 41, the control unit can be configured to display on the user interface an indicium prompting a user to select the dose option (step 42) and an indicium prompting (step 43a) to enter: the prescribed dose for the selected dose option, the blood pump flow rate QB and of the patient fluid removal rate Qpfr (step 44a). For instance, if the user entered in dose control mode and selected the effluent fluid dose as dose option, then the control unit may be programmed to request the user to enter the prescribed dose Dset eff, the value of the blood pump flow rate QB and of the patient fluid removal rate Qpfr. The control unit can then be configured to calculate the set values of the other flow rates (Qdial, Qrep, Qeff) at step 45a.
Assuming the user enters the following values:
Dset eff=Dose effluent=3200 ml/h as prescribed dose of effluent to be kept as mean value across the entire treatment.
QB=200 ml/min
Qpfr=100 ml/h
Then, the control unit would calculate the set values for flow rates through the various lines (step 45a) as a function of the set dose, of the patient fluid removal rate and of a pre-determined algorithm. Using the above figures, the control unit would set the effluent flow rate to an initial set value Qeff=3200 ml/h and then determine the dialysis fluid flow initial set value Qdial and the infusion flow initial set value Qrep dividing, e.g. in two equal parts, the difference Qeffluent−Qpfr, thus obtaining 1550 ml/h for each of Qdial and Qrep (of course other pre-stored rules could be applied).
In a third alternative (not shown in
Irrespective of which one of the above alternatives is followed, the control unit 10 is configured to assign set initial values to one or more fluid flow rates (step 46 in
The control unit is also configured to periodically (e.g. at check intervals of 2 or 3 or 4 hours after start of the treatment, see step 48) execute a flow rate update procedure (step 49). Note that the control unit can also be configured to run a first update procedure immediately before start of the treatment. Once the flow rate update procedure has been completed the various pumps are controlled with the new and updated flow rates (step 50) until a next time interval has passed. When a further time interval Ti has passed (step 51) a new flow rate update procedure (step 49) is run and new updated values for controlling the pumps calculated (step 50). The loop of steps 49, 50, 51 is then cyclically repeated.
The update procedure (step 49) is designed in order to make sure that the prescribed dose for the selected dose option (e.g. the effluent dose Deff) is actually achieved across a reference time interval, as it will explained herein below. The reference time interval may be set at 48 hours and a plurality of check points separated by check intervals are provided during the reference time; at each check point the control unit is configured to run the flow rate update procedure.
More in detail the control unit can be configured to regularly execute, e.g. periodically, at check points Ti during treatment, a flow rate update procedure (step 49) comprising the following steps:
The above update procedure can be iteratively repeated at time intervals.
Below a short description of an algorithm for iterative adjustments of the flow rate setting in order to achieve the set dose across a reference time. In below example, which makes reference to
Typical values for time windows are: Tretro=Tprosp=24 hours. Thus the time interval of reference is basically 48 hours as mentioned above.
The computations steps, which can be periodically re-iterated, are the following:
In the calculation of the updated set of values, the control unit can additionally be programmed to estimate an effective portion Teff of said next time period Tprosp during which treatment will be actually delivered to the patient. The estimation of the effective portion Teff of the remaining treatment time allows the control unit to account for possible down times, or period of no treatment delivery (bag changes, disposable changes, alarms, etc. that may cause temporary stop of treatment delivery as either the blood flow of the flow in one or more fluid lines is interrupted) which may occur in the future and which may, however, be statistically forecasted with a certain degree of accuracy. Thus, the control unit can be configured to also consider and estimate the effective run time of pumps Teff to be expected over the coming time period Tprosp. The determination of Teff is explained in a separate section here below.
In the case of effluent dose:
This means that an effluent flow rate change (ΔQeff=Deff
In one aspect, the change ΔQeff can be balanced over Dialysate and Replacement flow rates only
In an alternative aspect, the change ΔQeff can be balanced over all 3 flow rates: namely, PBP, Dialysate and Replacement flow rates.
In a further alternative aspect, the change ΔQeff can be balanced over one of PBP, Dialysate and Replacement flow rates.
Moreover, the splitting of ΔQeff can be done according to different rules; for instance: ΔQeff/N change could be equally split on each of the N selected flows. Alternatively ΔQeff could be split by keeping the current Dial/Rep ratio:
ΔQdial=ΔQeff×Qdial/(Qdial+Qrep)
ΔQrep=ΔQeff×Qrep/(Qdial+Qrep)
Estimating ‘future’ down times is the process needed to get Teff. The control unit is configured to execute such process. Several types of down-times can be estimated:
CVVHDF treatment initially prescribed with:
Volume of dialysate and replacement solution containers (e.g. solution bags) are Vdial=Vrep=5000 ml
Effluent is collected in bags of volume Veff=8000 ml
At the time T0 of Teff estimation, the set has been already in use for 65 hours and has to be changed after 72 hours. Treatment interruption time related to a change of set (Tchange
Tprosp=24 hours.
Over the time period Tretro=24 hours a total effluent volume of 72 000 ml has been collected, meaning a delivered dose D_del=72000/24=3000 ml/h
Doseneed over Tprosp is then:
In this example, the constant correction coefficient K is representative of the 2nd item (alarms) of the list presented in the section “down times”.
Time spent in therapy/run mode over time window Tprosp: Trun=Tprosp−Tchange_set
Treatment time lost because of alarms: Tdownalarms=Kalarms×Trun, where Kalarms=0.01 has a statistical definition.
Treatment time lost because of bag changes: Tdownbags=Tdownbag
Number of bag change for Dialysate:
Similar formula for number of bag changes on Replacement and Effluent lines.
The time required for changing a bag (from statistical analysis) can be: Tchange_bag=2 min
Final expression of down time related to bags:
Effective run time during time window Tprosp:
Teff=Trun−Tdownalarms−Tdownbags
(Instantaneous) effluent flow to be set to achieve the delivery of Dose_need over Tprosp time:
The last equation (for Qeff1) includes the term T_eff, which is a function of effluent flow rate and other flows. A numerical iterative method will easily solve the set of equations and provide for the Qeff1 value. Before achieving this, the rule for changing Dial and Rep flow in correlation to the required Eff flow change is to be chosen.
Below results for the given example are computed with the rule:
Solutions to the example:
Thus, more in general, the effective portion of the remaining treatment time can be calculated as a function of a number of K factors, which can at least in part be statistically determined, as explained in the section “down times”. Once the effective treatment time is determined, the control unit is configured to calculate, at a certain instant t during treatment, said updated flows based on: the dose need, which depends upon the delivered dose and the prescribed dose, the effective treatment time portion Teff.
Then the control unit will control the means for regulating the flow rate, e.g. pumps 21 and 18 in the example of
The control unit can also be configured to run a flow update procedure in case there is a change in the Dose prescription. In practice, the control unit detects the change in prescription and runs the flow update procedure thereafter.
In an aspect, an update of floe parameters is performed immediately after a change of dose prescription.
Parameters of previous example 2 are revisited in the case where the flow update is triggered by a change of prescribed dose.
Unchanged parameters (settings before T0):
CVVHDF treatment initially prescribed with:
Volume of dialysate and replacement solution containers (e.g. solution bags) are Vdial=Vrep=5000 ml.
Effluent is collected in bags of volume Veff=8000 ml.
At the time T0, the set has been already in use for 65 hours and has to be changed after 72 hours. Treatment interruption time related to a change of set (Tchange
Tprosp=24 hours.
At the time T0, dose prescription is moved to: Doseeff1=3500 ml/h.
Over the time period Tretro=24 hours a total effluent volume of 72 000 ml has been collected, meaning a delivered dose Ddel=72000/24=3000 ml/h
Dose needed over Tprosp is then:
Equations are exactly the same as in previous example.
With the new value of Doseneed, flow rates solutions become:
Note: flow computation keeping the planned change set at 72 h as in previous example 2
For the next periodic flow updates (period ΔT), the computation of dose gap over time period Tretro needs to consider the change of prescription.
Dose gap has to be computed over each time period with constant dose.
Continuation of previous example with following additional data:
Flow rate solutions are:
Note: flow computation keeping the planned change set at 72 h as in previous example 2(T1=T0+4 h=69 h<72 h)
Although the above examples focused on the case of the dose being the effluent fluid dose Deff, the control unit is configured to give the operator several dose options, as already mentioned, namely:
In general the flow rates update procedure takes into account for the dose option and for the selected treatment.
Then the control unit is configured to receive a set prescription for the hourly dose of e.g. the effluent fluid (step 43a) and set values for the blood flow QB and patient fluid removal rate QPFR rate (step 44a) and to receive or calculate initial set values for the dialysis and replacement fluid flow rates (45a). At step 46 and 47, the above rates are set as initial values and implemented by the control unit controlling the respective pumps. Periodically (see steps 48) a flow rate update procedure (step 61), e.g. comprising steps as described in above section “flow rate update procedure” is executed. Moreover, each time new updated values of the flow rates are calculated as above described, the control unit will run a safety check to make sure that the new flow rates are compatible with certain safety criteria (step 62): for instance each set flow rate cannot pass a respective maximum threshold value; moreover, the variation between the values of each updated flow rate and the respective previous flow rate (which can be one of the initial flow rates or a previously updated flow rate value) should preferably not be excessive and is also controlled to be below a respective threshold.
Furthermore, the control unit 10 can be configured to also calculate a maximum achievable dose (step 63) within said safety criteria, and to assess whether said prescribed dose can be reached. In the affirmative, the control unit can be configured to control the means for regulating the flow rates such as to achieve the prescribed dose within the prescribed time interval. Alternatively, the control unit could be configured to control the means for regulating the flow rates to achieve the maximum dose possible within said prescribed time interval in a manner compatible with the safety criteria.
If, instead, it is determined that the prescribed dose is higher than the maximum achievable dose, then the control unit is programmed to calculate a remaining dose as a difference between the prescribed dose and the maximum dose actually achievable within the prescribed time interval. As mentioned, the control unit is designed to control the apparatus in term of flow rates, thus after a number of check points it may be possible to recover the any remaining dose accumulated in previous time intervals (step 66).
As a further safety measure, or in alternative to the safety criteria above described, the control unit may be programmed to display on the user interface 12 the calculated updated set of values for said flow rates, and to prompt user to confirm the updated set of values (step 64) for said flow rates before using the updated values for controlling the means for regulating (step 65). If the user approves the updated set of values, then the control unit 10 is programmed to use the updated flow rate values as new set values for controlling the means for regulating the fluid flow through the fluid flow lines. In practice, referring to the example of
The step of calculating updated values of the flow rates is affected by the selected dose option and by the type of apparatus and treatment mode selected. For instance if the effluent dose is the dose option and if the treatment mode is a pure HF (i.e. there is no dialysis liquid container), then the flow rate update procedure will not generate an updated dialysis fluid flow rate. In one embodiment, where both the infusion line and the dialysis line are used (HDF configuration), the step of calculating the updated set of values comprises calculating an updated infusion pump flow rate and an updated dialysis pump flow rate, as above described with reference to
In a configuration where the apparatus comprises both a pre-dilution and a post-dilution line the control unit can be configured for calculating an updated infusion pump flow rate by calculating an updated pre-dilution pump flow rate and an updated post-dilution pump flow rate: the updated pre-dilution pump flow rate and the updated post-dilution pump fluid flow rate may differ from their respective initial values by a same percentage.
It should be noted that the control unit is configured during the flow update procedure to leave the set blood pump flow rate unchanged to its initial set value.
In accordance with a further aspect, which may be additional or alternative to one or more of the above disclosed aspects, the control unit 10 is programmed to allow a user to vary the initial value for the dose of the substance. In this case, the control unit is programmed to receive the new dose value (step 67) and to calculate corresponding updated values for the flow rates through the fluid flow lines in order to arrive as close as possible and possibly match said new dose value.
For instance, a first value for the prescribed dose (D0) can be entered before treatment start (T0); then after a while (instant Tt) from treatment start, a second different value of the prescribed dose (D1) to be reached can be entered. In this case, the control unit, after receipt of said second value, is configured to calculate the updated set of values based upon:
In making the calculation, the control unit can also be programmed to account for the fraction of dose Dt already delivered at time Tt and for the effective remaining treatment time K*(T−Tt).
Going into the description of further aspects of the apparatus of
From a structural point of view one or more, optionally all containers 14, 16, 20, 23 may be disposable plastic containers, preferably bags which are hang on a support carried by the respective scale. All lines and the filtration unit may also be plastic disposable components which can be mounted at the beginning of the treatment session and then disposed of at the end of the treatment session. The means for regulating typically may comprise pumps, although other regulating means as valves or combinations of valves and pumps could be used. The scales may comprise piezoelectric sensors, or strain gauges, or spring sensors, or any other type of transducer able to sense forces applied thereon. Although the examples in the figures show use of scales for determining the amount of fluid in the respective containers and for allowing calculation of the respective flow rates through the various lines, it should be noted that the above described aspects of the invention are compatible also with blood treatment machines using volumetric sensors for determining flow rates or combinations of mass and volumetric sensors.
Number | Date | Country | Kind |
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10010805.9 | Sep 2010 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2011/002098 | 9/8/2011 | WO | 00 | 6/10/2013 |