Rate-responsive implantable stimulation device having a miniature hybrid-mountable accelerometer-based sensor and method of fabrication

US 5,383,473 A
Filed: 05/10/1993
Issued: 01/24/1995
Est. Priority Date: 05/10/1993
Status: Expired due to Term

First Claim

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1. An accelerometer for providing a signal indicative of bodily accelerations associated with physical activity to circuitry in an implantable cardiac stimulating device, the accelerometer comprising:

transducing element means for generating a signal in accordance with mechanical stresses resulting from deflections of the free end of the transducing element caused by the bodily accelerations, wherein the transducing element means comprises;

a cantilever beam having a fixed end and a free end and including a material having an electrical characteristic that varies measurably when the cantilever beam experiences mechanical stresses; and

supporting means for securing the fixed end and for enabling the free end to deflect in response to the bodily accelerations, the supporting means having means for preventing the accelerometer from tipping toward the free end of the transducing element when the accelerometer rests unsecured, wherein the supporting means comprises;

a first electrically conductive support member in contact with a first surface of the cantilever beam at the fixed end; and

a second electrically conductive support member substantially interposed between the first support member and the free end, the second support member having means for supporting the free end without restricting the deflections caused by the bodily accelerations.

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Abstract

A miniature, hybrid-mountable, accelerometer-based, physical activity sensor for use with a rate-responsive implantable stimulation device is provided. The physical activity sensor is constructed as 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 pair of electrically conductive supports serve to anchor the physical activity sensor to a substrate and deliver the output signal provided by the sensor to circuitry within the rate-responsive implantable stimulation device. The physical activity sensor is adapted to be mounted directly to conductive traces on a suitable substrate, preferably an implantable stimulation device hybrid.

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24 Claims

1. An accelerometer for providing a signal indicative of bodily accelerations associated with physical activity to circuitry in an implantable cardiac stimulating device, the accelerometer comprising:
- transducing element means for generating a signal in accordance with mechanical stresses resulting from deflections of the free end of the transducing element caused by the bodily accelerations, wherein the transducing element means comprises;
  
  a cantilever beam having a fixed end and a free end and including a material having an electrical characteristic that varies measurably when the cantilever beam experiences mechanical stresses; and
  
  supporting means for securing the fixed end and for enabling the free end to deflect in response to the bodily accelerations, the supporting means having means for preventing the accelerometer from tipping toward the free end of the transducing element when the accelerometer rests unsecured, wherein the supporting means comprises;
  
  a first electrically conductive support member in contact with a first surface of the cantilever beam at the fixed end; and
  
  a second electrically conductive support member substantially interposed between the first support member and the free end, the second support member having means for supporting the free end without restricting the deflections caused by the bodily accelerations.
- View Dependent Claims (2, 3, 4, 5, 6, 7)
- - 2. The accelerometer of claim 1, wherein the second support member comprises:
    - an electrically conductive projection which contacts a second surface of the cantilever beam at the fixed end.
  - 3. The accelerometer of claim 1, wherein the supporting means further comprises:
    - nonconductive mount retainer means for interlocking the cantilever beam with the first support member and the projection for preventing slippage of the cantilever beam from the supporting means.
  - 4. The accelerometer of claim 3, wherein:
    - the nonconductive mount retainer means includes a housing having protruding radii and the cantilever beam, first and second support members each include regions defining indentations which conform in shape to the protruding radii, whereby the protruding radii of the nonconductive mount retainer means register with the indentations of the cantilever beam and first and second support members when the nonconductive mount retainer means is disposed on the fixed end.
  - 5. The accelerometer of claim 1, wherein the material comprises:
    - a first film of a piezoelectric polymer that causes an electrical potential to appear across first and second surfaces of the cantilever beam.
  - 6. The accelerometer of claim 5, wherein the cantilever beam comprises:
    - an electrically conductive beam substrate, and the first film is electrically connected to a first surface of the beam substrate.
  - 7. The accelerometer of claim 6, wherein the cantilever beam further comprises:
    - a second film of the piezoelectric polymer electrically connected to a second surface of the beam substrate, whereby the first and second films are connected in series.

8. An accelerometer for providing a signal indicative of bodily accelerations associated with physical activity to circuitry in an implantable cardiac stimulating device, the accelerometer comprising:
- transducing means for generating a signal in accordance with mechanical stresses caused by bodily accelerations, wherein the transducing means comprises 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 the cantilever beam experiences mechanical stresses; and
  
  a mass assembly disposed on the free end, which enhances the mechanical stresses experienced by the cantilever beam, wherein the mass assembly includes means for interlocking the mass assembly with the cantilever beam to prevent slippage of the cantilever beam from the mass assembly, wherein the mass assembly comprises nonconductive mass retainer means having protruding radii and a mass having regions defining indentations which conform in shape to the protruding radii; and
  
  the cantilever beam comprises regions defining indentations which also conform in shape to the protruding radii, whereby the protruding radii of the mass retainer register with the indentations of the mass and with the indentations of the cantilever beam when the mass assembly is disposed on the free end; and
  
  supporting means for securing the fixed end and for enabling the free end to deflect in response to bodily accelerations, the supporting means having means for preventing the accelerometer from tipping toward the free end of the transducing element when the accelerometer rests unsecured.

9. An accelerometer-based physical activity sensor suitable for use in a rate-responsive implantable stimulation device, the sensor comprising:
- a cantilever beam having a fixed end and a free end, and including a piezoelectric polymer which causes electrical potentials to appear across first and second surfaces of the cantilever beam when the cantilever beam experiences mechanical stresses caused by bodily accelerations;
  
  a first electrically conductive support member in contact with the first surface of the cantilever beam at the fixed end; and
  
  a second electrically conductive support member substantially interposed between the first support member and the free end, the second support member being positioned with respect to the first support member and the free end of the cantilever beam so as to prevent the sensor from tipping toward the free end of the cantilever beam when the sensor rests unsecured.
- View Dependent Claims (10, 11, 12, 13, 14, 15, 16, 17)
- - 10. The sensor of claim 9, wherein the cantilever beam comprises:
    - an electrically conductive beam substrate; and
      
      a first film of the piezoelectric polymer is electrically connected to a first surface of the beam substrate.
  - 11. The sensor of claim 10, wherein the cantilever beam further comprises:
    - a second film of the piezoelectric polymer electrically connected to a second surface of the beam substrate;
      
      whereby the first and second films of piezoelectric polymer are connected in series.
  - 12. The sensor of claim 9, wherein the first and second electrically conductive support members include:
    - means for electrically connecting the first and second surfaces of the cantilever beam to conduct the electrical potentials to circuitry within the implantable stimulation device through the first and second contact pads, respectively, of the hybrid substrate.
  - 13. The sensor of claim 12, wherein the second support member includes:
    - an electrically conductive projection which contacts the second surface of the cantilever beam at the fixed end.
  - 14. The sensor of claim 13, wherein the supporting structure comprises:
    - nonconductive mount retainer means for interlocking the cantilever beam with the first support member and the projection to prevent slippage of the cantilever beam from the supporting structure.
  - 15. The sensor of claim 14, wherein:
    - the nonconductive mount retainer includes a housing having protruding radii; and
      
      the cantilever beam, the first and second support members includes regions defining indentations which conform in shape to the protruding radii;
      
      whereby the protruding radii of the nonconductive mount retainer register with the indentations of the cantilever beam, the first and second support members when the nonconductive mount retainer is disposed on the fixed end.
  - 16. The sensor of claim 9, further comprising:
    - a mass assembly disposed on the free end of the cantilever beam for enhancing the mechanical stresses experienced by the cantilever beam, wherein the mass assembly includes means for interlocking the mass assembly with the cantilever beam to prevent slippage of the cantilever beam from the mass assembly.
  - 17. The sensor of claim 16, wherein:
    - the mass assembly comprises a mass retainer having protruding radii and a mass having regions defining indentations which conform in shape to the protruding radii; and
      
      the cantilever beam comprises regions defining indentations which also conform in shape to the protruding radii;
      
      whereby the protruding radii of the mass retainer register with the indentations of the mass and with the indentations of the cantilever beam when the mass assembly is disposed on the free end of the cantilever beam.

18. A method of fabricating a physical activity sensor for use with a rate-responsive implantable stimulation device, comprising the steps of:
- forming a cantilever beam incorporating a material having an electrical characteristic that varies measurably when the transducing element experiences mechanical stresses in response to bodily accelerations associated with physical activity;
  
  securing a first end of the cantilever beam between a first electrically conductive support member of a support structure and an electrically conductive projection extending from a second electrically conductive support member of the support structure; and
  
  interposing the second support member between the first support member and a second end of the cantilever beam to permit the second end to deflect in response to the bodily accelerations and to prevent the sensor from tipping toward the second end when the sensor rests unsecured on a microelectronic substrate.
- View Dependent Claims (19, 20)
- - 19. The method of claim 18, wherein the forming step further comprises the steps of:
    - providing an electrically conductive beam substrate; and
      
      adhering a first film of piezoelectric polymer to a first surface of the beam substrate.
  - 20. The method of claim 19, wherein the forming step further comprises the step of:
    - adhering a second film of piezoelectric polymer to a second surface of the beam substrate so that the first and second film of piezoelectric polymer are electrically connected in series through the conductive beam.

22. The method of claim 22, further comprising the step of:
- interlocking a symmetrical mass assembly to a second end of the cantilever beam to enhance the mechanical stresses experienced by the cantilever beam.
- View Dependent Claims (21, 23)
- - 21. The method of claim 22, further comprising the step of:
    - interlocking the first end of the cantilever beam with the first support member and the projection using a nonconductive mount retainer to prevent the cantilever beam from slipping from the support structure.
  - 23. The method of claim 22, wherein the interlocking step comprises the steps of:
    - providing indentations in a mass;
      
      providing indentations in the cantilever beam; and
      
      attaching the mass to the second end of the cantilever beam using a nonconductive mass retainer having protruding radii which register with indentations in the mass and the cantilever beam.

24. A body motion detecting accelerometer for mounting on a desired flat surface in a pacemaker, the accelerometer comprising:
- first and second supports for supporting the accelerometer on the desired flat surface;
  
  a cantilever beam having a fixed end and a free end, the fixed end being secured to the first support, the beam comprising beam material having first and second sides, such sides having electrical characteristics that vary as a function of mechanical stresses induced in the beam material caused by deflections of the beam, said first support being electrically coupled to the first side of the beam material, the first support having a support portion for contact with the desired flat surface, said second support being mechanically coupled to the first support and electrically coupled to the second side of the beam material, the second support having a support portion depending from the first support for contact with the desired flat surface; and
  
  a mass coupled to the free end of the cantilever beam, the beam material being of sufficient rigidity to maintain the mass freely suspended, the beam material deflecting under the load created by the mass resulting from bodily accelerations associated with physical activity.

Specification

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Litigation Campaign Assessment

Current Assignee
Pacesetter Incorporated (Abbott Laboratories)
Original Assignee
Pacesetter Incorporated (Abbott Laboratories)
Inventors
Moberg, Sheldon B.
Primary Examiner(s)
Kamm, William E.
Assistant Examiner(s)
SCHAETZLE, KENNEDY

Application Number

US08/059,698
Time in Patent Office

624 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

600/595
CPC Class Codes

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

Rate-responsive implantable stimulation device having a miniature hybrid-mountable accelerometer-based sensor and method of fabrication

First Claim

2 Assignments

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24 Claims

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Rate-responsive implantable stimulation device having a miniature hybrid-mountable accelerometer-based sensor and method of fabrication

First Claim

2 Assignments

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Accused Products

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Abstract

Citations

24 Claims

Specification

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Solutions

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