U.S. patent application number 11/318216 was filed with the patent office on 2006-05-11 for generic multi-step therapeutic treatment protocol.
This patent application is currently assigned to Medtronic, Inc.. Invention is credited to Peter J. Kovach, Craig R. Lang, David C. Ullestad.
Application Number | 20060100609 11/318216 |
Document ID | / |
Family ID | 23168512 |
Filed Date | 2006-05-11 |
United States Patent
Application |
20060100609 |
Kind Code |
A1 |
Kovach; Peter J. ; et
al. |
May 11, 2006 |
Generic multi-step therapeutic treatment protocol
Abstract
A generic treatment protocol is disclosed for therapeutically
treating a patient via an implantable treatment device. Treatment
steps can be defined to start and end at absolute times, or can be
programmed via telemetry to start a certain amount of time after
termination of a previously executed treatment step. Treatment
steps have a treatment rate or dose attribute and a duration
attribute. Treatment steps may optionally enable patient-activated
bolus overlays. Patient-activated rate or dosage adjustments can
also optionally be enabled. Repeated-execution treatment-step
groups are also provided. Such treatment-step groups can have start
and end times, a group duration, and a group total dose, each
defined in a manner similar to that for a treatment step.
Treatment-step groups include a repetition count, which could be
set to a value that causes the group to repeat forever. Single
execution treatment steps can, accordingly, be programmed to
execute before and/or after a repeated-execution treatment-step
group.
Inventors: |
Kovach; Peter J.; (Fridley,
MN) ; Lang; Craig R.; (Brooklyn Center, MN) ;
Ullestad; David C.; (Maple Grove, MN) |
Correspondence
Address: |
BANNER & WITCOFF, LTD.
TEN SOUTH WACKER DRIVE
SUITE 3000
CHICAGO
IL
60606
US
|
Assignee: |
Medtronic, Inc.
Minneapolis
MN
|
Family ID: |
23168512 |
Appl. No.: |
11/318216 |
Filed: |
December 23, 2005 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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10459672 |
Jun 11, 2003 |
7008413 |
|
|
11318216 |
Dec 23, 2005 |
|
|
|
09302613 |
Apr 30, 1999 |
6579280 |
|
|
10459672 |
Jun 11, 2003 |
|
|
|
Current U.S.
Class: |
604/891.1 |
Current CPC
Class: |
A61N 1/3605 20130101;
A61M 5/14276 20130101; G16H 20/30 20180101; A61M 5/172 20130101;
G16H 20/17 20180101; A61M 2205/3523 20130101; A61M 2005/14208
20130101 |
Class at
Publication: |
604/891.1 |
International
Class: |
A61K 9/22 20060101
A61K009/22 |
Claims
1. A therapeutic treatment device adapted to be implanted within a
patient's body, the treatment device including a computer-readable
medium having computer-executable instructions for causing a
processor to store generic therapeutic treatment protocol
parameters to thereby define a specific therapeutic treatment
protocol by performing steps comprising: storing at least one
user-selectable treatment-step duration and at least one
user-selectable treatment rate or dose corresponding, respectively,
to a user-selectable number of one or more treatment steps; storing
in response to a downlink at least one user-selectable number
indicative of a number of treatment steps to be included in one or
more corresponding treatment step groups; storing at least one
treatment-step-group repetition count for at least one of the
treatment-step groups; and storing, for at least one of the
treatment-step groups, an absolute start time and an absolute end
time.
2. The treatment-device computer-readable medium of claim 1,
wherein the absolute start time and the absolute end time are
specified in a form indicative of a time-of-day.
3. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing a
value for the treatment-step-group repetition count indicative of a
finite number of treatment-step-group repetitions.
4. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing at
least one treatment-step-group repetition count that indicates that
at least one treatment-step group should repeat forever.
5. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing at
least one user-selectable treatment-step-group duration for at
least one of the treatment-step groups.
6. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing
generic treatment protocol parameters defining a series of
single-execution treatment steps to be executed before execution of
the treatment-step groups.
7. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing
generic treatment protocol parameters defining a series of
single-execution treatment steps to be executed after execution of
the treatment-step groups.
8. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing at
least one start delay, specified relative to completion of at least
one of the treatment steps, for at least one of the treatment-step
groups.
9. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing an
indication that a patient-activated bolus is allowed to be overlaid
onto at least one of the treatment steps.
10. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing an
indication that a patient-activated treatment-rate adjustment is
allowed to be overlaid onto at least one of the treatment
steps.
11. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing an
indication that a physician has disallowed any patient-activated
boluses from being overlaid onto at least one of the treatment
steps.
12. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing an
indication that a physician has disallowed any patient-activated
treatment-rate adjustments from being overlaid onto at least one of
the treatment steps.
13. The treatment-device computer-readable medium of claim 1,
further including computer-executable instructions for storing an
indication that the treatment device should, at a predetermined
time, switch from a first time-zone representation of time to a
second time-zone representation of time based upon expected patient
travel from a first time zone to a second time zone.
14. A therapeutic treatment device adapted to be implanted within a
patient's body, the treatment device having a computer-readable
medium having computer-executable instructions stored thereon,
providing treatment steps and treatment-step groups, the device
further comprising input means adapted to receive input from the
user for selecting the number, duration and rate or dose of each of
said treatment steps; wherein said number is more than one and
indicates the number of treatment steps to be included in one or
more corresponding treatment-step-groups, and wherein said input
means is further adapted to receive input from the user to select a
treatment-step-group repetition count and a treatment step group
duration.
15. The treatment device of claim 14, wherein said input means is
adapted to receive input from the user for selecting the repeated
execution of at least one of said one or more treatment-step groups
forever.
16. The treatment device of claim 14, wherein said input means is
adapted to receive input from the user for selecting the optional
execution of a series of single-execution treatment steps before
executing a treatment-step group.
17. The treatment device of claim 14, wherein said input means is
adapted to receive input from the user to select the start of
execution of at least one of the one or more treatment-step groups
at a predetermined start time and the end of the execution of said
at least one of the one or more treatment-step groups at a
predetermined end time.
18. The treatment device of claim 14, wherein said input means is
adapted to receive input from the user to select the start of
execution of at least one of the one or more treatment-step groups
after a corresponding user-selectable start delay relative to
completion of execution of one of said one or more treatment
steps.
19. The treatment device of claim 14, wherein said input means is
adapted to receive input from the user to select a
patient-activated bolus to be provided during at least one of the
one or more treatment steps.
20. The treatment device of claim 14, wherein said input means is
adapted to receive input from the user to select a
patient-activated treatment rate adjustment to be provided during
at least one of the one or more treatment steps.
21. The treatment device of claim 14, wherein said input means is
adapted to receive input from the user to select the execution of
at least one of the one or more treatment step groups to start at
an absolute start time; and to receive input from the user to
select the execution of said at least one or more treatment step
groups to end at a corresponding absolute end time.
22. The treatment device of claim 14, wherein said device is an
infusion-pump for therapeutically infusing medicaments into a
patient's body.
23. The treatment device of claim 22, said input means being
adapted to receive input from the user to select at least one of
the one or more infusion steps to allow a bolus activated by the
patient via telemetry to be overlaid onto the at least one of the
one or more infusion steps.
24. The treatment device of claim 22, said input means being
adapted to receive input from the user to select at least one of
the one or more infusion steps to allow a rate adjustment activated
by the patient via telemetry to be overlaid onto the at least one
of the one or more infusion steps.
25. The treatment device of claim 14, wherein said device is a
nerve stimulator for therapeutically stimulating the nervous system
of a patient via an electric nerve stimulator implanted within the
patient's body.
26. The treatment device of claim 25, said input means being
adapted to receive input from the user to select at least one of
the one or more stimulation steps to allow a bolus activated by the
patient via telemetry to be overlaid onto the at least one of the
one or more stimulation steps.
27. The treatment device of claim 25, said input means being
adapted to receive input from the user to select at least one of
the one or more stimulation steps to allow a rate adjustment
activated by the patient via telemetry to be overlaid onto the at
least one of the one or more stimulation steps.
28. A therapy treatment device configured to be implanted within a
patient's body, the therapy treatment device comprising: a housing;
a processor mounted in the housing an antenna in communication with
the processor; and a memory including computer executable
instructions for causing the processor to perform the steps: (a)
receiving a downlink containing a treatment protocol; (b) storing
in the memory at least one user-selectable treatment-step duration
and at least one user-selectable treatment rate or dose
corresponding, respectively, to a user-selectable number of one or
more treatment steps; (b) storing in the memory least one
user-selectable number indicative of a number of treatment steps to
be included in one or more corresponding treatment step groups; and
(c) storing at least one treatment-step-group repetition count for
at least one of the treatment-step groups.
29. The device of claim 28, wherein the protocol received in (a) is
a complex continuous mode.
Description
[0001] This application is a divisional of application Ser. No.
10/459,672, filed Jun. 11, 2003, now U.S. Pat. No. ______, which is
a divisional of U.S. Pat. No. 6,579,280, filed Apr. 30, 1999.
FIELD OF THE INVENTION
[0002] This invention relates to generic building blocks for
specifying various modes of treating a patient via drug infusion or
electrical nerve stimulation using a generic multi-step treatment
protocol including single-execution treatment steps and
repeated-execution treatment-step groups.
BACKGROUND OF THE INVENTION
[0003] Devices and techniques for treating neurological disorders
by drug infusion and by electrical stimulation of a person's
central nervous system are well known in the prior art. For
instance, U.S. Pat. No. 5,713,922 to King, U.S. Pat. No. 5,782,798
to Rise, and U.S. Pat. No. 5,814,014 to Elsberry et al., each
assigned to Medtronic, Inc. of Minneapolis, Minn., disclose such
devices and techniques and are hereby incorporated by
reference.
[0004] Such treatment devices and techniques often employ
drug-infusion pumps and/or electrical pulse generators that are
implanted within a patient's body. Accordingly, available memory
for storing the parameters, such as treatment dose, duration, and
timing, of various treatment protocols is severely limited. As a
result, known implantable treatment devices are capable of storing
a treatment protocol via telemetry that implements only a single
treatment mode, such as single bolus, simple continuous, periodic
bolus, or complex continuous treatment protocols. Single bolus
refers to a non-recurring, finite treatment period. Simple
continuous is a continuous treatment at a fixed treatment level.
Periodic bolus refers to a single periodically recurring finite
treatment period. Complex continuous refers to a plurality of
treatment periods that periodically repeat themselves.
[0005] FIG. 2 depicts a prior art manner of specifying a complex
continuous treatment protocol. The vertical axis represents the
treatment rate. The horizontal axis represents elapsed time from
the treatment protocol having been downlinked to the treatment
device. In FIG. 2, the location of the vertical axis along the
horizontal axis represents the time at which the treatment protocol
was downloaded to the treatment device, as depicted at 100. For
each example given in this document, the time at which the
treatment prescription was downlinked to the treatment device will
be assumed to be 3:00 PM, local time. In FIG. 2, a complex
continuous treatment protocol is depicted in which a background
rate of 20 microliters/hour is infused, as depicted at 102-1
through 102-8 (collectively 102). Note that, while the examples
refer to infusion protocols, they are equally applicable to
stimulation protocols. Background rate 102 is in effect when no
treatment step is being performed.
[0006] The complex continuous treatment protocol depicted in FIG. 2
has the additional following attributes: the treatment cycle time
is 24 hours; between 6:00 AM and 8:00 AM, 600 microliters is
infused; between 11:00 AM and 1:00 PM, 200 microliters is infused;
and between 9:00 PM and 11:00 PM, 500 microliters is infused.
[0007] In order to program such a treatment protocol using known
prior art methods, treatment step 104-1, which corresponds to the
500 microliter treatment step from 9-11 PM, is programmed to start
after a delay of 6 hours from the time the protocol is downlinked
to the treatment device, namely, 3:00 PM. The treatment rate is
determined by dividing the dose by the treatment-step duration, in
this case 500 microliters divided by 2 hours, which is 250
microliters/hour. Accordingly, treatment step 104-1 would be
programmed to include a delay from downlinking of 6 hours, during
which the background treatment rate would be in effect, as depicted
by 102-1. Treatment step 104-1 would also be programmed to provide
treatment at 250 microliters/hour for 2 hours. Similarly, treatment
step 106-1 would be programmed to include a delay from the
completion of treatment step 104-1 of 7 hours, during which
background treatment 102-2 would be in effect, and treatment at 300
microliters/hour for 2 hours. Treatment step 108-1 would be
programmed to include a delay from the completion of treatment step
106-1 of 3 hours, during which background treatment 102-3 would be
in effect, and treatment at 100 microliters/hour for 2 hours.
[0008] Following the completion of treatment step 108-1, background
rate 1024 would be in effect for the remaining 2 hours of the
24-hour treatment cycle.
[0009] Then, the 24-hour cycle would repeat itself in perpetuity or
until a new treatment protocol is downlinked to the treatment
device. Accordingly, background rates 102-5 through 102-8 of the
second 24-hour treatment cycle shown in FIG. 2 correspond to
background rates 102-1 through 102-4, respectively, of the first
24-hour treatment cycle shown in FIG. 2. Similarly, treatment steps
104-2, 106-2, and 108-2 of the second 24-hour treatment cycle shown
in FIG. 2 correspond to treatment steps 104-1, 106-1, and 108-1,
respectively, of the first 24-hour treatment cycle shown in FIG.
2.
[0010] Such known methods of specifying treatment protocols
undesirably require that each time a change from one infusion mode,
such as single bolus, simple continuous, periodic bolus, or complex
continuous, to another infusion mode is desired, the new treatment
protocol must be downlinked to the treatment device. In other
words, known implantable treatment devices are incapable of storing
multiple treatment-mode protocols. Patients and
physician-programmers of such treatment devices are therefore
severely inconvenienced by having to re-program such treatment
devices each time an infusion mode change is made.
BRIEF SUMMARY OF THE INVENTION
[0011] It is therefore an object of this invention to overcome the
shortcomings of the prior art by providing a generic treatment
protocol for treating a patient via an implantable treatment
device. The generic treatment protocol of this invention provides
significantly improved versatility in implementing known treatment
protocols, without the inconvenience of re-programming upon
transitions between different treatment modes that is required when
programming treatment protocols using prior art methods. In
addition, the generic manner in which various treatment protocols
can be specified using this invention also provides significant
advantages for implementing newly created treatment protocols and
for altering treatment protocols based on criteria such a patient
travel between different time zones.
[0012] In one embodiment, the protocol includes a user-selectable
number of one or more treatment steps, each having a corresponding
duration, and one or more treatment-step groups, each having one or
more treatment steps, a user-selectable treatment-step-group
repetition count, and a user-selectable treatment-step-group
duration. Additional aspects of the generic treatment protocol
include: the capability of programming at least one of the
treatment-steps to repeat forever; a series of single-execution
treatment steps optionally executed initially upon programming the
implantable treatment device; at least one of the treatment-step
groups including: an absolute start time and an absolute end time,
a start delay relative to completion of another treatment step, a
user-selectable treatment rate, a user-selectable treatment dose, a
patient-activated bolus, and/or a patient-activated rate
adjustment.
[0013] In another embodiment of this invention, a therapeutic
treatment device adapted to be implanted within a patient's body
has a computer-readable medium that stores computer-executable
instructions for providing a user-selectable number of one or more
treatment steps for treating a patient using an implantable
treatment device. Each of the treatment steps has a corresponding
user-selectable treatment-step duration. In addition, the
treatment-device computer-readable medium stores
computer-executable instructions for providing one or more
treatment-step groups. Each of the treatment-step groups includes:
a user-selectable number of treatment steps; a user-selectable
treatment-step-group repetition count; and a user-selectable
treatment-step-group duration. The treatment-device
computer-readable medium also contains further computer-executable
instructions for performing steps analogous to the additional
aspects of the generic treatment protocol set forth in the
immediately preceding paragraph.
BRIEF DESCRIPTION OF THE DRAWINGS
[0014] FIG. 1 is a schematic view of a patient with a treatment
device implanted within the patient's body.
[0015] FIG. 2 depicts a complex continuous mode treatment protocol
specified using prior art methods.
[0016] FIG. 3 depicts the same complex continuous mode treatment
protocol as in FIG. 2, specified using the generic treatment
protocol of this invention.
[0017] FIG. 4 depicts a complex continuous mode treatment protocol
and a bolus.
[0018] FIG. 5 depicts the same complex continuous mode treatment
protocol as in FIG. 4, a patient-activated rate increase, and two
patient-activated boluses.
[0019] FIG. 6 depicts two different ways of transitioning from
single-execution treatment steps to a repeated-execution
treatment-step group.
DETAILED DESCRIPTION OF THE INVENTION
[0020] FIG. 1 is a schematic view of a patient 10 having treatment
device 14 implanted within the patient's body. Implantable
treatment device 14 is programmable through a telemetry link from
programmer 20, which is coupled via a conductor 22 to a radio
frequency antenna 24. Treatment device 14 could be, but is not
limited to being, a pump for infusing medicaments into a patient's
body or an electrical nerve stimulator for stimulating a patient's
nervous system.
[0021] The fundamental building block for specifying various
treatment protocols according to this invention is referred to as a
treatment step. Treatment steps may be specified to start after a
predetermined delay relative to downlinking of the treatment
protocol to the implanted device or relative to completion of the
preceding treatment step or any other suitable point in time. In
the alternative, a treatment step may have a specified absolute
start time and/or date. A treatment step according to this
invention will include a treatment rate or dose and a treatment
duration. A treatment step could also specify whether or not a
patient-activated bolus may overlay the treatment step and whether,
and if so, how much, of a patient-activated rate adjustment is
allowed during the treatment step.
[0022] Treatment steps according to this invention are typically
specified as executing one time. By grouping one or more treatment
steps into a treatment-step group, the group of one or more
treatment steps can be specified to repeat according to the
treatment-step group specifications. Treatment-step groups
according to this invention include a start time and/or date, which
can be specified as either a delay or as an absolute time and/or
date, as is the case for treatment steps. Treatment-step groups may
include the number of treatment steps in the group. Treatment-step
groups can include a background rate, which specifies the treatment
rate when no treatment step is in effect. A repetition count is
also included. The repetition count is capable of indicating that
the group should repeat forever. Treatment-step groups also have a
duration or period. A treatment-step group could have a maximum
dosage associated with the group.
[0023] In addition to treatment steps and treatment step groups,
boluses could also be defined separately to include a start delay
or start time and/or date, a treatment rate or dose, a treatment
duration, and whether the bolus is low-priority patient-activated,
or high-priority physician-activated. High priority boluses could
always take precedence over treatment steps, while
patient-activated boluses could take precedence only over treatment
steps that specifically allow themselves to be overlaid by
low-priority boluses.
[0024] FIG. 3 depicts the complex continuous mode treatment
protocol depicted in FIG. 2, but programmed or specified using the
generic treatment protocol of this invention.
[0025] The prescription parameters are the same, namely, the
treatment cycle time is 24 hours; between 6:00 AM and 8:00 AM, 600
microliters is infused; between 11:00 AM and 1:00 PM, 200
microliters is infused; and between 9:00 PM and 11:00 PM, 500
microliters is infused. In addition, the complex continuous mode
treatment protocol is downlinked to the treatment device at 3:00
PM, as depicted by dashed line 200-1. The treatment device
automatically determines what treatment step or background rate
should be executing at downlink time 200-1. Background rates 102-1
through 102-6 are the same as those depicted in FIG. 2 with the
same reference numbers. However, the delays between treatment
steps, such as treatment steps 104-1, 106-1, 108-1, and 104-2, may,
but need not be specified. The generic treatment protocol of this
invention provides backward compatibility so that physician
programmers familiar with existing treatment protocol programming
methods will be able to use this invention without learning
anything new, if a physician programmer so desires. Nevertheless,
treatment steps can be programmed using this invention by
specifying treatment start time, a treatment end time, and a
treatment rate or a treatment dose. Accordingly, instead of
programming treatment step 104-1 as described above, namely, as a
delay of 6 hours from the time the protocol is downlinked to the
treatment device and as providing treatment at 250 microliters/hour
for 2 hours, treatment step 104-1 could be programmed to provide
500 microliters between a treatment-step start time of 9:00 PM and
a treatment-step end time of 11:00 PM. Treatment steps can also be
specified as either allowing or not allowing a patient activated
bolus and/or a patient-activated rate or dose adjustment. The
physician-programmer may be provided with the option of disabling
such patient-activated boluses and/or rate adjustments. A specified
background rate can optionally be in effect for any period for
which no treatment step is programmed.
[0026] In addition to programming specific treatment steps,
treatment-step groups can be specified. For instance, the treatment
steps 104-1, 106-1, and 108-1 could be defined as a treatment-step
group including these three treatment steps. Such a treatment-step
group could also include a repetition count specifying the number
of times the treatment-step group should be executed. The
treatment-step group could also be programmed to repeat forever.
The duration of the treatment-step group is also
programmable/user-selectable, which is advantageous for certain
treatments having a treatment cycle time other than 24 hours, such
as certain types of chemotherapy. The treatment-step group also may
include a maximum incremental dosage for each iteration of a
treatment-step group.
[0027] FIG. 4 depicts an exemplary programmed treatment protocol
including a bolus followed by a complex continuous mode treatment
protocol according to the following parameters: background rate: 60
microliters/hour; group duration: 24 hours; [0028] 6-8 AM: 600
microliters; 11 AM-1 PM: 250 microliters; and 9-11 PM: 400
microliters. Bolus 302 of FIG. 4 is depicted as having been
programmed according to the following parameters: 12-2 PM, 0
microliters; 2-4 PM, 500 microliters/hour; and
[0029] 4-8 PM, 0 microliters/hour. The background rate of 60
microliters/hour is in effect as depicted at 300-1. The treatment
device is programmed off, which overrides the background rate,
before and after the bolus 302. The periods during which the
treatment device is off are depicted as 304-1 and 304-2,
respectively.
[0030] FIG. 5 depicts a patient rate adjustment 400, a
patient-activated bolus 402, and the interaction between a
patient-activated bolus 404 that partially overlaps, and is
locked-out by, treatment step 406, which has been programmed to
disable patient-activated boluses. The complex continuous treatment
mode prescription depicted in FIG. 5 has the same attributes as the
complex continuous treatment prescription shown in FIG. 4, namely,
background rate: 60 microliters/hour; group duration: 24 hours; 6-8
AM: 600 microliters; 11 AM-1 PM: 250 microliters; and 9-11 PM: 400
microliters. In addition, the 6-8 AM treatment step also specifies
that patient boluses are disabled during that treatment step.
Patient-activated rate increase 400 is depicted as having been
programmed as a rate increase of 60 microliters per hour from 4-9
PM over background rate 300. Patient bolus 402 is depicted as
having been programmed as 300 microliters per hour from 12-2 AM.
Although a patient bolus is attempted from 5-7 AM at 300
microliters per hour, only the portion of the patient bolus from
5-6 AM will actually be administered because from 6-7 AM, patient
boluses have been specifically disabled during programming of
treatment step 406. Alternatively, a low-priority patient-activated
bolus could be disabled in its entirety if any portion of the
patient-activated bolus comes within a pre-determined time window
either before or after a treatment step that disables
patient-activated boluses. In addition to patient-activated low
priority boluses, physician-programmer high priority boluses may
also be specified. High priority boluses are always executed
regardless of whether a particular treatment step has enabled
patient-activated boluses. As used herein, the term user refers to
a physician who programs the treatment device, as opposed to a
patient within whom the treatment device is implanted.
[0031] FIG. 6 depicts a set of single execution treatment steps,
spanned by double-headed arrow 500, that can optionally be executed
before repeated execution of a treatment-step group, two of which
are spanned by double-headed arrows 502 and 504. Double-headed and
dashed arrow 506 represents the time at which the single execution
treatment steps 500 terminate. Repeated-execution of treatment-step
group 502 is depicted as starting upon termination of single
execution treatment steps 500. This is a specific example of
generically starting execution of a repeated-execution
treatment-step group after a predetermined delay elapses relative
to termination of single execution treatment steps 500. The
predetermined delay between termination of single execution
treatment steps 500 and repeated-execution treatment-step group 502
happens to be 0 seconds. As will be apparent, other suitable delays
could also be used, as desired.
[0032] Repeated-execution treatment-step group 504 differs from
repeated-execution treatment-step group 502 in the manner in which
it begins executing upon termination of single-execution treatment
steps 500. Repeated-execution treatment-step group 504 begins
execution, not necessarily at the beginning of group 504, but at
the point in time of group 504 that corresponds to termination of
single execution steps 500. In other words, execution of
repeated-execution treatment-step group 504 begins, or is
picked-up, "in-progress" upon completion of single execution steps
500, as depicted at 506 in FIG. 6. Completion of each iteration of
treatment-step group 504 is depicted at 512. Upon completion of the
first iteration of repeated-execution treatment-step group 504,
each following iteration of treatment-step group 504 starts at the
beginning of group 504, which beginning is depicted at 514.
[0033] Following repeated execution treatment step groups 502 and
504 are single-execution steps 508 and 510, respectively. Single
execution steps 508 and/or 510 may optionally be executed following
a finite number of repetitions of repeated-execution treatment-step
groups 502 and/or 504, respectively.
[0034] According to an aspect of this invention, the timing of a
particular treatment protocol can be altered according to time zone
changes. For instance, if a patient is planning to travel from the
United States to Europe for a two-week vacation, the timing of
treatment steps and/or treatment-step groups can be programmed to
automatically adjust for the time zone change from the United
States to Europe and to re-adjust the timing upon the expected
return to the United States.
* * * * *