Accelerometer-based multi-axis physical activity sensor for a rate-responsive pacemaker and method of fabrication

US 5,425,750 A
Filed: 07/14/1993
Issued: 06/20/1995
Est. Priority Date: 07/14/1993
Status: Expired due to Term

First Claim

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1. A multi-axis physical activity sensor for a rate-responsive pacemaker, comprising:

transducing means for providing a signal indicative of physical activity occurring in directions along a plurality of axes, said transducing means comprising a cantilever beam having a fixed end and a free end, the cantilever beam including a material having an electrical characteristic that varies measurably when said cantilever beam experiences mechanical stresses, the free end deflecting in response to bodily accelerations associated with physical activity, thereby inducing said mechanical stresses in said cantilever beam, said transducing means further comprising a mass disposed on said free end of said cantilever beam and substantially offset with respect to a planar surface of said cantilever beam for imparting multi-axis sensitivity to said sensor;

locking means for securing said mass onto said free end of said cantilever beam; and

conducting means for communicating said signal provided by said transducing means to circuitry of said rate-responsive pacemaker.

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Abstract

An accelerometer-based, multi-axis physical activity sensor for use with a rate-responsive pacemaker, and a method for fabricating the sensor, are provided. The multi-axis physical activity sensor includes a cantilever beam having a film of a piezoelectric polymer adhered to each surface of an electrically conductive substrate. The piezoelectric films are highly resistant to fracturing during manufacture and in use, and they provide a strong output signal when stressed in response to bodily accelerations. A mass is mounted to a free end of the cantilever beam, and is substantially offset with respect to a planar surface of the beam so as to impart multi-axis sensitivity to the physical activity sensor. The accelerometer-based, multi-axis physical activity sensor provides an output signal that is communicated to pacemaker circuitry using a pair of electrical conductors.

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40 Claims

1. A multi-axis physical activity sensor for a rate-responsive pacemaker, comprising:
- transducing means for providing a signal indicative of physical activity occurring in directions along a plurality of axes, said transducing means comprising a cantilever beam having a fixed end and a free end, the cantilever beam including a material having an electrical characteristic that varies measurably when said cantilever beam experiences mechanical stresses, the free end deflecting in response to bodily accelerations associated with physical activity, thereby inducing said mechanical stresses in said cantilever beam, said transducing means further comprising a mass disposed on said free end of said cantilever beam and substantially offset with respect to a planar surface of said cantilever beam for imparting multi-axis sensitivity to said sensor;
  
  locking means for securing said mass onto said free end of said cantilever beam; and
  
  conducting means for communicating said signal provided by said transducing means to circuitry of said rate-responsive pacemaker.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The sensor of claim 1, wherein said transducing means is responsive to physical activity occurring in directions along a plurality of perpendicular axes.
  - 3. The sensor of claim 1, wherein said conducting means comprises a pair of electrical conductors which communicate said signal to said circuitry of said rate-responsive pacemaker.
  - 4. The sensor of claim 1, wherein said locking means comprises a mass mount and a mass backing which lock said mass onto said free end of said cantilever beam.
  - 5. The sensor of claim 1, wherein said material comprises a first film of a piezoelectric polymer that causes electrical potentials to appear across first and second surfaces of said cantilever beam when said cantilever beam experiences said mechanical stresses.
  - 6. The sensor of claim 5, wherein said cantilever beam comprises an electrically conductive beam substrate, and said first film is adhered to a first surface of said beam substrate.
  - 7. The sensor of claim 6, wherein said material further comprises a second film of said piezoelectric polymer adhered to a second surface of said beam substrate.
  - 8. The sensor of claim 1, wherein said conducting means comprises first and second electrically conductive support members which conduct said signal to said circuitry of said rate-responsive pacemaker and mechanically support said cantilever beam so as to prevent said sensor from tipping toward the free end of the cantilever beam when the sensor rests unsecured.
  - 9. The sensor of claim 8, wherein said first and second electrically conductive support members contact, respectively, first and second surfaces of said cantilever beam at said fixed end.
  - 10. The sensor of claim 9, wherein said first and second electrically conductive support members support said cantilever beam so that said cantilever beam is orthogonally oriented with respect to said substrate.
  - 11. The sensor of claim 10, further comprising:
    - a nonconductive mount that includes a slot within which regions of said first and second electrically conductive support members and said fixed end of said cantilever beam are disposed; and
      
      retaining clip means disposed on said mount for causing said mount to urge said first and second electrically conductive support members against, respectively, said first and second surfaces of said cantilever beam.

12. An accelerometer-based multi-axis physical activity sensor for providing a signal indicative of bodily accelerations associated with physical activity to circuitry of an implantable cardiac stimulating device, said sensor comprising:
- a substrate;
  
  means, mounted to said substrate, for providing said signal in accordance with mechanical stresses experienced by said means for providing which are induced by bodily accelerations associated with physical activity, said providing means comprising;
  
  a cantilever beam having a fixed end and a free end, the cantilever beam including a material having an electrical characteristic that varies measurably when said cantilever beam experiences said mechanical stresses, the free end deflecting in response to bodily accelerations associated with physical activity, thereby inducing said mechanical stresses in said cantilever beam;
  
  means, mechanically coupled to said means for providing, for imparting multi-axis sensitivity to said means for providing said imparting means comprising;
  
  a mass disposed on said free end of said cantilever beam and substantially offset with respect to a planar surface of said cantilever beam for imparting multi-axis sensitivity to said sensor; and
  
  locking means for securing said mass onto said free end of said cantilever beam; and
  
  means for conducting said signal from said means for providing to said circuitry of said implantable cardiac stimulating device.
- View Dependent Claims (13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 28)
- - 13. The sensor of claim 12, wherein said means for providing is responsive to bodily accelerations associated with physical activity along a plurality of perpendicular axes.
  - 14. The sensor of claim 12, wherein said means for conducting comprises a pair of electrical conductors which communicate said signal to said circuitry of said implantable cardiac stimulating device.
  - 15. The sensor of claim 12, wherein said locking means comprises a mass mount and a mass backing which lock said mass onto said free end of said cantilever beam.
  - 16. The sensor of claim 12, wherein said material comprises a first film of a piezoelectric polymer that causes electrical potentials to appear across first and second surfaces of said cantilever beam when said cantilever beam experiences said mechanical stresses.
  - 17. The sensor of claim 16, wherein said cantilever beam comprises an electrically conductive beam substrate, and said first film is adhered to a first surface of said beam substrate.
  - 18. The sensor of claim 17, wherein said material further comprises a second film of said piezoelectric polymer adhered to a second surface of said beam substrate.
  - 19. The sensor of claim 12, wherein said means for conducting comprises first and second electrically conductive support members which communicate said signal to said circuitry of said implantable cardiac stimulating device and mechanically support said cantilever beam on the substrate.
  - 20. The sensor of claim 19, wherein said first and second electrically conductive support members contact, respectively, first and second surfaces of said cantilever beam at said fixed end.
  - 21. The sensor of claim 20, wherein said first and second electrically conductive support members support said cantilever beam so that said cantilever beam is orthogonally oriented with respect to said substrate.
  - 22. The sensor of claim 21 further comprising:
    - a nonconductive mount that includes a slot within which regions of said first and second electrically conductive support members and said fixed end of said cantilever beam are disposed; and
      
      retaining clip means disposed on said mount for causing said mount to urge said first and second electrically conductive support members against, respectively, said first and second surfaces of said cantilever beam.
  - 28. The pacemaker of claim 21, further comprising a hybrid, and said transducing means is anchored to said hybrid.

23. A method of fabricating a multi-axis physical activity sensor for use with a rate-responsive pacemaker, comprising the steps of:
- forming a transducing element incorporating a material having an electrical characteristic that varies measurably when said transducing element experiences mechanical stresses in response to bodily accelerations associated with physical activity along a plurality of axes comprising the steps of;
  
  fabricating said transducing element in the form of a cantilever beam comprising the steps of;
  
  providing an electrically conductive beam substrate;
  
  adhering a first film of a piezoelectric polymer to a first surface of said beam substrate;
  
  attaching a mass to a first end of said cantilever beam, so as to be substantially offset with respect to a planar surface of said cantilever beam; and
  
  providing a conductive path for communicating a signal representative of said varying electrical characteristic from said transducing element to circuitry of said pacemaker.
- View Dependent Claims (24, 25, 26)
- - 24. The method of claim 23, wherein said providing step comprises attaching a pair of electrical conductors to said transducing element, which communicate said signal to said circuitry of said pacemaker.
  - 25. The method of claim 23, wherein said fabricating step further comprises the step of adhering a second film of said piezoelectric polymer to a second surface of said beam substrate.
  - 26. The method of claim 23, wherein said securing step comprises the steps of inserting said second end of said cantilever beam between first and second electrically conductive support members.

27. A rate-responsive pacemaker, comprising:
- pulse generating means for generating pacing pulses at an adjustable rate;
  
  control means, coupled to said pulse generating means, for determining the rate at which said pulse generating means generates said pacing pulses in accordance with physical activity; and
  
  transducing means for providing a signal to said control means indicative of physical activity occurring in directions along a plurality of axes, said transducing means comprising a cantilever beam having a fixed end and a free end, the cantilever beam including a material having an electrical characteristic that varies measurably when said cantilever beam experiences mechanical stresses, said material comprising a first film of a piezoelectric polymer that causes electrical potentials to appear across first and second surfaces of said cantilever beam when said cantilever beam experiences mechanical stresses, wherein the free end deflects in response to bodily accelerations associated with physical activity, thereby inducing said mechanical stresses in said cantilever beam, and wherein said transducing means further comprises a mass disposed on said free end of said cantilever beam and substantially offset with respect to a planar surface of said cantilever beam.
- View Dependent Claims (29, 30, 31, 32, 33, 34, 35)
- - 29. The pacemaker of claim 27, further comprising a battery support, wherein said transducing means is disposed within said battery support.
  - 30. The pacemaker of claim 27, wherein said cantilever beam comprises an electrically conductive beam substrate, and said first film is adhered to a first surface of said beam substrate.
  - 31. The pacemaker of claim 30, wherein said material further comprises a second film of said piezoelectric polymer adhered to a second surface of said beam substrate.
  - 32. The pacemaker of claim 27, further comprising first and second electrically conductive support members which communicate said signal provided by said transducing means and mechanically support said cantilever beam on a substrate.
  - 33. The pacemaker of claim 32, wherein said first and second electrically conductive support members contact, respectively, first and second surfaces of said cantilever beam at said fixed end.
  - 34. The pacemaker of claim 33, wherein said first and second electrically conductive support members support said cantilever beam so that said cantilever beam is orthogonally oriented with respect to said substrate.
  - 35. The pacemaker of claim 34, further comprising:
    - a nonconductive mount that includes a slot within which regions of said first and second electrically conductive support members and said fixed end of said cantilever beam are disposed; and
      
      retaining clip means disposed on said mount for causing said mount to urge said first and second electrically conductive support members against, respectively, said first and second surfaces of said cantilever beam.

36. A physical activity sensor for use in a rate-responsive pacemaker comprising:
- transducer means for generating a signal indicative of physical activity, comprising a cantilever beam having a fixed end and a free end, the cantilever beam deflecting in response to body accelerations associated with physical activity, thereby inducing mechanical stresses in the cantilever beam, the cantilever beam including a piezoelectric polymer film having first and second surfaces, across which an electrical potential is developed as a function of the mechanical stresses, such electrical potentials furnishing said signal indicative of physical activity, the cantilever beam including a mass disposed on the free end thereof and offset from a planar surface of such cantilever beam for imparting multi-axis sensitivity to the physical activity sensor.
- View Dependent Claims (37, 38, 39)
- - 37. The physical activity sensor of claim 36, further comprising conductor means for conducting said signal to desired circuitry in the rate-responsive pacemaker, the conductor means comprising first and second support members, the first and second support members being electrically conductive and in electrical communication with said first and second surfaces, respectively, the support members further for supporting the cantilever beam so as to prevent said sensor from tipping toward the free end of the cantilever beam when the sensor rests unsecured.
  - 38. The physical activity sensor of claim 37, wherein the piezoelectric polymer film comprises first and second piezoelectric polymer films joined together to thereby form a composite piezoelectric polymer film.
  - 39. The physical activity sensor of claim 38, further comprising a beam substrate disposed between the first and second piezoelectric polymer films in sandwich-like fashion.

40. A physical activity sensor for use in a rate-responsive pacemaker comprising:
- transducer means for generating a signal indicative of physical activity, comprising a cantilever beam having a fixed end and a free end, the cantilever beam deflecting in response to body accelerations associated with physical activity, thereby inducing mechanical stresses in the cantilever beam, the cantilever beam having first and second surfaces, the cantilever beam including means for generating an electrical potential across said first and second surfaces as a function of the mechanical stresses, such electrical potentials being a measure of said signal indicative of physical activity; and
  
  conductor means for conducting said signal to desired circuitry in the rate responsive pacemaker, the conductor means comprising first and second support members, the first and second support members being electrically conductive and in electrical communication with said first and second surfaces, respectively, the support members further for supporting the cantilever beam so as to prevent said sensor from tipping toward the free end of the cantilever beam when the sensor rests unsecured.

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Current Assignee
Pacesetter Incorporated (Abbott Laboratories Incorporated)
Original Assignee
Pacesetter Incorporated (Abbott Laboratories Incorporated)
Inventors
Moberg, Sheldon B.
Primary Examiner(s)
Howell, Kyle L.
Assistant Examiner(s)
SCHAETZLE, KENNEDY

Application Number

US08/091,850
Time in Patent Office

706 Days
Field of Search

607/2, 607/9, 607/19, 607/36, 607/17, 128/774, 128/782, 128/739, 128/740, 128/670, 310/348, 310/338, 310/339, 73/517 R, 73/517 AV
US Class Current

607/19
CPC Class Codes

A61N 1/36542 controlled by body motion, ...

G01P 15/18 in two or more dimensions

Accelerometer-based multi-axis physical activity sensor for a rate-responsive pacemaker and method of fabrication

First Claim

3 Assignments

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Abstract

176 Citations

40 Claims

Specification

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Accelerometer-based multi-axis physical activity sensor for a rate-responsive pacemaker and method of fabrication

First Claim

3 Assignments

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0 Petitions

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Accused Products

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Abstract

176 Citations

40 Claims

Specification

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Use Cases

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Others