초록 ▼

An ambulatory medical device for detecting acceleration, temperature, and/or humidity conditions in or around the medical device is provided. The medical device includes one or more acceleration, thermal, and/or humidity sensors which detect acceleration, temperature, and/or humidity conditions in o

An ambulatory medical device for detecting acceleration, temperature, and/or humidity conditions in or around the medical device is provided. The medical device includes one or more acceleration, thermal, and/or humidity sensors which detect acceleration, temperature, and/or humidity conditions in or around the medical device. In response to detected conditions, the medical device may, among other things, alter the operation of the device, provide an alarm or warning to the user, or transmit data about the detected conditions to another device.

대표청구항 ▼

What is claimed is: 1. An external infusion device for infusing fluid into a person from a reservoir, comprising: a housing adapted to be carried on an exterior of the person; a drive mechanism contained in the housing and operatively coupled to the reservoir to deliver fluid from the reservoir int

What is claimed is: 1. An external infusion device for infusing fluid into a person from a reservoir, comprising: a housing adapted to be carried on an exterior of the person; a drive mechanism contained in the housing and operatively coupled to the reservoir to deliver fluid from the reservoir into the person; a processor contained in the housing; an indicator operatively coupled to the processor and adapted to provide at least one of a visual indication, an audible indication, or a tactile indication to indicate information about the infusion device to the person; and an acceleration sensor coupled to the processor and adapted to provide an acceleration output signal as a function of acceleration forces acting on the housing, wherein the acceleration sensor is an impact switch disposed within the housing, the impact switch comprising: an electrical input and an electrical output, an electrically conductive seismic mass having an anchored end and a free end, the mass being electrically coupled to the electrical output, the mass being coupled to the housing at the anchored end and adapted for resilient deflection in a first closing contact direction, and a first electrically conductive contact fixedly mounted adjacent to the mass, the first contact being electrically coupled to the electrical input, wherein the mass is adapted to deflect in the first closing contact direction from a first position to a second position, touch the first contact, and return from the second position to the first position such that a circuit between the electrical input and the electrical output is closed to provide the acceleration output signal when a first predetermined acceleration force acts on the housing; wherein the processor is adapted to control the infusion device in accordance with the acceleration output signal. 2. The external infusion device of claim 1, further comprising a memory contained in the housing and coupled to the processor, wherein the memory is adapted to store a predetermined acceleration threshold corresponding to an impact on the housing. 3. The external infusion device of claim 2, wherein if the acceleration output signal exceeds the predetermined acceleration threshold, the processor is adapted to control the infusion device by causing the indicator to provide an alarm or a warning to the person. 4. The external infusion device of claim 2, wherein if the acceleration output signal exceeds the predetermined acceleration threshold, the processor is adapted to control the infusion device by causing the drive mechanism to alter delivery of the fluid into the person. 5. The external infusion device of claim 2, further comprising a transmitter/receiver contained in the housing and coupled to the processor, wherein the transmitter/receiver is adapted to communicate with a remote device, and further wherein if the acceleration output signal exceeds the predetermined acceleration threshold, the processor is adapted to control the infusion device by causing the transmitter/receiver to send information about the impact to the remote device. 6. The external infusion device of claim 1, wherein the conductive seismic mass comprises: an electrically conductive arm member having a proximate end and a distal end, the arm member being coupled to the housing at the proximate end and adapted for resilient deflection in the first closing contact direction; and an electrically conductive impact head mounted on the distal end of the arm member, the impact head being electrically coupled to the arm member, wherein the arm member is adapted to deflect from the first position to the second position, the impact head is adapted to touch the first contact, and the arm member is adapted to return from the second position to the first position when the first predetermined acceleration force acts on the housing. 7. The external infusion device of claim 1, wherein the impact switch further comprises: a second electrically conductive contact fixedly mounted adjacent to the seismic mass, the second contact being electrically coupled to the electrical input, wherein the mass is further adapted for resilient deflection in a second closing contact direction, and wherein the mass is adapted to deflect in the second closing contact direction from the first position to a third position, touch the second contact, and return from the third position to the first position such that a circuit between the electrical input and the electrical output is closed to provide the acceleration output signal when a second predetermined acceleration force acts on the housing. 8. The external infusion device of claim 1, wherein the processor is further adapted to determine whether the person is engaging in a physical activity based on the acceleration output signal. 9. The external infusion device of claim 8, further comprising a memory contained in the housing and coupled to the processor, wherein the memory is adapted to store a predetermined acceleration force corresponding to a physical activity of the person, and the processor determines that the person is engaging in the physical activity if the acceleration output signal exceeds the predetermined acceleration force. 10. The external infusion device of claim 8, further comprising a memory contained in the housing and coupled to the processor, wherein the memory is adapted to store a pattern of acceleration forces corresponding to a physical activity of the person, and the processor determines that the person is engaging in the physical activity if the acceleration output signal corresponds to the pattern of acceleration forces. 11. The external infusion device of claim 8, wherein if the processor determines that the person is engaging in a physical activity, the processor is adapted to control the infusion device by causing the indicator to notify the person about the physical activity. 12. The external infusion device of claim 8, further comprising a transmitter/receiver contained in the housing and coupled to the processor, wherein the transmitter/receiver is adapted to communicate with a remote device, and further wherein if the processor determines that the person is engaging in a physical activity, the processor is adapted to control the infusion device by causing the transmitter/receiver to send information about the physical activity of the person to the remote device. 13. The external infusion device of claim 12, wherein the information includes data about at least one of frequency, duration, and intensity of the physical activity of the person. 14. The external infusion device of claim 8, further comprising a memory contained in the housing and coupled to the processor, wherein the memory is further adapted to store data about at least one of frequency, duration, and intensity of the physical activity of the person. 15. The external infusion device of claim 8, wherein if the processor determines that the person is engaging in a physical activity, the processor is adapted to control the infusion device by causing the drive mechanism to alter delivery of the fluid into the person from a current delivery rate to a modified delivery rate. 16. The external infusion device of claim 15, wherein the processor is adapted to control the infusion device by causing the drive mechanism to automatically alter delivery of the fluid into the person from the current delivery rate to the modified delivery rate. 17. The external infusion device of claim 16, further comprising an input device coupled to the processor and adapted to receive input from the person about the modified delivery rate, wherein the processor is adapted to control the infusion device by causing the drive mechanism to automatically alter delivery of the fluid into the person from the current delivery rate to the modified delivery rate based on the input from the person. 18. The external infusion device of claim 15, further comprising an input device coupled to the processor and adapted to receive input from the person associated with the modified delivery rate, wherein the processor is adapted to control the infusion device by causing the drive mechanism to alter delivery of the fluid into the person from the current delivery rate to the modified delivery rate in response to the input by the person. 19. The external infusion device of claim 15, wherein the processor is adapted to control the infusion device by applying a time delay between determining that the person is engaging in the physical activity and causing the drive mechanism to alter delivery of the fluid into the person from the current delivery rate to the modified delivery rate. 20. The external infusion device of claim 8, wherein the processor is further adapted to determine whether the person has stopped engaging in the physical activity based on the acceleration output signal. 21. The external infusion device of claim 20, further comprising a memory contained in the housing and coupled to the processor, wherein the memory is adapted to store a predetermined acceleration force corresponding to a physical activity of the person, and the processor determines that the person has stopped engaging in the physical activity if the acceleration output signal drops below the predetermined acceleration force. 22. The external infusion device of claim 20, further comprising a memory contained in the housing and coupled to the processor, wherein the memory is adapted to store a pattern of acceleration forces corresponding to a physical activity of the person, and the processor determines that the person has stopped engaging in the physical activity if the acceleration output signal no longer corresponds to the pattern of acceleration forces. 23. The external infusion device of claim 20, wherein if the processor determines that the person has stopped engaging in the physical activity, the processor is adapted to control the infusion device by causing the indicator to notify the person about stopping the physical activity. 24. The external infusion device of claim 20, wherein if the processor determines that the person has stopped engaging in the physical activity, the processor is adapted to control the infusion device by causing the drive mechanism to return delivery of the fluid into the person from the modified delivery rate to the current delivery rate. 25. The external infusion device of claim 24, wherein the processor is adapted to control the infusion device by causing the drive mechanism to automatically return deliver of the fluid into the person from the modified delivery rate to the current delivery rate. 26. The external infusion device of claim 24, further comprising an input device coupled to the processor and adapted to receive input from the person, wherein the processor is adapted to control the infusion device by causing the drive mechanism to return delivery of the fluid into the person from the modified delivery rate to the current delivery rate in response to the input by the person. 27. The external infusion device of claim 24, wherein the processor is adapted to control the infusion device by applying a time delay between determining that the person has stopped engaging in the physical activity and causing the drive mechanism to return delivery of the fluid into the person from the modified delivery rate to the current delivery rate. 28. The external infusion device of claim 8, wherein if the processor determines that the person is engaging in a physical activity, the processor is adapted to control the infusion device by causing the drive mechanism to deliver the fluid into the person at a modified delivery rate after the physical activity while the person is sleeping. 29. An external ambulatory medical device for use on a person's body, comprising: a housing adapted to be carried on an exterior of the person's body; a processor contained in the housing; an indicator operatively coupled to the processor and adapted to provide at least one of a visual indication, an audible indication, or a tactile indication to indicate information about the ambulatory medical device to the person; and an acceleration sensor coupled to the processor and adapted to provide an acceleration output signal as a function of acceleration forces acting on the housing, wherein the acceleration sensor is an impact switch disposed within the housing, the impact switch comprising: an electrical input and an electrical output, an electrically conductive seismic mass having an anchored end and a free end, the mass being electrically coupled to the electrical output, the mass being coupled to the housing at the anchored end and adapted for resilient deflection in a first closing contact direction, and a first electrically conductive contact fixedly mounted adjacent to the mass, the first contact being electrically coupled to the electrical input, wherein the mass is adapted to deflect in the first closing contact direction from a first position to a second position, touch the first contact, and return from the second position to the first position such that a circuit between the electrical input and the electrical output is closed to provide the acceleration output signal when a first predetermined acceleration force acts on the housing; wherein the processor is adapted to control the ambulatory medical device and the indicator is adapted to indicate information about the ambulatory medical device based on the acceleration output signal. 30. The ambulatory medical device of claim 29, wherein the ambulatory medical device is an external infusion pump. 31. The ambulatory medical device of claim 29, wherein the ambulatory medical device is a glucose monitoring device. 32. The ambulatory medical device of claim 29, further comprising a transmitter/receiver contained in the housing and coupled to the processor, wherein the transmitter/receiver is adapted to communicate with a remote device, and further wherein the processor is adapted to control the ambulatory medical device by causing the transmitter/receiver to send information about the ambulatory medical device to the remote device based on the acceleration output signal. 33. The external infusion device of claim 29, wherein the conductive seismic mass comprises: an electrically conductive arm member having a proximate end and a distal end, the arm member being coupled to the housing at the proximate end and adapted for resilient deflection in the first closing contact direction; and an electrically conductive impact head mounted on the distal end of the arm member, the impact head being electrically coupled to the arm member, wherein the arm member is adapted to deflect from the first position to the second position, the impact head is adapted to touch the first contact, and the arm member is adapted to return from the second position to the first position when the first predetermined acceleration force acts on the housing. 34. The external infusion device of claim 29, wherein the impact switch further comprises: a second electrically conductive contact fixedly mounted adjacent to the seismic mass, the second contact being electrically coupled to the electrical input, wherein the mass is further adapted for resilient deflection in a second closing contact direction, and wherein the mass is adapted to deflect in the second closing contact direction from the first position to a third position, touch the second contact, and return from the third position to the first position such that a circuit between the electrical input and the electrical output is closed to provide the acceleration output signal when a second predetermined acceleration force acts on the housing.