Method and device for monitoring analyte concentration by determining its progression in the living body of a human or animal

US 7,650,244 B2
Filed: 02/15/2007
Issued: 01/19/2010
Est. Priority Date: 04/24/2004
Status: Active Grant

First Claim

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1. A device for continuous monitoring of an analyte concentration by determining its progression in the living body of a human or animal, comprising:

a measuring unit configured to produce a measurement signal that is indicative of a concentration of the analyte, andan analytical unit configured to correlate analyte values y(t_n) with the concentration of the analyte for consecutive points in time t_nbased on the measurement signal, the analytical unit further configured to determine a function F(t_k, t_k-Δ

n, t_k-2Δ

n, . . . , t_{k-(m-2) Δ

n}, t_{k-(m-1) Δ

n}), which depends on corresponding analyte values y(t_k), y(t_k-Δ

n), y(t_{k-2 Δ

n}), . . . , y(t_{k-(m-2) Δ

n}), y(t_{k-(m-1) Δ

n}), and which approximates the progression of the analyte values y(t_n) at time t_n0in a vicinity U of an analyte value y(t_n0) with a pre-determined accuracy σ

, such that

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Abstract

The present invention generally relates to a method and a device for monitoring an analyte concentration in the living body of a human or animal. In particular to a method and device for determining analyte values y(t_n) correlating with the concentration to be determined are determined for consecutive points in time t_n. The analyte values y(t_n) is used to predict a prediction value for an analyte y(t_n0+Δt) over a prediction period Δt.

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41 Claims

1. A device for continuous monitoring of an analyte concentration by determining its progression in the living body of a human or animal, comprising:
- a measuring unit configured to produce a measurement signal that is indicative of a concentration of the analyte, andan analytical unit configured to correlate analyte values y(t_n) with the concentration of the analyte for consecutive points in time t_nbased on the measurement signal, the analytical unit further configured to determine a function F(t_k, t_k-Δ
  
  n, t_k-2Δ
  
  n, . . . , t_{k-(m-2) Δ
  
  n}, t_{k-(m-1) Δ
  
  n}), which depends on corresponding analyte values y(t_k), y(t_k-Δ
  
  n), y(t_{k-2 Δ
  
  n}), . . . , y(t_{k-(m-2) Δ
  
  n}), y(t_{k-(m-1) Δ
  
  n}), and which approximates the progression of the analyte values y(t_n) at time t_n0in a vicinity U of an analyte value y(t_n0) with a pre-determined accuracy σ
  
  , such that
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20)
- - 2. The device according to claim 1, wherein the analytical unit is configured to determine the function F in a manner that depends not only on the analyte values y(t_k), y(t_k-Δ
    - n), y(t_k-2Δ
      
      n), . . . , y(t_{k-(m-2) Δ
      
      n}), y(t_{k-(m-1) Δ
      
      n}), but in addition on their first time derivatives.
  - 3. The device according to claim 1, wherein the analytical unit is configured to determine the function F in a manner that depends not only on the analyte values y(t_k), y(t_k-Δ
    - n), y(t_k-2Δ
      
      n), . . . , y(t_{k-(m-2) Δ
      
      n}), y(t_{k-(m-1) Δ
      
      n}), but in addition on their first and second time derivatives.
  - 4. The device according to claim 1, wherein the analytical unit is configured to include linear or square terms in the function F.
  - 5. The device according to claim 1, wherein the analytical unit is configured to determine the function F as a linear function.
  - 6. The device according to claim 1, wherein the analytical unit is configured to represent the function F by coefficients a₀to a_mas follows:
  - 7. The device according to claim 6, wherein the analytical unit is configured to determine the coefficients, a₀to a_m, by minimizing the sum
  - 8. The device according to claim 6, wherein the analytical unit is configured to determine the coefficients, a₀to a_m, by solving a system of linear equations which contains one equation each of the type
  - 9. The device according to claim 8, wherein the analytical unit is configured to determine the coefficients a₀to a_mby numerically solving the system of linear equations,and wherein the system of linear equations contains more than m+1 equations.
  - 10. The device according to claim 6, wherein the analytical unit is configured to determine the function F with the coefficients a₀to a_mranging in number between 4 and 11.
  - 11. The device according to claim 10, wherein the analytical unit is configured to determine the function F with the coefficients a₀to a_mranging in number between 6 and 9.
  - 12. The device according to claim 1, wherein the analytical unit is configured to obtain the analyte values y(t_n) used to determine the function F by numerical processing of measured values.
  - 13. The device according to claim 12 wherein the analytical unit is configured to filter the measured values in the numerical processing of the measured values.
  - 14. The device according to claim 1 wherein the analytical unit is further configured to define the function F(t_k, t_k-Δ
    - n, t_k-2Δ
      
      n, . . . , t_{k-(m-2) Δ
      
      n}, t_k-(m-1)Δ
      
      n) in a vicinity U of an analyte value y(t_n0+Δ
      
      t) at a point in time t_n=t_n0+Δ
      
      t for a calculated prediction value y(t_n0+Δ
      
      t), such that the defined function F approximates the progression of analyte values y(t_n) in the vicinity U with a predetermined accuracy and an additional prediction value y(t_n0+2Δ
      
      t) is calculated therefrom.
  - 15. The device according to claim 1, wherein the analytical unit is configured to determine the analyte values y(t_n), that are used calculate the prediction value, from consecutive points in time t_nwhich are separated by predefined time intervals.
  - 16. The device according to claim 15, wherein the analytical unit is configured to determine the analytical values y(t_n) from consecutive points in time t_nthat are separated by predefined time intervals within the range of 30 seconds to 5 minutes.
  - 17. The device according to claim 16, wherein the analytical unit is configured to determine the analytical values y(t_n) from consecutive points in time t_nthat are separated by predefined time intervals within the range of 1 to 3 minutes.
  - 18. The device according to claim 1, wherein the analytical unit is configured to determine the analyte values y(t_n), that are used to calculate the prediction value or one of the prediction values, for times t_nwhich are separated by an interval corresponding to the prediction period Δ
    - t.
  - 19. The device according to claim 1, wherein the analytical unit is further configured to determine the function F as a function of transformed coordinate values Ty(t_k), Ty(t_k-Δ
    - n), Ty(t_k-2Δ
      
      n), . . . , Ty(t_k-(m-2)Δ
      
      n), Ty(t_k-(m-1)Δ
      
      n), which transformed coordinate values are determined by a transformation from analyte values y(t_k), y(t_k-Δ
      
      n), y(t_k-2Δ
      
      n), . . . , y(t_{k-(m-2) Δ
      
      n}), y(t_{k-(m-1) Δ
      
      n}) in which at least one of the values Ty(t_k), Ty(t_k-Δ
      
      n), Ty(t_k-2Δ
      
      n), . . . , Ty(t_{k-(m-2) Δ
      
      n}), Ty(t_{k-(m-1) Δ
      
      n}) has a negligible influence on the function F at the predetermined accuracy σ
      
      .
  - 20. The device according to claim 19, wherein the analytical unit is configured to determine the transformed coordinate values using a linear transformation.

21. A method for continuous monitoring of an analyte concentration by determining its progression in the living body of a human or animal, comprising:
- receiving a measurement signal produced by a measuring unit that is indicative of a concentration of the analyte,determining analyte values y(t_n) correlating with the concentration of the analyte for consecutive points in time t_nbased on the measurement signal,determining a function F(t_k, t_k-Δ
  
  n, t_k-2Δ
  
  n, . . . , t_{k-(m-2) Δ
  
  n}, t_{k-(m-1) Δ
  
  n}), which depends on corresponding analyte values y(t_k), y(t_k-Δ
  
  n), y(t_k-2Δ
  
  n), . . . , y(t_{k-(m-2) Δ
  
  n}), y(t_{k-(m-1) Δ
  
  n}), and which approximates the progression of the analyte values y(t_n) at time t_n0in a vicinity U of an analyte value y(t_n0) with a pre-determined accuracy σ
  
  , such that
- View Dependent Claims (22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41)
- - 22. The method according to claim 21, wherein the function F depends not only on analyte values y(t_k), y(t_k-Δ
    - n), y(t_k-2Δ
      
      n), . . . , y(t_k-(m-2)Δ
      
      n), y(t_{k-(m-1) Δ
      
      n}), but in addition on their first time derivatives.
  - 23. The method according to claim 21, wherein the function F depends not only on analyte values y(t_k), y(t_k-Δ
    - n), y(t_k-2Δ
      
      n), . . . , y(t_k-(m-2)Δ
      
      n), y(t_{k-(m-1) Δ
      
      n}), but in addition on their first and second time derivatives.
  - 24. The method according to claim 21, wherein the function F contains linear or square terms.
  - 25. The method according to claim 21, wherein the function F is a linear function.
  - 26. The method according to claim 21, wherein the function F is represented by coefficients a₀to a_mas follows:
  - 27. The method according to claim 26, wherein the coefficients, a₀to a_m, are determined by minimizing the sum
  - 28. The method according to claim 26, wherein the coefficients, a₀to a_m, are determined by solving a system of linear equations which contains one equation each of the type
  - 29. The method according to claim 28, wherein the system of equations contains more than m+1 equations and is solved numerically by approximation to determine the coefficients a₀to a_m.
  - 30. The method according to claim 21, wherein the analyte values y(t_n) used to determine the function F are obtained by numerical processing of measured values.
  - 31. The method according to claim 30 wherein the numerical processing of measured values includes filtering the measured values.
  - 32. The method according to claim 21 further comprising configuring the function F(t_k, t_k-Δ
    - n, t_k-2Δ
      
      n, . . . , t_{k-(m-2) Δ
      
      n}, t_{k-(m-1) Δ
      
      n}) in a vicinity U of an analyte value y(t_n0+Δ
      
      t) at a point in time t_n=t_n0+Δ
      
      t for a calculated prediction value y(t_n0+Δ
      
      t), such that the configured function F approximates the progression of analyte values y(t_n) in the vicinity U with a predetermined accuracy and an additional prediction value y(t_n0+2Δ
      
      t) is calculated therefrom.
  - 33. The method according to claim 21, wherein the analyte values y(t_n) used to calculate the prediction value are determined from consecutive points in time t_nwhich are separated by predefined time intervals.
  - 34. The method according to claim 33, wherein the predefined time intervals are within the range of 30 seconds to 5 minutes.
  - 35. The method according to claim 34, wherein the predefined time intervals are within the range of 1 to 3 minutes.
  - 36. The method according to claim 21, wherein the analyte values y(t_n) used to calculate the prediction value or one of the prediction values are determined for times t_nwhich are separated by an interval corresponding to the prediction period Δ
    - t.
  - 37. The method according to claim 21, wherein the number of the coefficients a₀to a_mis within the range of 4 to 11.
  - 38. The method according to claim 37, wherein the number of the coefficients a₀to a_mis within the range of 6 to 9.
  - 39. The method according to claim 21, wherein the function F is determined as a function of transformed coordinate values Ty(t_k), Ty(t_k-Δ
    - n), Ty(t_k-2Δ
      
      n), . . . , Ty(t_k-(m-2)Δ
      
      n), Ty(t_k-(m-1)Δ
      
      n), which transformed coordinate values are determined by a transformation from analyte values y(t_k), y(t_k-Δ
      
      n), y(t_k-2Δ
      
      n), . . . , y(t_{k-(m-2) Δ
      
      n}), y(t_k-(m-1)Δ
      
      n) in which at least one of the values Ty(t_k), Ty(t_k-Δ
      
      n), Ty(t_k-2Δ
      
      n), . . . , Ty(t_{k-(m-2) Δ
      
      n}), Ty(t_k-(m-1)Δ
      
      n) has a negligible influence on the function F at the predetermined accuracy σ
      
      .
  - 40. The method according to claim 39, wherein the transformation is a linear transformation.
  - 41. The method according to claim 21, wherein the prediction value is produced as an output.

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Current Assignee
Roche Diabetes Care Inc. (Roche Holding AG)
Original Assignee
Roche Diagnostics Operations Incorporated (Roche Holding AG)
Inventors
Staib, Arnulf, Hegger, Rainer
Primary Examiner(s)
Lau; Tung S
Assistant Examiner(s)
SUN, XIUQIN

Application Number

US11/675,580
Publication Number

US 20070148778A1
Time in Patent Office

1,069 Days
Field of Search

702/14, 702/19, 702/22, 702/25, 702/177, 435/14, 436/95, 436/518, 250/573, 250/287, 600/345, 600/310
US Class Current

702/22
CPC Class Codes

A61B 5/14532 for measuring glucose, e.g....

Method and device for monitoring analyte concentration by determining its progression in the living body of a human or animal

First Claim

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Abstract

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41 Claims

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Method and device for monitoring analyte concentration by determining its progression in the living body of a human or animal

First Claim

1 Assignment

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Abstract

Citations

41 Claims

Specification

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