Claims
- 1.-13. (canceled)
- 14. A system for detecting the concentration of analyte in a fluid test sample which comprises an electrochemical sensor for detecting the concentration of analyte in a fluid test sample, the sensor comprising a base which provides a flow path for the fluid test sample having on its surface a counter electrode and a working electrode in electrical communication with a detector of electrical current, a reaction layer on the surface of at least the working electrode comprising an enzyme which reacts with the analyte to produce electrons that are transferred to the working electrode, and a cover which when mated with the base member forms a capillary space with an opening for the introduction of fluid test sample thereto which space contains the flow Path for the fluid test sample in which the counter and working electrodes are situated so that the major portion of the counter electrode is located downstream of the opening from the working electrode with a sub-element of the counter electrode being upstream of the working electrode so that when electrical communication between only the sub-element and working electrode takes Place there is insufficient flow of electrical current through the detector to constitute a valid test for the concentration of analyte in the fluid test sample and the detector is preprogrammed to emit an error signal in the event of such insufficient flow of electrical current,
wherein the sensor is in electrical connection with a meter which has been algorithmically programmed to a) make multiple current measurements at different time periods when a driving potential is applied between the electrodes, b) convert the multiple current measurements into error checking parameters and c) check the values of these parameters against their corresponding tolerance bands to determine if a short fill has occurred.
- 15. The system of claim 14 wherein the analyte is glucose and the system is programmed to apply a 0.4V potential for 10 seconds after the fluid test sample is applied, which is a first 10-second period, open the circuit so as to create OV potential for 10 seconds, which is a second 10-second period, apply a 0.4V potential for 10 seconds, which is a third 10-second period, and
A) make a current measurement at the end of the first 10 second period which is designated as Ib10, 5 seconds into the third 10 second period designated as Ir5 and at the end of the third 10 second period designated as Ir10, B) determine the decay factor which describes the shape of the current time course by solving the equation: 5k=ln(Ir5)-ln(Ir 10)ln(10)-ln(5)and the Read-to-Burn ratio, (R/B) by solving the equation: R/B=Ir10/Ib10 C) check the values of the decay factor and the Read-to-Burn ratio against their tolerance limits for k as:
Condition 1 (Decay factor checking): 6if&LeftBracketingBar;k-(ak 1+bk 1 · G)&RightBracketingBar;>wk is true when G≤dk 1, orif&LeftBracketingBar;k-(ak 2+bk 2 · G)&RightBracketingBar;>wk is true when dk 1<G≤dk 2, orif&LeftBracketingBar;k-(ak 3+bk 3 · G)&RightBracketingBar;>wk is true when G>dk 2where ak1, ak2, ak3, bk1, bk2, bk3, Wk, dk1, dk2, and dk3 are predetermined constants, G is the glucose measurement, and for R/B as: Condition 2 (R/B ratio checking): if|R/B−(ac1+bc1·G)|>wc is true when G≦dc, or if|R/B−(ac2+bc2·G)|>wc is true when G>dc where ac1, ac2, bc1, bc2, wc, and dc are predetermined constants, G is the glucose measurement, and D) conclude that there has been a short fill if either Condition 1 or Condition 2 is true.
BACKGROUND OF THE INVENTION
[0001] This is a Continuation-In-Part of co-pending application Ser. No. 09/731,943 filed Dec. 8, 20001 which is in turn a Continuation-In-Part of co-pending application Ser. No. 09/366,269, filed on August 2, 1999.
Continuation in Parts (2)
|
Number |
Date |
Country |
Parent |
09731943 |
Dec 2000 |
US |
Child |
09861437 |
May 2001 |
US |
Parent |
09366269 |
Aug 1999 |
US |
Child |
09731943 |
Dec 2000 |
US |