JPWO2020223524A5 - - Google Patents

Description

[Invention 1001]
A system for operating an intra-aortic balloon pump comprising:
at least one intra-aortic balloon pump positioned near the patient's heart;
at least one controller configurablely connected to the at least one intra-aortic balloon pump;
including
the at least one controller includes at least one processor and at least one non-transitory memory;
The at least one controller is
Initializing the value of one or more parameters based on the identity of the patient;
receiving a first electrocardiogram signal of the patient;
generating a first power spectrum signal by decomposing the received first electrocardiogram signal;
selecting a first portion of the generated first power spectrum signal;
one or more including the selected first portion of the generated first power spectrum signal, a sub-portion of the selected first portion of the generated first power spectrum signal split into subsets,
for each subset in the one or more subsets of the selected first portion of the generated first power spectrum signal;
calculating peak values of the sub-portions of the selected first portion of the first power spectrum signal within the subset;
storing the calculated peak value of the subset in a first threshold buffer;
calculating a first adaptive threshold R peak value based on the calculated peak value stored in the first threshold buffer
configured as
system.
[Invention 1002]
at least one controller
receiving a second electrocardiogram signal of the patient;
generating a second power spectrum signal by decomposing the received second electrocardiogram signal;
selecting a first portion of the generated second power spectrum signal;
one or more including the selected first portion of the generated second power spectrum signal, a sub-portion of the selected first portion of the generated second power spectrum signal split into a second subset,
for each subset in the one or more second subsets of the selected first portion of the generated second power spectrum signal;
calculating peak values of the sub-portions of the selected first portion of the second power spectrum signal within the subset;
storing the calculated peak values of the subset in a second threshold buffer;
calculating a second adaptive threshold R peak value based on the calculated peak value stored in the second threshold buffer
The system of the present invention 1001, further configured to:
[Invention 1003]
1003. The system of invention 1002, wherein the at least one controller is further configured to update the first adaptive threshold Rpeak value based on the second adaptive threshold Rpeak value.
[Invention 1004]
at least one controller
by applying the calculated first adaptive threshold Rpeak value or the calculated second adaptive threshold Rpeak value, or both, to the generated second power spectrum signal. determining whether the second electrocardiogram signal includes a QRS complex;
when the received electrocardiogram signal is determined to include a QRS complex, the calculated first adaptive threshold Rpeak value, or the calculated second adaptive threshold Rpeak value, or both calculating an R-R time interval value indicative of the timing between two consecutive R peaks in consecutive QRS complexes in the patient's received second electrocardiogram signal based on
The system of the present invention 1002, further configured to:
[Invention 1005]
Further, at least one controller generates a prediction of the timing of future R-peaks based on the calculated R-R time interval values indicative of the timing between two consecutive R-peaks in consecutive QRS complexes. The system of the invention 1004, configured.
[Invention 1006]
1006. The system of invention 1005, wherein the at least one controller is further configured to induce inflation of the at least one intra-aortic balloon pump based on the generated prediction of the timing of future R-peaks.
[Invention 1007]
at least one skin interface device configurablely connected to at least one intra-aortic balloon pump and configurablely connected to at least one controller;
further comprising
the at least one controller is further configured to receive a patient identity and a set of patient-specific information from the at least one skin interface device;
The system of the invention 1001.
[Invention 1008]
The first power spectrum signal is
applying at least one transform signal to decompose the received first electrocardiogram signal into discrete frequency signals;
selecting one or more portions of the discrete frequency signal; and
calculating the first power spectrum signal by aligning one or more portions of the selected discrete frequency signal;
The system of the invention 1001 produced by:
[Invention 1009]
1009. The system of the invention 1008, wherein at least one transform signal is based on Haar wavelets.
[Invention 1010]
the calculated power signal is based on a first selected portion of the discrete frequency signal and a second selected portion of the discrete frequency signal;
the first selected portion of the discrete frequency signal is in a first frequency range from 15.625 Hz to 31.25 Hz;
the second selected portion of the discrete frequency signal is in a second frequency range from 7.8125 Hz to 15.625 Hz;
The system of the invention 1008.
[Invention 1011]
1002. The system of invention 1001, wherein the first portion of the generated first power spectrum signal spans 7.5 seconds.
[Invention 1012]
1003. The system of invention 1002, wherein the first portion of the generated second power spectrum signal spans 7.5 seconds.
[Invention 1013]
1002. The system of invention 1001, wherein each subset in the one or more subsets of the selected first portion of the generated first power spectrum signal spans 1.5 seconds.
[Invention 1014]
1003. The system of invention 1002, wherein each subset in the one or more second subsets of the selected first portion of the generated second power spectrum signal spans 1.5 seconds.
[Invention 1015]
One or more parameters
the patient's first and last name,
age of the patient,
patient's average heart rate,
patient's maximum heart rate,
patient's minimum heart rate,
patient's pulse,
patient's mean R-R time interval,
patient's maximum R-R time interval,
the patient's minimum R-R time interval,
patient's mean R peak,
patient's maximum R peak,
patient's minimum R peak,
or any combination of these
The system of the present invention 1001, comprising:
[Invention 1016]
A computer-implemented method for operating an intra-aortic balloon pump, comprising:
initializing the value of one or more parameters based on patient identity;
receiving a first electrocardiogram signal of the patient;
generating a first power spectrum signal by decomposing the received first electrocardiogram signal;
selecting a first portion of the generated first power spectrum signal;
one or more including the selected first portion of the generated first power spectrum signal, a sub-portion of the selected first portion of the generated first power spectrum signal dividing into subsets;
for each subset in the one or more subsets of the selected first portion of the generated first power spectrum signal;
calculating peak values of the sub-portions of the selected first portion of the first power spectrum signal within the subset; and
storing the calculated peak values of the subset in a first threshold buffer; and
calculating a first adaptive threshold R peak value based on the calculated peak value stored in the first threshold buffer;
A computer-implemented method, comprising:
[Invention 1017]
receiving a second electrocardiogram signal of the patient;
generating a second power spectrum signal by decomposing the received second electrocardiogram signal;
selecting a first portion of the generated second power spectrum signal;
one or more including the selected first portion of the generated second power spectrum signal, a sub-portion of the selected first portion of the generated second power spectrum signal dividing into a second subset;
for each subset in the one or more second subsets of the selected first portion of the generated second power spectrum signal;
calculating peak values of the sub-portions of the selected first portion of the second power spectrum signal within the subset; and
storing the calculated peak values of the subset in a second threshold buffer; and
calculating a second adaptive threshold R peak value based on the calculated peak value stored in the second threshold buffer;
a computer-implemented method of the invention 1016, further comprising:
[Invention 1018]
updating the first adaptive threshold Rpeak value based on the second adaptive threshold Rpeak value;
a computer-implemented method of the invention 1017, further comprising:
[Invention 1019]
by applying the calculated first adaptive threshold Rpeak value or the calculated second adaptive threshold Rpeak value, or both, to the generated second power spectrum signal. determining whether the second electrocardiogram signal includes a QRS complex; and
when the received electrocardiogram signal is determined to include a QRS complex, the calculated first adaptive threshold Rpeak value, or the calculated second adaptive threshold Rpeak value, or both calculating an R-R time interval value indicative of the timing between two consecutive R peaks in consecutive QRS complexes in the patient's received second electrocardiogram signal based on
a computer-implemented method of the invention 1017, further comprising:
[Invention 1020]
A computer-implemented method for operating an intra-aortic balloon pump, comprising:
initializing the value of one or more parameters based on patient identity;
receiving a first electrocardiogram signal of the patient;
generating a first power spectrum signal by decomposing the received first electrocardiogram signal;
selecting a first portion of the generated first power spectrum signal;
one or more including the selected first portion of the generated first power spectrum signal, a sub-portion of the selected first portion of the generated first power spectrum signal dividing into subsets;
for each subset in the one or more subsets of the selected first portion of the generated first power spectrum signal;
calculating peak values of the sub-portions of the selected first portion of the first power spectrum signal within the subset; and
storing the calculated peak values of the subset in a first threshold buffer;
calculating a first adaptive threshold R peak value based on the calculated peak values stored in the first threshold buffer;
receiving a second electrocardiogram signal of the patient;
generating a second power spectrum signal by decomposing the received second electrocardiogram signal;
selecting a first portion of the generated second power spectrum signal;
one or more including the selected first portion of the generated second power spectrum signal, a sub-portion of the selected first portion of the generated second power spectrum signal dividing into a second subset;
for each subset in the one or more second subsets of the selected first portion of the generated second power spectrum signal;
calculating peak values of the sub-portions of the selected first portion of the second power spectrum signal within the subset; and
storing the calculated peak values of the subset in a second threshold buffer;
calculating a second adaptive threshold R peak value based on the calculated peak value stored in the second threshold buffer;
in the patient's received second electrocardiogram signal based on the calculated first adaptive threshold Rpeak value, or the calculated second adaptive threshold Rpeak value, or both calculating an R-R time interval value indicating the timing between two consecutive R peaks in consecutive QRS complexes;
generating a prediction of the timing of future R-peaks based on the calculated R-R time interval values indicative of the timing between two consecutive R-peaks in consecutive QRS complexes;
Inducing inflation of at least one intra-aortic balloon pump based on the generated prediction of the timing of future R-peaks.
A computer-implemented method, comprising:

Claims (34)

A system for operating an intra-aortic balloon pump comprising:
at least one intra-aortic balloon pump configured to be placed near the patient's heart;
at least one controller configurablely connected to the at least one intra-aortic balloon pump;
the at least one controller includes at least one processor and at least one non-transitory memory;
The at least one controller is
Initializing the value of one or more parameters based on the identity of the patient;
receiving a first electrocardiogram signal of the patient;
generating a first power spectrum signal by decomposing the received first electrocardiogram signal;
selecting a first portion of the generated first power spectrum signal;
one or more including the selected first portion of the generated first power spectrum signal, a sub-portion of the selected first portion of the generated first power spectrum signal split into subsets,
for each subset in the one or more subsets of the selected first portion of the generated first power spectrum signal;
calculating peak values of the sub-portions of the selected first portion of the first power spectrum signal within the subset;
storing the calculated peak value of the subset in a first threshold buffer;
calculating a first adaptive threshold R peak value based on the calculated peak value stored in the first threshold buffer ;
receiving a second electrocardiogram signal of the patient;
generating a second power spectrum signal by decomposing the received second electrocardiogram signal;
selecting a first portion of the generated second power spectrum signal;
one or more including the selected first portion of the generated second power spectrum signal, a sub-portion of the selected first portion of the generated second power spectrum signal split into a second subset,
for each subset in the one or more second subsets of the selected first portion of the generated second power spectrum signal;
calculating peak values of the sub-portions of the selected first portion of the second power spectrum signal within the subset;
storing the calculated peak values of the subset in a second threshold buffer;
calculating a second adaptive threshold R peak value based on the calculated peak value stored in the second threshold buffer;
by applying the calculated first adaptive threshold Rpeak value or the calculated second adaptive threshold Rpeak value, or both, to the generated second power spectrum signal. determining whether the second electrocardiogram signal includes a QRS complex;
when the received electrocardiogram signal is determined to include a QRS complex, the calculated first adaptive threshold Rpeak value, or the calculated second adaptive threshold Rpeak value, or both calculating an RR time interval value indicative of the timing between two consecutive R peaks in consecutive QRS complexes in the patient's received second electrocardiogram signal based on; and
Inducing at least one of inflation and deflation of the at least one intra-aortic balloon pump based on the RR time interval value
configured as
system. 2. The system of claim 1 , wherein the at least one controller is further configured to update the first adaptive threshold Rpeak value based on the second adaptive threshold Rpeak value. Further such that the at least one controller generates a prediction of the timing of future R-peaks based on the calculated RR time interval values indicative of the timing between two consecutive R-peaks in consecutive QRS complexes. 11. The system of claim 1 , configured. the at least one controller is further configured to induce at least one of inflation and deflation of the at least one intra-aortic balloon pump based on the generated prediction of the timing of future R-peaks; 4. The system of claim 3 . further comprising at least one skin interface device configurablely connected to the at least one intra-aortic balloon pump and configurablely connected to the at least one controller;
the at least one controller is further configured to receive a patient identity and a set of patient-specific information from the at least one skin interface device;
The system of Claim 1. decomposing the received first electrocardiogram signal;
applying at least one transform signal to decompose the received first electrocardiogram signal into discrete frequency signals;
selecting one or more portions of the discrete frequency signal; and calculating the first power spectrum signal by aligning one or more portions of the selected discrete frequency signal.
2. The system of claim 1, comprising : 7. The system of claim 6 , wherein at least one transform signal is based on Haar wavelets. wherein the calculated first power spectrum signal is based on a first selected portion of a discrete frequency signal and a second selected portion of the discrete frequency signal;
the first selected portion of the discrete frequency signal is in a first frequency range from 15.625 Hz to 31.25 Hz;
the second selected portion of the discrete frequency signal is in a second frequency range from 7.8125 Hz to 15.625 Hz;
7. The system of claim 6 . 2. The system of claim 1, wherein the first portion of the generated first power spectrum signal spans 7.5 seconds. 2. The system of claim 1 , wherein the first portion of the generated second power spectrum signal spans 7.5 seconds. 2. The system of claim 1, wherein each subset in the one or more subsets of the selected first portion of the generated first power spectrum signal spans 1.5 seconds. 2. The system of claim 1 , wherein each subset in the one or more second subsets of the selected first portion of the generated second power spectrum signal spans 1.5 seconds. One or more parameters
the patient's first and last name,
age of the patient,
patient's average heart rate,
patient's maximum heart rate,
patient's minimum heart rate,
patient's pulse,
patient's mean RR time interval,
patient's maximum RR time interval,
patient's minimum RR time interval,
patient's mean R peak,
patient's maximum R peak,
patient's minimum R peak,
or any combination thereof. A computer-implemented method for operating an intra-aortic balloon pump, comprising:
initializing the value of one or more parameters based on patient identity;
receiving a first electrocardiogram signal of the patient;
generating a first power spectrum signal by decomposing the received first electrocardiogram signal;
selecting a first portion of the generated first power spectrum signal;
one or more including the selected first portion of the generated first power spectrum signal, a sub-portion of the selected first portion of the generated first power spectrum signal dividing into subsets;
for each subset in the one or more subsets of the selected first portion of the generated first power spectrum signal;
calculating a peak value of the sub-portion of the selected first portion of the first power spectrum signal within the subset; and storing the calculated peak value of the subset in a first threshold buffer. the process of memorizing ,
calculating a first adaptive threshold R peak value based on the calculated peak value stored in the first threshold buffer;
receiving a second electrocardiogram signal of the patient;
generating a second power spectrum signal by decomposing the received second electrocardiogram signal;
selecting a first portion of the generated second power spectrum signal;
one or more including the selected first portion of the generated second power spectrum signal, a sub-portion of the selected first portion of the generated second power spectrum signal dividing into a second subset;
for each subset in the one or more second subsets of the selected first portion of the generated second power spectrum signal;
calculating peak values of the sub-portions of the selected first portion of the second power spectrum signal within the subset; and
storing the calculated peak values of the subset in a second threshold buffer;
calculating a second adaptive threshold R peak value based on the calculated peak value stored in the second threshold buffer;
by applying the calculated first adaptive threshold Rpeak value or the calculated second adaptive threshold Rpeak value, or both, to the generated second power spectrum signal. determining whether the second electrocardiogram signal includes a QRS complex;
when the received electrocardiogram signal is determined to include a QRS complex, the calculated first adaptive threshold Rpeak value, or the calculated second adaptive threshold Rpeak value, or both and calculating an RR time interval value indicative of the timing between two consecutive R peaks in consecutive QRS complexes in the received second electrocardiogram signal of the patient, based on
Inducing at least one of inflation and deflation of the at least one intra-aortic balloon pump based on the RR time interval value.
A computer-implemented method, comprising: 15. The computer-implemented method of claim 14 , further comprising updating the first adaptive threshold Rpeak value based on the second adaptive threshold Rpeak value. A computer-implemented method for operating an intra-aortic balloon pump, comprising:
initializing the value of one or more parameters based on patient identity;
receiving a first electrocardiogram signal of the patient;
generating a first power spectrum signal by decomposing the received first electrocardiogram signal;
selecting a first portion of the generated first power spectrum signal;
one or more including the selected first portion of the generated first power spectrum signal, a sub-portion of the selected first portion of the generated first power spectrum signal dividing into subsets;
for each subset in the one or more subsets of the selected first portion of the generated first power spectrum signal;
calculating a peak value of the sub-portion of the selected first portion of the first power spectrum signal within the subset; and storing the calculated peak value of the subset in a first threshold buffer. the process of memorizing,
calculating a first adaptive threshold R peak value based on the calculated peak values stored in the first threshold buffer;
receiving a second electrocardiogram signal of the patient;
generating a second power spectrum signal by decomposing the received second electrocardiogram signal;
selecting a first portion of the generated second power spectrum signal;
one or more including the selected first portion of the generated second power spectrum signal, a sub-portion of the selected first portion of the generated second power spectrum signal dividing into a second subset;
for each subset in the one or more second subsets of the selected first portion of the generated second power spectrum signal;
calculating a peak value of the sub-portion of the selected first portion of the second power spectrum signal within the subset; and storing the calculated peak value of the subset in a second threshold buffer. the process of memorizing,
calculating a second adaptive threshold R peak value based on the calculated peak value stored in the second threshold buffer;
by applying the calculated first adaptive threshold Rpeak value, or the calculated second adaptive threshold Rpeak value, or both to the generated second power spectrum signal; determining whether the received second electrocardiogram signal includes a QRS complex;
the calculated first adaptive threshold Rpeak value or the calculated second adaptive threshold Rpeak value when the received second electrocardiogram signal is determined to include a QRS complex; or based on both, calculating an RR time interval value indicative of the timing between two consecutive R peaks in consecutive QRS complexes in the patient's received second electrocardiogram signal;
generating a prediction of the timing of future R-peaks based on the calculated RR time interval values indicative of the timing between two consecutive R-peaks in consecutive QRS complexes; A computer-implemented method comprising inducing at least one of inflation and deflation of at least one intra-aortic balloon pump based on a prediction of R-peak timing. Resolving the received second electrocardiogram signal includes:
applying at least one transform signal to decompose the received second electrocardiogram signal into second discrete frequency signals;
selecting one or more portions of the second discrete frequency signal;
calculating the second power spectrum signal by aligning one or more portions of the selected second discrete frequency signal;
2. The system of claim 1, comprising: wherein the calculated second power spectrum signal is based on a first selected portion of the second discrete frequency signal and a second selected portion of the second discrete frequency signal;
the first selected portion of the second discrete frequency signal is in a first frequency range from 15.625 Hz to 312.25 Hz;
the second selected portion of the second discrete frequency signal is in a second frequency range from 7.8125 Hz to 15.625 Hz;
18. The system of claim 17. Resolving the received first electrocardiogram signal includes:
applying at least one transform signal to decompose the received first electrocardiogram signal into discrete frequency signals;
selecting one or more portions of the discrete frequency signal;
calculating the first power spectrum signal by aligning one or more portions of the selected discrete frequency signal;
15. The computer-implemented method of claim 14, comprising: wherein the calculated first power spectrum signal is based on a first selected portion of the discrete frequency signal and a second selected portion of the discrete frequency signal;
the first selected portion of the discrete frequency signal is in a first frequency range from 15.625 Hz to 31.25 Hz;
the second selected portion of the discrete frequency signal is in a second frequency range from 7.8125 Hz to 15.625 Hz;
20. The computer-implemented method of claim 19. The second power spectrum signal is
applying at least one transform signal to decompose the received second electrocardiogram signal into second discrete frequency signals;
selecting one or more portions of the second discrete frequency signal;
calculating the second power spectrum signal by aligning one or more portions of the selected second discrete frequency signal;
15. The computer-implemented method of claim 14, generated by: wherein the calculated second power spectrum signal is based on a first selected portion of the second discrete frequency signal and a second selected portion of the second discrete frequency signal;
the first selected portion of the second discrete frequency signal is in a first frequency range from 15.625 Hz to 31.25 Hz;
the second selected portion of the second discrete frequency signal is in a second frequency range from 7.8125 Hz to 15.625 Hz;
22. The computer-implemented method of claim 21. Resolving the received first electrocardiogram signal includes:
applying at least one transform signal to decompose the received first electrocardiogram signal into discrete frequency signals;
selecting one or more portions of the discrete frequency signal;
calculating the first power spectrum signal by aligning one or more portions of the selected discrete frequency signal;
17. The computer-implemented method of claim 16, comprising: wherein the calculated first power spectrum signal is based on a first selected portion of the discrete frequency signal and a second selected portion of the discrete frequency signal;
the first selected portion of the discrete frequency signal is in a first frequency range from 15.625 Hz to 31.25 Hz;
the second selected portion of the discrete frequency signal is in a second frequency range from 7.8125 Hz to 15.625 Hz;
24. The computer-implemented method of Claim 23. The second power spectrum signal is
applying at least one transform signal to decompose the received second electrocardiogram signal into second discrete frequency signals;
selecting one or more portions of the second discrete frequency signal;
calculating the second power spectrum signal by aligning one or more portions of the selected second discrete frequency signal;
25. The computer-implemented method of claim 24, generated by: wherein the calculated second power spectrum signal is based on a first selected portion of the second discrete frequency signal and a second selected portion of the second discrete frequency signal;
the first selected portion of the second discrete frequency signal is in a first frequency range from 15.625 Hz to 31.25 Hz;
the second selected portion of the second discrete frequency signal is in a second frequency range from 7.8125 Hz to 15.625 Hz;
26. The computer-implemented method of Claim 25. The at least one controller is
Get multiple additional R-R time interval values,
triggering at least one of inflation and deflation of the at least one intra-aortic balloon pump based on the median of the most recent set of R-R time interval values;
The system of Claim 1. The at least one controller is
generating a prediction of future R-peak timing based on the median of the set of most recent R-R time interval values;
Inducing at least one of inflation and deflation of the at least one intra-aortic balloon pump based on the generated prediction of the timing of future R-peaks.
28. The system of claim 27, further configured to: 28. The system of claim 27, wherein the set of latest R-R time interval values is the five latest R-R time interval values. obtaining a plurality of additional R-R time interval values;
inducing at least one of inflation and deflation of the at least one intra-aortic balloon pump based on the median of the most recent set of R-R time interval values;
15. The computer-implemented method of claim 14, further comprising: generating a prediction of the timing of future R-peaks based on the median of the most recent set of R-R time interval values;
triggering at least one of inflation and deflation of the at least one intra-aortic balloon pump based on the generated prediction of future R-peak timing;
31. The computer-implemented method of claim 30, further comprising: 31. The computer-implemented method of claim 30, wherein the set of most recent R-R time interval values is five most recent R-R time interval values. obtaining a plurality of additional R-R time interval values;
generating a prediction of the timing of future R-peaks based on the median of the most recent set of R-R time interval values;
15. The computer-implemented method of claim 14, further comprising: 34. The computer-implemented method of claim 33, wherein the set of most recent R-R time interval values is five most recent R-R time interval values.