U.S. patent application number 13/085370 was filed with the patent office on 2011-11-17 for system and method for continuous non-invasive glucose monitoring.
This patent application is currently assigned to ECHO THERAPEUTICS, INC.. Invention is credited to Shikha Barman, Han Chuang, Scott C. KELLOGG, Nick Warner.
Application Number | 20110282327 13/085370 |
Document ID | / |
Family ID | 38119712 |
Filed Date | 2011-11-17 |
United States Patent
Application |
20110282327 |
Kind Code |
A1 |
KELLOGG; Scott C. ; et
al. |
November 17, 2011 |
SYSTEM AND METHOD FOR CONTINUOUS NON-INVASIVE GLUCOSE
MONITORING
Abstract
A system and method for continuous non-invasive glucose
monitoring is disclosed. According to one embodiment of the present
invention, the method includes the steps of (1) contacting a remote
device to an area of biological membrane having a permeability
level, the remote device comprising a sensor and a transmitter; (2)
extracting the at least one analyte through and out of the area of
biological membrane and into the sensor; (3) generating an
electrical signal representative of a level of the at least one
analyte; (4) transmitting the electrical signal to a base device;
(5) processing the electrical signal to determine the level of the
at least one analyte; and (6) displaying the level of the at least
one analyte in real time. The system includes a remote device that
includes a sensor that generates an electrical signal
representative of the concentration of the at least one analyte;
and a transmitter that transmits the electrical signal. The system
further includes a base device that includes a receiver that
receives the electrical signal; a processor that processes the
electrical signal; and a display that displays the processed signal
in real time.
Inventors: |
KELLOGG; Scott C.; (Boston,
MA) ; Chuang; Han; (Canton, MA) ; Barman;
Shikha; (Bedford, MA) ; Warner; Nick;
(US) |
Assignee: |
ECHO THERAPEUTICS, INC.
Franklin
MA
|
Family ID: |
38119712 |
Appl. No.: |
13/085370 |
Filed: |
April 12, 2011 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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11275038 |
Dec 5, 2005 |
7963917 |
|
|
13085370 |
|
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Current U.S.
Class: |
604/890.1 ;
600/347 |
Current CPC
Class: |
A61B 5/0002 20130101;
A61B 5/1486 20130101 |
Class at
Publication: |
604/890.1 ;
600/347 |
International
Class: |
A61M 5/00 20060101
A61M005/00; A61B 5/1468 20060101 A61B005/1468 |
Claims
1. A method for real time remote monitoring and display of a level
of at least one analyte in a body fluid of a subject, comprising:
contacting a remote device to an area of biological membrane having
a permeability level, the remote device comprising a sensor and a
transmitter; extracting the at least one analyte through and out of
the area of biological membrane and into the sensor; generating an
electrical signal representative of a level of the at least one
analyte; transmitting the electrical signal to a base device;
processing the electrical signal to determine the level of the at
least one analyte; and displaying the level of the at least one
analyte in real time.
2. The method of claim 1, wherein the at least one analyte is
glucose.
3. The method of claim 1, further comprising the step of:
increasing the permeability level of the area of biological
membrane.
4. The method of claim 1, wherein the step of contacting a remote
device to an area of biological membrane having a permeability
level comprises: affixing the remote device to the area of
biological membrane with an adhesive.
5. The method of claim 1, wherein the step of transmitting the
signal to a base device comprises: converting the electrical signal
representative of the level of the at least one analyte to a
digital signal; and transmitting the digitized signal, an
identification number of the remote device, and a time stamp to the
base device.
6. The method of claim 1, wherein the step of transmitting the
signal to a monitoring device is performed periodically.
7. The method of claim 1, wherein step of the transmitting the
electrical signal to a base device comprises: transmitting the
signal to the base device by at least one of a wireless application
protocol link, a general packet radio service link, a Bluetooth
radio link, an IEEE 802.11-based radio frequency link, a RS-232
serial connection, an IEEE-1394 (Firewire) connection, a fibre
channel connection, an infrared (IrDA) port, a small Computer
Systems Interface (SCSI) connection, and a Universal Serial Bus
(USB) connection.
8. The method of claim 1, further comprising the step of:
periodically determining an amount of a drug to be injected in
response to the analyte level; and automatically providing the
determined amount of the drug to the subject.
9. The method of claim 8, wherein the drug is insulin.
10. The method of claim 1, wherein the analyte level is displayed
graphically.
11. The method of claim 10, wherein the analyte level is displayed
in relative to time.
12. A system for real time remote monitoring of a level of at least
one analyte in a body fluid, comprising: a remote device,
comprising: a sensor that generates an electrical signal
representative of the concentration of the at least one analyte;
and a transmitter that transmits the electrical signal; a base
device, comprising: a receiver that receives the electrical signal;
a processor that processes the electrical signal; and a display
that displays the processed signal in real time.
13. The system of claim 12, wherein the at least one analyte is
glucose.
14. The system of claim 12, wherein the remote device is affixed to
the area of biological membrane with an adhesive.
15. The system of claim 12, wherein the transmitter transmits the
electrical signal to a base device by at least one of a wireless
application protocol link, a general packet radio service link, a
Bluetooth radio link, an IEEE 802.11-based radio frequency link, a
RS-232 serial connection, an IEEE-1394 (Firewire) connection, a
fibre channel connection, an infrared (IrDA) port, a small Computer
Systems Interface (SCSI) connection, and a Universal Serial Bus
(USB) connection.
16. The system of claim 12, further comprising: means for providing
the subject with a drug.
17. The system of claim 16, wherein the processor determines an
amount of the drug to provide the subject responsive to the analyte
level.
18. The system of claim 17, wherein the drug is insulin.
19. The system of claim 12, wherein the display displays the
analyte level graphically.
20. The system of claim 19, wherein the analyte level is displayed
in relative to time.
21-25. (canceled)
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] The present invention generally relates to transdermal
transport using ultrasound or other skin permeation methods, and,
more particularly, to a system and method for continuous
non-invasive glucose monitoring.
[0003] 2. Description of Related Art
[0004] The benefits of an intensive glucose management protocol on
the mortality of critically ill adult patients is starting to be
understood. Dr. James Stephen Krinsley has reported that, in a
study recently conducted at the Intensive Care Unit at Stamford
Hospital, a protocol that attempts to keep blood glucose levels
lower than 140 mg/dL was associated with a significant decrease in
mortality among critically ill patients. See Krinsley, James
Stephen "Effect of Intensive Glucose Management Protocol on the
Mortality of Critically Ill Adult Patients," Mayo Clin Proc. August
2004; 79(8): 992-1000 (the contents of which are incorporated by
reference in their entirety).
[0005] Before Dr. Krinsley's protocol was introduced, the standard
of care at the ICU, which was typical for most ICUs, was to
tolerate moderate levels of hyperglycemia. Thus, insulin was
typically not administered unless the blood glucose levels exceeded
200 mg/dL on two successive finger sticks. If the blood glucose
level was not above 200 mg/dL, no treatment was provided.
[0006] With Krinsley's protocol in place, the glucose levels of
patients in the ICU was initially to be measured at least every
three hours. To accomplish this, nurses were required to perform a
finger stick initially every three hours to obtain a glucose value.
If the glucose value exceeded 200 mg/dL on two successive finger
sticks, intravenous insulin was administered to the patient. For
lower glucose levels, subcutaneous regular insulin was
administered. If the glucose value was below 140 mg/dL, no
treatment was administered.
[0007] Dr. Krinsley's protocol imposed a significant amount of
extra work on the nursing staff at the hospital. It required a
willingness and commitment on behalf of the nursing staff to take
repeated glucose measurements, and by a finger stick.
SUMMARY OF THE INVENTION
[0008] According to one embodiment of the present invention, a
method for real time remote monitoring and display of a level of at
least one analyte in a body fluid of a subject is disclosed. The
method includes the steps of (1) contacting a remote device to an
area of biological membrane having a permeability level, the remote
device comprising a sensor and a transmitter; (2) extracting the at
least one analyte through and out of the area of biological
membrane and into the sensor; (3) generating an electrical signal
representative of a level of the at least one analyte; (4)
transmitting the electrical signal to a base device; (5) processing
the electrical signal to determine the level of the at least one
analyte; and (6) displaying the level of the at least one analyte
in real time.
[0009] According to another embodiment of the present invention, a
system for real time remote monitoring of a level of at least one
analyte in a body fluid is disclosed. The system includes a remote
device that includes a sensor that generates an electrical signal
representative of the concentration of the at least one analyte;
and a transmitter that transmits the electrical signal. The system
further includes a base device that includes a receiver that
receives the electrical signal; a processor that processes the
electrical signal; and a display that displays the processed signal
in real time.
[0010] According to another embodiment of the present invention, a
transdermal sensor is disclosed. The transdermal sensor includes a
substrate having a first and a second surface. A first electrode
trace is formed on the first surface of the substrate. A second
electrode trace is formed on the second surface of the substrate. A
third electrode trace is formed on the second surface of the
substrate. A fourth electrode trace is formed on the second surface
of the substrate. A fifth electrode trace is formed on the second
surface of the substrate. A dielectric is formed on the second
surface of the substrate. A plurality of electrical contacts are
provided.
[0011] It is a technical advantage of the present invention that a
system for continuous non-invasive glucose monitoring is disclosed.
It is another technical advantage of the present invention that a
method for continuous non-invasive glucose monitoring is disclosed.
It is another technical advantage of the present invention that a
transdermal sensor is disclosed. It is still another technical
advantage of the present invention that a remote device and a base
device are disclosed. It is another technical advantage of the
present invention that the remote device and the base device may
communicate by a wireless protocol, such as a wireless application
protocol link, a general packet radio service link, a Bluetooth
radio link, an IEEE 802.11-based radio frequency link, a RS-232
serial connection, an IEEE-1394 (Firewire) connection, a fibre
channel connection, an infrared (IrDA) port, a small Computer
Systems Interface (SCSI) connection, and a Universal Serial Bus
(USB) connection.
BRIEF DESCRIPTION OF THE DRAWINGS
[0012] For a more complete understanding of the present invention,
the objects and advantages thereof, reference is now made to the
following descriptions taken in connection with the accompanying
drawings in which:
[0013] FIG. 1 illustrates a block diagram of a system for
continuous, noninvasive monitoring of a subject's glucose levels
according to one embodiment of the invention;
[0014] FIG. 2 illustrates exemplary modules that may be associated
with system of FIG. 1;
[0015] FIG. 3a is a top perspective view of and FIG. 3b is a bottom
perspective view of a remote device according to one embodiment of
the present invention;
[0016] FIG. 4 is an illustration of a sensor according to one
embodiment of the present invention;
[0017] FIG. 5 is an illustration of a transdermal sensor according
to one embodiment of the present invention;
[0018] FIG. 6 is a detailed schematic for a remote device according
to one embodiment of the present invention;
[0019] FIG. 7 is an illustration of a state machine executed by
controller according to one embodiment of the present
invention;
[0020] FIG. 8 is a data format in accordance with one embodiment of
the present invention is provided;
[0021] FIG. 9 is a schematic for a base device according to one
embodiment of the invention;
[0022] FIG. 10 is an example of a display according to one
embodiment of the present invention;
[0023] FIG. 11 is an illustration of a method for continuous,
noninvasive monitoring of a subject's glucose level according to
one embodiment of the present invention; and
[0024] FIG. 12 illustrates a method for identifying errors in the
transmission of data according to one embodiment of the present
invention.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
[0025] Preferred embodiments of the present invention and their
advantages may be understood by referring to FIGS. 1-12, wherein
like reference numerals refer to like elements, and are described
in the context of a portable skin permeation system for pretreating
an area of skin with ultrasound and then transdermally extracting a
continuous flux of glucose to be measured by a sensor.
[0026] It is known that ultrasound can be used to increase the
permeability of the skin, thereby allowing the extraction of
analytes, such as glucose, through the skin. For example, U.S. Pat.
No. 6,234,990 to Rowe et al., the disclosure of which is hereby
incorporated by reference, discloses methods and devices using a
chamber and ultrasound probe to non-invasively extract analyte and
deliver drugs (i.e., broadly transdermally transport substances).
This provides many advantages, including the ability to create a
small puncture or localized erosion of the skin tissue, without a
large degree of concomitant pain. The number of pain receptors
within the ultrasound application site decreases as the application
area decreases. Thus, the application of ultrasound to a very small
area will produce less sensation and allow ultrasound and/or its
local effects to be administered at higher intensities with little
pain or discomfort.
[0027] By applying a brief duration of ultrasound, the outer most
layer of skin (i.e., stratum corneum) becomes permeable. In an
exemplary embodiment of the invention, the area of the pretreated
skin site is approximately 0.8 cm.sup.2. In-vivo studies
demonstrate that skin conductivity is significantly enhanced by
ultrasound pretreatment and that the enhancement lasts for
approximately twenty-four (24) hours. In order to control the
ultrasound pretreatment, particularly the duration thereof, the
change in skin conductance (or impedance) is measured during the
application of ultrasound. When a desired level of skin
conductivity is achieved, and hence a desired level of skin
permeability, application of ultrasound is terminated. After
permeation, passive diffusion or iontophoresis enhances the
transport of a drug, such as an anesthetic agent, across the
treated skin site. In the case of iontophoresis, a low-level
current to a drug delivery electrode and a grounding electrode are
employed. The potential difference between the two electrodes
allows the drug ions to migrate efficiently from the drug delivery
electrode into the skin. The delivery dose is proportional to the
level of applied current and the treatment time. Similarly,
analytes can be passively or iontophoretically transported across
the skin for measurement.
[0028] Moreover, U.S. Pat. No. 6,190,315 to Kost et al., the
disclosure of which is incorporate by reference, discloses that
application of ultrasound is only required once for multiple
deliveries or extractions over an extended period of time rather
than prior to each extraction or delivery. That is, it has been
shown that if ultrasound having a particular frequency and a
particular intensity of is applied, multiple analyte extractions or
drug deliveries may be performed over an extended period of time.
For example, if ultrasound having a frequency of 20 kHz. and an
intensity of 10 W/cm.sup.2 is applied, the skin retains an
increased permeability for a period of up to four hours.
[0029] Nevertheless, the amount (e.g., duration, intensity, duty
cycle) of ultrasound necessary to achieve this permeability
enhancement varies widely. Several factors on the nature of skin
must be considered. For example, the type of skin which the
substance is to pass through varies from species to species, varies
according to age, with the skin of an infant having a greater
permeability than that of an older adult, varies according to local
composition, thickness and density, varies as a function of injury
or exposure to agents such as organic solvents or surfactants, and
varies as a function of some diseases such as psoriasis or
abrasion.
[0030] Once the permeability of the skin is increased, by
ultrasound or by another means, the system of the present invention
may be implemented. FIG. 1 illustrates a block diagram of a system
for continuous, noninvasive monitoring of a subject's glucose
levels according to one embodiment of the invention. System 100
generally includes remote device 110 and base device 150. Remote
device 110, which preferably includes sensor 120, is provided to a
subject and produces a signal (e.g., an amperometric current
signal) related to an analyte concentration, such as glucose, in
the subject. Remote device 110 may consist of a reusable assembly
that produces a signal that represents the magnitude of the current
produced by transdermal sensor. Remote device may also produce
signals that represent the subject's skin temperature and the
charge level of batteries. Remote device 110 also preferably
includes transmission unit 130 that transmits the signal to base
device 150. Remote device may also include a unique identifier,
such as an identification number.
[0031] Base device 150 preferably includes processor 160 that
processes the signal to determine the analyte concentration in the
subject. Base device 150 preferably also includes display 170 that
displays the results for a user.
[0032] FIG. 2 illustrates exemplary modules that may be associated
with system 100 for carrying out the various functions and features
of the embodiments described herein. In some embodiments, the
modules may be included that perform the following functions: (1)
quantify the current produced by remote device 110; (2) measure the
subject's skin temperature; (3) measure the voltage level of a
battery that may be used to power system 100; (4) transmit data
among system 100 modules; (5) receive data representing measured
values and store them in memory units; (6) receive at least a
calibration standard for the subject's glucose level via an input
device; (7) predict the subject's glucose level, the glucose
level's rate of change, and the percent change in the user's skin
temperature; (8) transmit data to base device 130; (9) operate the
device's alarm functions; and (10) operate the device's error
functions. A brief description of each module is provided below.
Although the modules are discussed individually by function, it
should be understood that a single module may perform more than one
function, or, alternatively, that more than one module may be
required to perform one function.
[0033] Sensor module 205 may monitor the amperometric current
produced at remote device 110 and produce a time-stamped
measurement of its magnitude. In some embodiments of the system
100, sensor module 205 may use a potentiostat to measure this
current. This value is related to the subject's glucose level.
[0034] Temperature module 210 may produce a time-stamped
measurement of the subject's skin temperature. In some embodiments
of the system 100, temperature module 210 may use a thermally
sensitive resistors (i.e., a thermistor) to measure the
temperature. Other mechanisms for measuring the subject's skin
temperature may also be used.
[0035] Battery module 215 may measure the voltage level of battery
or other power source that may be used to power at least some of
the modules in system 100. In some embodiments of system 100,
battery module 215 may use a voltmeter to measure this value.
[0036] Relay module 220 may transmit data among at least some of
the modules of system 100 using any wired or wireless, digital or
analog interface or connection. In some embodiments of system 100,
relay module 220 may use a radio frequency transmitter to transmit
data among modules.
[0037] Memory module 225 may receive data sent from relay module
220 and store it in memory units. Any suitable type of memory may
be used. In one embodiment, a non-volatile memory that can store
seven days of data may be used. Other types and sizes of memory may
be used as appropriate.
[0038] Input module 230 may allow a user to enter data for the
system, such as glucose level calibration data. This may be based
on a measurement taken from a blood sample. In some embodiments of
system 100, input module 230 may use a keypad to allow a user to
input calibration data.
[0039] Prediction module 235 may combine calibration data with the
signals representing the current in remote device 110 to predict
the subject's current glucose level, the glucose level's rate of
change, and the percent change of the subject's skin temperature.
In some embodiments of system 100, prediction module 235 may
include a microcontroller to predict a subject's glucose
levels.
[0040] Transmit module 240 may transmit a signal to base device 150
using any wired or wireless, digital or analog interface or
connection. In some embodiments of the system, this signal may
contain data representing, for example, the current in remote
device 110, the subject's predicted glucose value, the predicted
rate of change of the subject's glucose value, the measured current
voltage of batteries, the percent change of the subject's skin
temperature, etc.
[0041] Transmit module 240 may also transmit a signal to a
hospital's central patient database.
[0042] Alarm module 245 may allow the user to set parameters for
the devices' alarm function. These alarms may be set to become
active when certain conditions are met, such as when the subject's
glucose level reach certain values, when a predicted rate of change
reaches a certain value, or when battery voltages reach a certain
level. The alarms will be discussed in greater detail, below.
[0043] Error module 250 may verify that any data transmitted
between system 150 modules is transmitted accurately and
securely.
[0044] In some embodiments of the invention, modules associated
with system 100 may be located independently, with remote device
110, with base device 150, or located with both. For example, in
system 100, sensor module 205, temperature module 210, battery
module 215, relay module 220, and transmit module 240 may be
colocated with remote device 110. In this embodiment, the remaining
modules of system 100 may be located with base device 150.
[0045] Referring to FIGS. 3a and 3b, an exemplary embodiment remote
device 110 is provided. FIG. 3a is a top perspective view of remote
device 110 and FIG. 3b is a bottom perspective view of remote
device 110. Upper portion 310 of remote device 110 includes
operational indicator 315, such as a LED, temperature module 320,
such as a thermistor, battery 325, and contacts 330 for making
contact with contacts 355 on sensor 350. Upper portion 310 may also
include relay module (not shown) and transmit module (not
shown).
[0046] Lower portion 360 of remote device 110 includes target ring
365 and adhesive 370.
[0047] The upper portion 310 and lower portion 360 of remote device
110 preferably interface so they are easily detachable after use,
but are not easily detachable during use. In one embodiment, lower
portion 360 is disposable, while upper portion 310 is
reuseable.
[0048] Although remote device 110 and certain portions thereof are
illustrated as being circular, other geometries may be used as
necessary.
[0049] Referring to FIG. 4, an illustration of sensor 350 according
to one embodiment of the present invention is provided. Sensor 350
includes adhesives 405 and 410. Adhesives 405 and 410 may be
commercially-available medical adhesives. In one embodiment,
adhesive 405 may be an adhesive ring MED 3044 with a 9/16 inch
inner diameter, and a 13/8 inch outer diameter, and adhesive 410
may be an adhesive disc MED 3044 with a 13/8 inch diameter. Both
are available from Avery Dennison, 150 North Orange Grove
Boulevard, Pasadena, Calif. 91103-3596, USA.
[0050] Sensor 350 also includes working electrode 415, counter
electrode 420, and reference electrode 425. In one embodiment,
working electrode 415 is formed by sputter coating pure platinum
(Pt) material, and both counter electrode 420 and reference
electrode 425 are formed by screen printing carbon and Ag/AgCl
materials.
[0051] Referring to FIG. 5, an illustration of sensor 350 according
to one embodiment of the present invention is provided. Electrode
500 may of sensor 350 has an outer diameter of 9/16''. Electrode
500 is mounted on substrate 550, which is preferably heat
annihilated PET. Electrode 500 includes, on a front surface of
substrate 550, silver 505 on a front of substrate 550,
silver/silver chloride 510, platinum 515, carbon 520, and clear
dielectric 525. On a back surface of substrate 550, silver (not
shown) is provided. Connection points to electronics are located on
the back of the sensor using a mill-and-fill and printing process
by CTI.
[0052] Sensor 350 may be provided with a hyrdogel (not shown). In
one embodiment, hydrogel may be polyethylene glycol diacrylate
(PEG-DA) hydrogel with entrapped glucose oxidase (GOx). Such a
hydrogel is disclosed in U.S. patent application Ser. No. ______,
entitled "Biocompatible Chemically Crosslinked Hydrogels For
Glucose Sensing," Attorney Docket No. 62803.000066, filed Dec. 2,
2005, the disclosure of which is incorporated reference in its
entirety. The hydrogel may be sized to be inserted in the inner
diameter of adhesive 405.
[0053] Once sensor 355 is connected and adhered to the subject's
skin, it may begin to produce a signal representing an amperometric
current proportionate to the subject's glucose level.
[0054] Referring to FIG. 6, a detailed schematic for remote device
110 according to one embodiment of the present invention is
provided. Remote device 110 includes switch 610. Switch 610 may be
a contact switch that is triggered when remote device 110 is
secured to a subject. For example, transmitter 615 may be
electrically disconnected until remote device 110 is secured to a
subject.
[0055] Remote device 110 also includes battery 620. In one
embodiment, battery 620 is a single 3V Lithium "coin-cell." It is
anticipated that this type of battery will power remote device 110
for a minimum of 1 week. In one embodiment, the voltage of battery
620 is transmitted to and monitored by base device 150. This
voltage may be transmitted at a predetermined time interval,
discussed below.
[0056] Potentiostat 625 is provided to quantify the amperometric
current produced by sensor 350. In one embodiment, potentiostat 625
sets remote device 110 at a predetermined voltage, such as 500 mV.
Once set, sensor 350 will initially start with a high current, such
as 50 .mu.A and then ramps down to 200 nA. While at a high current,
it is important that potentiostat 625 does not saturate (i.e. the
working electrode moves above ground). For this reason, currents
above 1 .mu.A will be detected with a low value resistor (kOhms)
and currents below 1 .mu.A will be accurately measured with a high
value resistor (MOhms).
[0057] In one embodiment, potentiostat 625 is bi-polar, splitting
the supply voltage in half. For example, potentiostat 625 may split
supply voltage 3 V DC into +/-1.5 V DC. Because, in one embodiment,
the data from potentiostat 625 is downloaded to base device 150
periodically, adequate filtering and roll-off may be provided to
average the data over the predetermined time interval.
[0058] In addition, signal filtering (not shown) may be provided to
reduce spurious noise events, such as current spikes on the order
of 5 nA to 10 nA, or greater per minute.
[0059] Thermistor 630 is provided to monitor the temperature near
the surface of the subject's skin. In one embodiment, this data may
be transmitted to base device 150 at a predetermined interval,
discussed below.
[0060] Analog to digital (A/D) converters 635 are provided to
digitize the outputs of potentiostat 625, thermistor 630, and the
voltage of battery 620. In one embodiment, this data is collected
and stored in memory for transmission to base device 150. Although
three A/D converters 635 are illustrated in FIG. 5, additional A/D
converters may be used, or a single A/D converter with a
multiplexed input may also be used.
[0061] Controller 640, which may be a miniature low power
controller or state machine is provided to coordinate all hardware
interaction. Controller 640 will be discussed in greater detail,
below.
[0062] Memory 645 is provided to store a unique identifier that is
common between the transmitter 615 and base device 150. In one
embodiment, base device 150 may be programmed such that it will
only recognize data from a transmitter with a certain unique
identifier. Memory 645 may be programmed via programming port
650.
[0063] Programming port 650 is provided to allow firmware and/or a
unique identifier to be programmed. Any suitable interface may be
used.
[0064] Transmitter 615 may be provided to transmit data to base
device 150. Transmitter 615 may communicate via any wired or
wireless, digital or analog interface or connection including a
Wireless Application Protocol (WAP) link, a General Packet Radio
Service (GPRS) link, a Bluetooth radio link, an IEEE 802.11-based
radio frequency link, a RS-232 serial connection, an IEEE-1394
(Firewire) connection, a Fibre Channel connection, an infrared
(IrDA) port, a Small Computer Systems Interface (SCSI) connection,
or a Universal Serial Bus (USB) communication. Other non-protocol
based communication methods may also be employed. Transmitter 615
may transmit data to base device 150 at a predetermined interval,
such as once every minute. Other intervals may be used as
required.
[0065] In one embodiment, the same data may be transmitted multiple
times during the predetermined interval. For example, if the
predetermined time interval is one minute, the same data may be
transmitted three times during the predetermined interval. These
transmissions may occur at random intervals during the
predetermined interval. This provides redundancy to the
transmission.
[0066] The operation frequency and power are set so that
transmitter 615 can communicate with base device 150. Preferably,
the operation frequency and power are in compliance with FCC and
FDA requirements.
[0067] In one embodiment, prior to transmitting, transmitter 615
checks to ensure that no other transmitter within range are
transmitting. This reduces the likelihood of data corruption.
[0068] Resistor Rshunt 655 and switch 660 are provided to set the
range of the sensor. When switch 660 is closed, the resistance seen
is 1 K ohm. This sets the range of the sensor at greater than 1
.mu.A. If switch 660 is opened, the resistance seen is 1 M ohm.
This sets the range of the sensor at less than 1 .mu.A.
[0069] FIG. 7 is an illustration of a state machine executed by
controller 640. At state 705, if the power is on, the state machine
proceeds to state 710.
[0070] In state 710, the timer is reset (i.e., the timer is set to
zero) and then started. In state 720, shunt resistor Rshunt is
closed. Resistor Rshunt switches in or out a 1 k ohm resistor that
is in parallel with the 1 M ohm sense resistor. When resistor
Rshunt is open, the measurement resistance is 1 M ohm. Thus, a
current of 1 .mu.A is measured as a drop of 1 volt across the
resistor. Essentially this provides a very sensitive gain of 1V/1
.mu.A.
[0071] When resistor Rshunt is closed, the measurement resistance
is 1K ohm in parallel with 1 M ohms, or 999 Ohms (approximately 1K
ohm). The 1 .mu.A now represents a 1 mV drop across the resistor.
This reduces the sensitivity to 1 mV/.mu.A.
[0072] During sensor conditioning the sensor operates at higher
currents therefore the 1 mV/.mu.A gain is used. Once the sensor
stabilizes at a lower current, the resistor Rshunt is opened and a
gain of 1V/.mu.A is used.
[0073] In state 725, the system waits for a predetermined passage
of time, such as a minute. Once that predetermined time is met, in
states 730, 740, and 745 measurements are made or captured. For
example, in step 730, the current at potentiostat 725 is measured.
If the current is less than 1 .mu.Amp, in step 735, shunt resistor
Rshunt is opened.
[0074] In state 740, the voltage at battery 620 is measured, and at
state 745 the subject's temperature is measured.
[0075] In state 750, the collected data is formatted for
transmission. Any suitable data format may be used. Referring to
FIG. 8, a data format in accordance with one embodiment of the
present invention is provided. Data format 800 includes current
field 810, battery voltage field 820, subject temperature field
830, device identification number field 840, minute field 850, and
checksum 860. Rshunt field (not shown) may be provided to indicate
whether Rgain is shunted or not shunted. Additional or fewer fields
may be included as necessary and/or desired.
[0076] In one embodiment, current field 810 may have a width of 16
bits, battery voltage field 820 may have a width of 7 bits, subject
temperature field 830 may have a width of 8 bits, device
identification number field 840 may have a width of 16 bits, minute
field 850 may have a width of 16 bits, and checksum 860 may have a
width of 16 bits.
[0077] Referring again to FIG. 7, in state 755, the state machine
waits to transmit the formatted data. In one embodiment, the state
machine waits to ensure that no other devices are transmitting at
the same time.
[0078] In state 760, the formatted data is transmitted to base
device 150. Following transmission, the state machine loops back to
state 725.
[0079] Referring again to FIG. 1, base device 150 receives the
signal transmitted from remote device 110. Base device 150
processes the received signal, resulting in a signal that is
indicative of the predicted analyte concentration in the
subject.
[0080] Referring to FIG. 9, schematics for base device 150
according to one embodiment of the invention are provided. Base
device 150 includes receiver 910 that receives the signal
transmitted by remote device 110. In one embodiment, as base device
150 receives data from remote device 110, the data is error checked
and written to non-volatile memory 935. This will be described in
greater detail, below.
[0081] In one embodiment, base device 150 monitors the operation of
remote device 110. In one embodiment, when base device 150 detects
that remote device 110 has been transmitting for a predetermined
time, indicating that remote device is attached to a subject, base
device 150 prompts the operator to enter calibration data from the
blood draw. The calibration data may be a time-stamped measurement
of the subject's glucose level taken from a venous blood sample or
finger stick meter reading. Preferably, this may take place after
one hour of operation. Therefore the blood draw time and date occur
between Sensor On +1 hour and the Current Sensor Time.
[0082] Programming port 915 is provided in the same manner as
programming port 550.
[0083] Interface 920 is provided to allow access to the data stored
and/or received by base device 150. In one embodiment this may be a
RS-232 serial connection. Other communications protocols, such as a
Wireless Application Protocol (WAP) link, a General Packet Radio
Service (GPRS) link, a Bluetooth radio link, an IEEE 802.11-based
radio frequency link, an IEEE-1394 (Firewire) connection, a Fibre
Channel connection, an infrared (IrDA) port, a Small Computer
Systems Interface (SCSI) connection, or a Universal Serial Bus
(USB) connection may also be used.
[0084] Interface 920 may also transmit data to the hospital's
patient database and to a patent terminal, central nurse's station,
etc.
[0085] In one embodiment, seven days worth of data will be stored
in a buffer and downloaded via interface 920.
[0086] Clock 925 is provided. In one embodiment, clock 925 is used
to time-stamp data that is received from remote device 110.
[0087] Base device 150 is provided with processor 930. Processor
930 may be either a 16 or 18-series microcontroller. For example,
the MicroChip PIC-18 family of processors may be used. In one
embodiment, processor 930 preferably includes an internal analog to
digital converter (not shown) and program memory (not shown).
Processor 930 also preferably includes memory 935, such as a
nonvolatile memory. Memory 935 can be located internal to processor
930, or it can be located external to processor 930. In one
embodiment, memory 935 should be of adequate size to hold a minimum
of 24 hours worth of data.
[0088] Processor 930 executes software, firmware, and/or microcode.
This will be discussed in greater detail, below.
[0089] Memory 935 may store a unique identification code in the
same manner as memory 645.
[0090] Base device 150 includes a power supply, such as battery
pack 940. In one embodiment, battery pack 940 supplies base device
150 with power for 1 week without replacement. In one embodiment,
battery pack 940 may be a rechargeable battery pack.
[0091] During operation, battery voltage may be monitored. This may
require an analog to digital converter (not shown). If the voltage
of battery pack 940 falls below a predetermined voltage, the
operator is alerted. This may include a visual indication, or an
audible indication. Preferably, powering-down base device 150, or
replacing battery pack 940 does not result in any data being
lost.
[0092] Alarm 950 and mute switch 955 are provided. In one
embodiment, alarm 950 is a piezoelectric alarm that is used to
alert the operator of certain events, alarm states and error
conditions. These, as well as other types of alarms and
notifications will be discussed in greater detail below.
[0093] In one embodiment, mute switch 955 is provided to mute or
silence alarm 950.
[0094] Base device 150 may include an input device, such as keypad
960. Keypad 960 may include several input switches, such as nine
poly dome-type switches, that are used to input data and control
remote device 110 and/or base device 150. In another embodiment a
touch-screen may be used.
[0095] Base device 150 also includes display 965. In one
embodiment, display 965 is a liquid crystal display. The operating
characteristics of display 965 may be configured (e.g., contrast,
viewing angle, backlight, etc.) as necessary.
[0096] Display 965 may graphically present information to a user in
real time. For example, in one embodiment of the invention. a
subject's glucose level may be graphically displayed for a certain
period of time. Notable events, such as actual blood measurements,
injections of insulin, etc. may be graphically displayed on the
timeline so that the impact of such on the subject's glucose level
may be viewed.
[0097] Other parameters, such as the subject's glucose rate of
change, temperature, and temperature rate of change, may also be
graphically displayed. In addition to display 965, base device 150
may also include LEDs (not shown) as necessary to provide status
information (e.g., power on/off, battery status, etc.) to the
user.
[0098] Referring to FIG. 10, an example of a display according to
one embodiment of the present invention is provided. Display 1000
includes graphical representation 1010 of blood glucose versus
time. In one embodiment, graphical plot 1010 for the past four
hours is displayed; other time periods may be displayed as desired.
In another embodiment, the scales may be selected by a user.
[0099] Marker 1020 may be provided to indicate when insulin was
administered to the subject. In one embodiment, marker 1020 may
comprise a vertical line, such as that shown in FIG. 10. Label 1030
may also be provided to indicate what marker 1020 is marking. In
another embodiment, marker 1020 may be selected by a user such that
it most effectively indicates the time at which the insulin was
administered
[0100] Marker 1020 may also provide additional information, such as
the doseage of the insulin, the person who administered the
insulin, and the time of that the administration occurred. This may
be continuously provided in display 1000, or it may be provided in
a drop-down box (not shown) that is selected by a user.
[0101] FIG. 11 illustrates a method 1100 for continuous,
noninvasive monitoring of a subject's glucose level, preferably in
an intensive care unit, according to one embodiment of the
invention. In some embodiments, method 1100 may be performed by
system 100 of FIG. 1.
[0102] In step 1105, the permeability of an area of a subject's
skin is increased. This may be accomplished by any suitable
mechanism, including the application of ultrasound, mechanical
disruption, laser skin ablation, electroporation, RF ablation,
microneedles, chemical peel, etc. In one embodiment, the
SonoPrep.RTM. Skin Permeation Device, available from Sontra Medical
Corp., Franklin, Mass., may be used to increase the permeability of
the area of skin. Other devices, such as the QuickPrep.TM.
automated patient prep system available from Quinton, Inc., 303
Monte Villa Parkway, Bothell, Wash. 98021-8906, may also be
used.
[0103] In step 1110, the remote device is positioned and affixed to
the area of skin. Preferably, remote device is affixed to the area
of skin by a medical grade adhesive. Remote device should be
securely affixed so that it is not unintentionally removed from the
area of skin, but not preferably does not cause significant skin
damage when removed.
[0104] A medium may be provided between the surface of the skin and
the sensor in order to keep the two in aqueous contact. In one
embodiment, a hydrogel disc may be positioned between the skin and
the sensor. Referring to FIG. 4, the hydrogel disc is preferably
inserted in the interior portion of adhesive ring 405.
[0105] Referring again to FIG. 11, in step 1115, once the remote
device is affixed, the sensor begins to produce a signal, such as
an amperometric current, that is representative of a subject's
glucose level. In step 1120, the magnitude of the signal is
measured, and may associated with the current time (i.e.,
time-stamped). Additionally, other modules, such as the temperature
module and the battery module, may measure the subject's skin
temperature and the voltage level of the a battery, respectively.
These measurements may also be time-stamped.
[0106] In step 1125, the time-stamped measurements may be
transmitted from the remote device to the base device. As discussed
above, this transmission may be made by any suitable wired or
wireless protocol. Prior to transmission, a unique identification
number and checksum value may be added to this data in order to
produce a secure and accurate transmission.
[0107] In step 1130, the base device receives the transmitted data
and stores it in memory. In one embodiment, the base device may
verify the integrity of this transmitted data. This may be
accomplished through the use of a checksum value. In addition, the
identification number may be compared to one that is stored in the
base device's memory.
[0108] At step 1135, the user may input at least a glucose
calibration standard for the subject. This calibration standard may
be a time-stamped measurement of the subject's glucose level taken
from a venous blood sample or finger stick meter reading. The user
may input this calibration standard through the use of a keypad or
other input device attached to the base device.
[0109] At step 1140, the base device may combine the time-stamped
data representing the current produced by the remote device and the
inputted calibration standard to predict the value of the subject's
glucose level. The base device may calculate the predicted glucose
value, current, and percent change in skin temperature by using the
following equations:
Predicted Glucose.sub.t=I.sub.t.times.(Measured
Glucose.sub.t=cal/I.sub.t=cal);
I.sub.t=sensor current-baseline; and
Displayed Temp.sub.t=(Temp.sub.t/Temp.sub.t=cal).times.100
[0110] where baseline is a preprogrammed value in nA.
Predicted Glucose Rate of change=Predicted Glucose.sub.T-Predicted
Glucose.sub.T=1
[0111] Predicted glucose displayed may also be adjusted to
compensate for temperature changes and temporal changes. This is
discussed in greater detail in U.S. patent application Ser. No.
10/974,963, entitled "System and Method for Analyte Sampling and
Analysis," the disclosure of which is incorporated by reference in
its entirety.
[0112] In some embodiments of the method, these calculations may be
performed by the prediction module using a microcontroller.
[0113] At step 1145, the base device displays this data, including
data representing the current in the remote device; the subject's
predicted glucose value; the predicted rate of change of the
subject's glucose value and a future estimated glucose value (T+10
minutes, for example) based on the rate of change; the voltage of
the batteries in either remote device, base device, or both; the
percent change of the subject's skin temperature; and the status of
the piezo alarm. The number of minutes that have elapsed since the
remote device was first attached to the subject may also be
displayed.
[0114] In one embodiment, the results may be displayed graphically,
as discussed above with reference to FIG. 10.
[0115] As discussed above, the method and device of the present
invention included an alarm function that provides an audible
and/or visual notification when predetermined conditions are met.
In one embodiment, the following alarms may be provided: (1)
hypoglycemic; (2) hypoglycemic anticipated; (3) hyperglycemic; (4)
hyperglycemic anticipated; (5) low remote device battery; (6) low
base device battery; (7) communication link lost; (8) communication
link disturbed; (9) bad sensor data; (10) 1 hour left; and (11) 24
hours exceeded. Other alarms may be provided as necessary and
desired.
[0116] These messages may also be transmitted to and displayed on a
patient terminal via a central database, and/or displayed at a
central nurse's station.
[0117] In general, a single measurement that meets a predetermined
condition is insufficient to trigger an alarm. Rather, two (or
more) consecutive alarm conditions are required to trigger the
alarm. The number of consecutive alarm conditions may be increased
or decreased as necessary and/or desired.
[0118] Each of these alarms will be discussed in greater detail
below. Although a variety of conditions precedent for each alarm
may be used, a set of preferred conditions will be discussed.
[0119] The hypoglycemic alarm may be triggered when two consecutive
glucose predictions are below a preset limit. In one embodiment,
the preset limit may be 60 mg/dl. In addition, the preset limit may
vary from subject to subject.
[0120] The hypoglycemic anticipated alarm may be triggered when
five minute averaged rate of change predicts that two consecutive
glucose readings will be below the hypoglycemic preset limit within
ten minutes.
[0121] The hyperglycemic alarm may be triggered when two
consecutive glucose predictions are above a preset limit. In one
embodiment, the preset limit may be 200 mg/dl. In one embodiment,
the preset limit may be 160 mg/dl. In addition, as with the preset
limit for the hypoglycemic alarm, the preset limit may vary from
subject to subject.
[0122] The hyperglycemic anticipated alarm may be triggered when
five minute averaged rate of change predicts that two consecutive
glucose readings will be above the hyperglycemic preset limit
within ten minutes.
[0123] The low remote device battery and low base device battery
alarms may be triggered when the measured voltage on either battery
falls below a predetermined voltage. In one embodiment, the
predetermined voltage may be set in order to provide at least a
certain amount of time before the battery fails. For example, when
the battery voltage for the remote device falls below 2.8 VDC for
two consecutive transmissions, or when the battery voltage for the
remote device falls below 6.0 VDC, the respective alarms are
triggered.
[0124] Power-saving techniques, such as a reduction in power to the
display, may be employed to conserve power once the alarm condition
is met.
[0125] The communication link lost alarm may be triggered when two
consecutive measurements are missed.
[0126] The communication link disturbed alarm may be triggered when
two consecutive data streams with valid identification code have
invalid check sum values.
[0127] The bad remote device data alarm may be triggered when two
consecutive data streams have sensor currents below a predetermined
value, such as 10 nA (any time) or above a predetermined value,
such as 1 uA, after a certain period of operation, such as 35
minutes.
[0128] The 1 hour left alarm may be triggered when two consecutive
data streams report times greater than 1380 minutes (i.e., 23
hours).
[0129] The 24 hours exceeded alarm may be triggered when two
consecutive data streams report times greater than 1440 minutes
(i.e., 24 hours)
[0130] The alarms may be displayed until the mute switch is
pressed. In the case of multiple alarms, the base device may queue
the alarms in a first in first out sequence. Each time the mute
switch is pressed, the current alarm will be cleared and the next
alarm in the queue will be displayed. In one embodiment, certain
alarms, such as hypoglycemic and hyperglycemic will have priority
over all other alarms and be displayed regardless of their position
in the queue.
[0131] FIG. 12 illustrates a method for identifying errors in the
transmission of data. In step 1205, data may be transmitted
wirelessly between the remote device and the base device of the
system. As discussed above, in some embodiments, this data may
contain a measurement of the current produced at remote device, a
measurement of the subject's skin temperature, and a measurement of
the transmitter unit's battery. This data may also have been
formatted to include a timestamp value, checksum value, and a ID
number.
[0132] In step 1210, the security and accuracy of this transmitted
data may be verified. In one embodiment of the method, an error
module may use a microprocessor to compare the timestamp of the
most recent data transmission to that of previous transmissions, to
compare the data identification f the most recent data transmission
to that which is stored in the base device's memory, to verify the
transmitted data's checksum value, and to analyze the value of the
current produced in the remote device.
[0133] In step 1215, the system may notify the user if the data is
found to be insecure or inaccurate. In one embodiment of the
method, the error module may sound an alarm if (1) a comparison of
the data timestamps shows that two consecutive transmissions have
been missed (2) two consecutive data transmissions have incorrect
checksum values (3) a predetermined number of measurements for the
current in remote device are below or above certain preset values.
In one embodiment, it two measurements are below or above the
preset values, the alarm is activated.
[0134] In one embodiment, system 100 may interface with a mechanism
for providing insulin. Thus, with this addition, not only is the
hypoglycemic or hypoglycemic conditions detected and/or predicted,
but the conditions are appropriately treated automatically. In one
embodiment, the initiation of treatment requires human
authorization, i.e., the insulin cannot be administered without a
human authorizing the administration. In other embodiments, human
authorization is only required for the administration of insulin in
extreme conditions.
[0135] The present invention contemplates a system that
continuously monitors the amount of insulin treatment and the
effect of that insulin treatment on the subject's glucose level.
Because the effect of insulin on a glucose level will vary from
subject to subject, and even within the same subject, the system
may attempt to determine an optimum insulin treatment based on past
performance. However, until several insulin treatments are
observed, it may be difficult for the contemplated system to
accurately determine the amount of an insulin treatment required.
Therefore, until a sufficient number of observations have been
completed, the system may require all insulin to be administered by
a human.
[0136] The various embodiments of the systems and methods described
and claimed herein provide numerous advantages. For example, the
systems and methods permit continuous, noninvasive detection of a
subject's glucose levels. Thus, a user can monitor the a subject's
post operative glucose levels more frequently, effectively, and
comfortably. Such improved systems and methods for monitoring post
operative glucose levels may help to reduce a subject's risk of
infection and reduce hospitalization.
[0137] Other embodiments, uses, and advantages of the present
invention will be apparent to those skilled in the art from
consideration of the specification and practice of the invention
disclosed herein. The specification and examples should be
considered exemplary only.
* * * * *