Patent No. 6214032 System for implanting a microstimulator
Patent No. 6214032
System for implanting a microstimulator (Loeb, et al., April 10, 2001)
Assignee: Advanced Bionics Corporation (Sylmar, CA)
Abstract
Improved implantable microstimulators are covered with a biocompatible polymeric coating in order to provide increased strength to the capsule and to capture fragments of the microstimulator should it become mechanically disrupted. Such coating also makes the microstimulator safer and easier to handle. The coating may include one or more diffusible chemical agents that are released in a controlled manner into the surrounding tissue. The chemical agents, such as trophic factors, antibiotics, hormones, neurotransmitters and other pharmaceutical substances, are selected to produce desired physiological effects, to aid, support or to supplement the effects of the electrical stimulation. Further, microstimulators in accordance with the invention provide systems that prevent and/or treat various disorders associated with prolonged inactivity, confinement or immobilization of one or more muscles. Such disorders include pressure ulcers, venous emboli, autonomic dysreflexia, sensorimotor spasticity and muscle atrophy. The microstimulator systems include external control for controlling the operation of the microstimulators. The control includes memory for programming preferred stimulation patterns for later activation by the patient or caregiver.
Notes:
BACKGROUND
OF THE INVENTION
Muscles serve a number of functions, most of which are dependent upon their
regular contraction, which is in turn dependent upon their strength and health.
For example, in addition to the well known functions of supporting the skeleton
and permitting movement, muscles serve to pad the force of bone protuberances
against the skin, and they promote blood flow, particularly through deep blood
vessels. In response to repeated contractions against a load, muscle fibers
grow in cross-sectional area and develop more force, and in response to repeated
contraction over a long period of time, the oxidative capacity and blood supply
of the fibers is enhanced.
In normal individuals, muscles are activated to contract by electrical signals
that are communicated from the brain and spinal cord by way of muscle nerves.
Many medical diseases, physical disabilities and cosmetic disfigurements arise
from abnormal or absent electrical signals to the muscles. Such abnormal or
absent electrical signals may be pathological or may simply be due to prolonged
immobility or confinement that restricts or prevents the voluntary movement
of one or more muscles. Without normal, routine electrical stimulation, muscles
atrophy, that is lose their normal size and strength. Also contributing to muscle
atrophy may be a wide range of other pathophysiological mechanisms, including
absence of sustaining hormones and other endogenous trophic substances.
Many situations exist in which voluntary muscle contraction cannot be used effectively
to operate, condition or strengthen muscles. The most extreme loss of voluntary
muscle function occurs when the brain or spinal cord is injured by trauma, the
growth of tumors or cerebrovascular accidents. In patients suffering from these
conditions, muscles become wholly or partially paralyzed because the electrical
commands that are normally generated in the nervous system are no longer available
to stimulate muscle contractions. Less extreme degrees of muscle weakness and
atrophy can come about when some of the nerve fibers supplying a muscle are
damaged by disease or injury or when the muscle is immobilized or voluntarily
rested, for example by casting or bedrest, in order to recover from an injury
or surgical intervention involving a nearby body part, or other prolonged confinement
or immobilization.
With respect to prolonged physical confinement or immobilization, the affect
of muscle non-use and atrophy frequently leads to two disorders that are particularly
difficult to avoid and expensive to treat, pressure ulcers of the skin and subcutaneous
tissues and retardation of the normal circulation of blood through deep vessels.
Continual, unrelieved pressure on localized regions of skin can result in the
development of pressure ulcers of the skin and subcutaneous tissues, also known
as bed sores or decubitus ulcers. Pressure ulcers are thought to occur when
tissues underlying a site of pressure are deprived of oxygen and nutrients because
blood flow is impeded, and when the area is subjected to frictional and shearing
forces associated with continuous rubbing and movement. Pressure ulcers vary
in size and degree of damage from small regions of redness to deep craters of
tissue erosion passing through skin, connective tissues, muscle and even bone
that can threaten the life of a patient by providing portals of entry for pathogenic
organisms. They are often exacerbated in chronically paralyzed or bedridden
patients because of atrophy of the unused muscles that normally provide a degree
of padding between the skin and underlying bony protuberances. The treatment
of pressure ulcers often requires prolonged, intensive medical care and occasionally
extensive surgery, usually entailing further restrictions in the posture of
the patient, which may further complicate medical and nursing care and cause
other complications.
As mentioned above, prolonged immobilization or physical confinement of a body
part often also results in retardation of circulation of blood through deep
vessels, particularly the veins in an around muscles. For example, the failure
to contract muscles in the limbs at regular intervals, as occurs normally when
walking or standing, is known to cause stasis of blood in some veins. Venous
stasis is a predisposing factor in the formation of clots in the veins. Such
deep venous thrombosis further compromises blood flow to the immobilized body
part and can be the source of dangerous emboli to the heart and lungs. Thrombosed
veins may also become chronically infected, posing a danger of septicemia. Examples
of particular populations of patients that are especially at risk for development
of pressure ulcers and venous emboli include comatose and obtunded patients,
patients who are confined by paralysis to bed or wheelchairs, bedridden patients
who have medical or surgical conditions that limit their activity, and elderly
patients with limited mobility. To reduce complications in these patients, it
is necessary to reestablish movement of the vulnerable body parts; however,
these patients are either incapable of voluntary movement or severely restricted
in their ability to voluntarily move. Therefore, therapists often spend considerable
time manipulating the passive limbs of these patients, but this is expensive
and relatively ineffectual because it is the active contraction of muscle that
tends to pump blood through the veins and to maintain the bulk of the muscle.
It has long been known that muscle contractions can be elicited involuntarily
by stimulating muscles and their associated motor nerves by means of electrical
currents generated from electronic devices called stimulators. This has given
rise to various therapies that seek to prevent or reverse muscle atrophy and
its associated disorders by the application of electrical stimulation to the
muscles and their nerves via these stimulators. For example, the field of research
known as functional neuromuscular stimulation (FNS) or functional electrical
stimulation (FES) has begun, which seeks to design and implement devices capable
of applying electrical currents, in order to restore functional movement to
paralyzed limbs. Similarly, therapies employing stimulators to regularly apply
specific patterns of electrical stimulation to muscles in order to prevent or
reverse atrophy are known.
Many of the earliest stimulators were bulky and relied upon the delivery of
large current pulses through electrodes affixed to the skin, a procedure that
requires careful positioning and fixation of the electrodes to the skin and
frequently produces disagreeable cutaneous sensations and irritation of the
skin. Additionally, such transcutaneous stimulation produces relatively poor
control over specific muscles, particularly those that lie deep in the body.
Thus, this procedure can be time-consuming, uncomfortable, and is generally
useful only for muscles located immediately beneath the skin.
It is also possible to stimulate muscles more directly by passing electrodes
through the skin into the muscles or by surgically implanting self-contained
stimulators and their associated leads and electrodes in the body. These devices
have many configurations, but most are large and have numerous leads that must
be implanted and routed through the body to the desired muscles using complex
surgical methods. Further, they are expensive to produce and the invasive procedures
required for their implantation are impractical for most patients because they
increase rather than decrease the required care and the danger of infection
and other sources of morbidity in patients who are already seriously ill. Thus,
such devices have been used primarily in patients with severe paralysis in order
to demonstrate the feasibility of producing purposeful movements such as those
required for locomotion, hand-grasp or respiration.
More recently a new technology has been described whereby electrical signals
can be generated within specific tissues by means of a miniature implanted capsule,
referred to as a "microstimulator", that receives power and control signals
by inductive coupling of magnetic fields generated by an extracorporeal antenna
rather than requiring any electrical leads. See, U.S. Pat. Nos. 5,193,539; 5,193,540;
5,324,316; and 5,405,367, each of which is incorporated in its entirety by reference
herein. These microstimulators are particularly advantageous because they can
be manufactured inexpensively and can be implanted non-surgically by injection.
Additionally, each implanted microstimulator can be commanded, at will, to produce
a well-localized electrical current pulse of a prescribed magnitude, duration
and/or repetition rate sufficient to cause a smoothly graded contraction of
the muscle in which the microstimulator is implanted. Further, operation of
more than one microstimulator can be coordinated to provide simultaneous or
successive stimulation of large numbers of muscles, even over long periods of
time.
While originally designed to reanimate muscles so that they could carry out
purposeful movements, such as locomotion, the low cost, simplicity, safety and
ease of implantation of these microstimulators suggests that they may additionally
be used to conduct a broader range of therapies in which increased muscle strength,
increased muscle fatigue resistance and/or increased muscle physical bulk are
desirable; such as therapies directed to those muscle disorders described above.
For example, electrical stimulation of an immobilized muscle in a casted limb
may be used to elicit isometric muscle contractions that would prevent the atrophy
of the muscle for the duration of the casting period and facilitate the subsequent
rehabilitative process after the cast is removed. Similarly, repeated activation
of microstimulators injected into the shoulder muscles of patients suffering
from stroke would enable the paretic muscles to retain or develop bulk and tone,
thus helping to offset the tendency for such patients to develop subluxation
at the shoulder joint. Use of microstimulators to condition perineal muscles
as set forth in applicant's copending patent application, Ser. No. 60/007,521,
filed Nov. 24, 1995, entitled "Method for Conditioning Pelvic Musculature Using
an RF-Controlled Implanted Microstimulator", incorporated herein by reference,
increases the bulk and strength of the musculature in order to maximize its
ability to prevent urinary or fecal incontinence.
In addition to the therapeutic use of microstimulators to promote contraction
of specific, isolated muscles in order to prevent or remedy the disorders caused
or contributed to by inactive muscles, the administration of hormones, trophic
factors and similar physiologically active compounds may also be useful. It
is known that the extent to which a muscle will grow in response to any stimulation
regime is affected by the hormonal and chemical environment around the muscle.
Muscle fibers have receptors for many physiologically active compounds that
circulate normally in the blood stream or are released from nerve endings. These
trophic factors have significant effects on the nature, rate, and amount of
growth and adaptation that can be expected of the muscle in response to stimulation,
whether such is produced voluntarily or by electrical stimulation. Perhaps the
best known of these hormones are the androgenic steroids often used by athletes
to increase muscle bulk and strength; but other hormones such as estrogens and
growth hormones are also known to affect muscle properties. For example, the
dramatic reductions in circulating estrogens and androgens that occur in women
following menopause appear to account for decreases in the mass of muscles and
bones, which can be slowed or even reversed by administering the deficient hormones
systemically.
Thus, the beneficial strengthening effects of electrical stimulation can be
maximized by providing the affected muscles with a supportive hormonal environment
for growth. These compounds can be provided systemically by administering them
orally or by injection. However, many such compounds are rapidly metabolized
by the liver, so that high doses must be administered to achieve a desirable
therapeutic effect. This can expose all tissues of the body, including the liver,
to high and perhaps poorly controlled levels of the compound, resulting in undesirable
side-effects that may outweigh the desired actions of the agent. In one aspect,
the present invention recognizes that this problem could be circumvented by
using a more selective method of drug delivery directed specifically to the
electrically exercised muscles. Even if the introduced compound were ultimately
to be cleared by absorption into the bloodstream, high concentrations would
be produced only in the tissue around the target. A steep dilutional gradient
would ensure that other regions of the body were exposed to much lower levels
of the administered compound. By providing a more conducive chemical environment
in the early stages of electrical therapy, it is expected that muscle atrophy
could be reversed more rapidly and effectively. After muscle function has been
reestablished, longer-term performance of the muscle could be more easily maintained
at the desired level by electrical stimulation alone or in combination with
low-dose systemic replacement therapy.
The microstimulators described and claimed herein are elongated devices with
metallic electrodes at each end that deliver electrical current to the immediately
surrounding biological tissues. The microelectronic circuitry and inductive
coils that control the electrical current applied to the electrodes are protected
from the body fluids by a hermetically sealed capsule. This capsule is typically
made of a rigid dielectric material, such as glass or ceramic, that transmits
magnetic fields but is impermeable to water vapor.
Encapsulation in glass is an effective and inexpensive way to ensure a hermetic
seal between the electronic components and the biological tissues. Methods for
forming similar hermetic seals within the confined dimensions of the overall
device are well-known in the fabrication of industrial magnetic reed relays
and diodes and have been described specifically for implantable microstimulators.
See, e.g., U.S. Pat. Nos. 4,991,582; 5,312,439; and 5,405,367, each of which
is incorporated in its entirety by reference herein. Such a hermetic barrier
is important both to ensure good biocompatibility with the body and to protect
the sensitive electronics from the body fluids that might destroy their function.
Unfortunately, however, glass and similarly brittle materials such as ceramic
may crack or shatter as a result of externally applied forces or even residual
stress in the crystalline structure of the material itself. If such an event
occurs within the body or during a surgical procedure, it is desirable to retain
or capture the sharp fragments of the capsule and any internal components so
that they do not irritate or migrate into the surrounding tissues. In a testing
or surgical environment in which devices are handled repeatedly, the hard, slippery
surface of the glass capsule makes the device difficult to handle, and could
increase the likelihood that the device will be dropped or pinched with a force
sufficient to break the glass. Therefore, in one aspect, the present invention
provides a well-chosen biocompatible coating for the glass which would decrease
the lubricity of the device and ensure that glass pieces resulting from device
fracture would be contained/captured in a protective sleeve.
The reaction of a living body to an intact foreign body such as an implanted
microstimulator depends at least in part on the shape and texture of the surface
of the foreign body, as described, e.g., by Woodward and Saithouse (1986). The
surfaces left by the manufacturing processes used for the implanted microstimulator
are constrained by the nature of the materials and processes required to achieve
the desired electronic and mechanical characteristics of the device. Therefore,
modification of the microstimulators' chemical nature and/or superficial physical
contour s to avoid, prevent and/or discourage an immunological response by the
body, would be advantageous. Additionally, in selecting an appropriate coating
material the opportunity arises for the introduction of various chemical compounds,
such as trophic factors and/or hormones, as discussed above, into or onto the
coating. Such compounds could then diffuse from the surface of the coating into
the surrounding tissues for various therapeutic and diagnostic purposes, as
previously mentioned.
SUMMARY OF THE INVENTION
The present invention provides for the prevention and treatment of various disorders
caused or exacerbated by abnormal or absent electrical signals to the muscles
and apparatus useful therefore. In one aspect, the invention provides an improved
microstimulator having a biocompatible polymeric coating on portions of its
exterior, thereby reinforcing the mechanical strength of the microstimulator
such that it may optionally be implanted deeply into the muscle, while also
providing a means for capturing the fragments of the microstimulator should
mechanical disruption occur. In preferred embodiments, the coatings provided
herein are selected to improve the nature of the foreign body reaction to the
implanted microstimulator by modifying its chemical surface, texture and/or
shape.
The implantable microstimulators disclosed and claimed herein are preferably
of a size and shape that allows them to be implanted by expulsion through a
hypodermic needle or similar injectable cannula. The microstimulator includes
a hermetically-sealed housing, at least two exposed electrodes, and electronic
means within the housing for generating an electrical current and applying the
electrical current to the exposed electrodes. The coating, as described in detail
herein, is formed on at least a portion of the exterior of the microstimulator
in contact with the hermetic seal.
In another aspect of the present invention, the improved microstimulator, in
addition to providing electrical stimulation to the muscle within which it is
implanted, is modified to provide a locally high level of one or more desired
chemical agents or drugs. In a preferred embodiment, the polymeric coating covering
a portion of the microstimulator's surface contains a chemical agent that is
released gradually from the coating. Thus, when the microstimulator is implanted
within or adjacent to a muscle it produces an electrical current that activates
the motor nerves and/or muscle fibers of the muscle while simultaneously dispensing
the chemical agent(s) in the vicinity of the active muscle fibers.
Further, in preferred embodiments, the improved microstimulator is designed
to provide electrical stimulation over a period of many years and to provide
elution of the chemical agent(s) over a period of many days, weeks or longer
without any percutaneous connections to the external world. Release of the chemical
agent from the coating of the microstimulator may be by diffusion or, alternatively,
may be at a predetermined rate controlled by electrical signals produced by
the implantable device.
In yet another aspect of the present invention, systems providing involuntary
movement to muscles for the purpose of preventing, treating and/or slowing the
progress of various complications associated with muscle inactivity, especially
inactivity due to prolonged physical confinement or immobilization, are provided.
These systems employ one or more microstimulators non-surgically implanted in
or near one or more inactive muscles. Once implanted, the prescribing physician
uses an external controller to command each of the implanted microstimulators
to produce various output stimulation pulses in order to determine a pattern
of stimulation that produces the desired muscle contraction pattern. The external
controller retains the programmed stimulation routine and, thereafter, administers
the therapy on a regularly scheduled basis and/or whenever commanded to do so
by the patient or any caregiver.
The systems provided herein are particularly useful for maintaining or improving
the functional capacity of paralyzed, weak, immobilized or under-exercised muscle
without requiring voluntary exercise and for preventing various complications
of prolonged physical confinement, including but not limited to pressure ulcers,
deep venous thrombosis, autonomic dysreflexia and sensorimortor spasticity.
For example, the implantable microstimulators are employed to stimulate specific
muscles in order to reduce the incidence and accelerate the healing of pressure
ulcers on the sacrum heels and other bony protuberances of bedridden or immobilized
patients. Alternatively or additionally, the systems are employed to reduce
the possibility of venous stasis and embolus formation by eliciting regular
muscle contractions in the legs of the bedridden or otherwise immobilized patient.
Advantageously, these systems may be employed to produce the desired pattern
of regular contractions in one or more muscles for periods of days or weeks
without the need for ongoing, continuous patient or caregiver supervision.
DETAILED
DESCRIPTION OF THE INVENTION
The following description is of the best mode presently contemplated for carrying
out the invention. This description is not to be taken in a limiting sense,
but is made merely for the purpose of describing the general principles of the
invention. The scope of the invention should be determined with reference to
the claims.
An implantable device 9 made in accordance with the present invention is illustrated
in FIG. 1. The device 9 includes a narrow, elongated capsule 2 containing electronic
circuit 4 connected to electrodes 6 and 8, which pass through the walls of the
capsule at either end together forming a microstimulator of the type disclosed
and fully described in U.S. Pat. Nos. 5,193,539; 5,193,540; 5,324,316 and 5,405,367,
each of which is incorporated herein, in its entirety, by reference. A coating
10 is applied over the longitudinal extent of the surface of the capsule 2.
In the particular embodiment of FIG. 1, the ends of the coating 11 do not extend
over the surface of electrodes 6, 8, so that the coating does not change the
overall profile of the microstimulator. The device 9 is shaped to permit its
insertion through a tubular insertion cannula, such as a syringe, that can be
passed transcutaneously into a target muscle with or without fluoroscopic guidance,
as described further below.
The capsule 2 may be made of glass or a similar dielectric material, such as
ceramic, that can provide a hermetic barrier to the permeation of body fluids
and water vapor into circuitry 4. The basic design of the current-generating
circuitry 4 is the same or similar to that described in the above-referenced
patents, in which electrodes 6 and 8 may be continuously charged (through inductive
coupling) by a programmable magnitude of direct current and may be occasionally
discharged so as to produce a large, brief stimulation pulse with a programmable
magnitude and duration, which stimulation pulse is used for the activation of
nearby motor nerve and/or muscle fibers.
The coating 10 of the improved microstimulator is selected to both be biocompatible
and to be elastic enough to provide some reinforcement to the capsule 2. Additionally,
it is advantageous and preferred that the material chosen to form the coating
10 serve to reduce the risk of injury from and to provide means for the capture
of capsule fragments in the event the capsule is broken. Finally, it is desirable
that the coating 10 chosen reduces the lubricity of the device, as glass and
ceramic materials, of which the capsule 2 is most often constructed, are slippery.
It will be appreciated by those of skill in the art that several different coatings
are available having these characteristics. By way of example only and in no
way to be limiting, the polymeric coating 10 may be formed of a silicone elastomer
or a thermoplastic material, such as polyethylene, polyester, polyurethane or
a fluorinated carbon chain from the TEFLON family.
The preferred method of application of coating 10 depends on its chemical composition
and physical properties. For example, in one embodiment, the coating 10 is formed
from a thin-walled extrusion of silicone elastomer whose inside diameter is
slightly smaller than the outside diameter of capsule 2. The extruded tubing
is cut to the desired length and its diameter temporarily expanded by absorption
of an appropriate solvent such as heptane, toluene or xylene. The expanded silicone
tubing is then slipped over the microstimulator, subsequently shrinking tightly
onto the surface of the microstimulator as the solvent is evaporated from the
silicone elastomer, thereby forming the desired coating 10.
In another embodiment, the coating 10 is made from a thermoplastic material
such as a polyethylene, polyester, polyurethane or a fluorinated carbon chain
from the Teflon family. A thin-walled extrusion of such thermoplastic material
whose inside diameter is smaller than the outside diameter of capsule 2 is mechanically
expanded so as to temporarily increase its inside diameter. The expanded extrusion
is then cut to the desired length, slipped over the microstimulator, and caused
to shrink onto the surface of the microstimulator by briefly heating it to the
temperature at which it contracts toward its unexpanded dimensions, thereby
forming the desired coating 10.
In another embodiment, coating 10 is made from a liquid solution containing
melted, dissolved or unpolymerized material which is applied to the surface
of the microstimulator by dip-coating, injection molding, or other suitable
methods known to those of skill in the coating art. After covering the desired
portions of the microstimulator, the coating 10 is allowed or caused to harden
by appropriate means.
FIG. 2 shows an alternative embodiment of a microstimulator 16 in accordance
with the present invention. The microstimulator 16 of FIG. 2 is similar to the
microstimulator 9 of FIG. 1 except that in FIG. 2 the ends 12 of coating 10
extend over electrodes 6, 8, thereby preventing concavities 14 from coming into
direct contact with tissues surrounding the implanted microstimulator. Advantageously,
concavities 14 may be filled with a solid material, such as silicone or other
material, to eliminate the presence of pockets of fluid that may act as a nidus
of chronic infection.
FIG. 3 shows another embodiment of an improved microstimulator 18 in accordance
with the present invention. The microstimulator 18 of FIG. 3 is similar to the
microstimulator 9 of FIG. 1 except that the coating 10 in FIG. 3 contains a
chemical agent 20 which diffuses from the surface of the coating 10 into the
surrounding tissues. The chemical agent 20 may be any of a large number of pharmacologic
and diagnostic agents whose presence in the tissue surrounding the implantable
microstimulator is desired as part of the treatment received by the patient.
Examples of suitable chemical agents 20 include anti-inflammatory or antibiotic
compounds intended to reduce the foreign body reaction, hormones, neuromodulators
and neurotransmitters intended to potentiate the effects of the electrical currents,
or dyes intended to mark the original location of the implanted microstimulator.
This list of agents provides only examples and is not intended to limit the
scope of the invention set forth in the claims.
The method of introduction of the chemical agent 20 into or onto the coating
10 depends upon the chemical nature of the agent and the selection of an appropriate
coating material. In general, the types of agents and compatible coatings that
may be used therewith are known to those of skill in the arts of chemical binding
and diffusion and the design of sustained release pharmaceuticals.
In a preferred embodiment, the chemical agent 20 comprises a long-acting compound
of testosterone, such as testosterone propionate, cypionate or enanthate. This
agent 20 is mixed with or adsorbed onto a silicone elastomer that is injection-molded
or dip-coated and subsequently polymerized to provide a thin coating 10, which
coating 10 is spread over a substantial portion of the surface area of the capsule
2. It should be appreciated that silicone is a highly biocompatible compound
that has been used previously to administer steroids to experimental animals
without exposing the animals to the trauma of repeated injections. However,
it should also be appreciated that coating 10 could be formed from a variety
of other materials, or by using a variety of other processes, as described above.
It is thus seen that in this preferred embodiment, agent 20 comprises a trophic
compound used to enhance muscle development, specifically a testosterone derivative.
It should be appreciated that such compounds have been used for many years in
humans to treat endocrine disorders or to retard the development of estrogen-sensitive
mammary tumors, and that a single intramuscular bolus of the compound will exert
its actions for 2 to 4 weeks. The chemical agent 20 associated with the external
coating 10 of the present invention, however, could be selected from a variety
of trophic chemicals with actions on muscle or connective tissues, and could
be bound to the coating in any manner that advantageously affects its rate of
release. The rate of release may be designed to be anywhere from a few hours
to a few days or weeks. Furthermore, agent 20 might actually consist of a multiplicity
of active compounds, various of which affect or influence muscle fibers, nerve
fibers, connective tissue, or inflammatory cells so as to modify many aspects
of the response of the tissues to the presence and activation of the device.
Certain composite materials, such as the drug-filled polymeric matrix that may
be used for coating the device, have the property that electrical voltage influences
a change in the rate at which the fillers diffuse form the matrix. Where it
is desirable to use such compositions, the microstimulator illustrated in FIG.
2 is particularly useful, as the electrical output signals generated by circuit
4 are applied, at least in part, to the coating 10 by its contact with the electrodes
6, 8 of the device. Such electrical output signals are systematically varied
so as to produce the desired rate of elution of the chemical agent 20 into the
tissues surrounding the implanted device. Thus, it is seen that the electrical
currents produced by electrodes 6 and 8 in the process of stimulating the muscle
could also advantageously have the effect of increasing the elution rate of
agent 20 simultaneously with the electrically-induced muscle contraction.
As illustrated in FIG. 4, rate control of the elution of the chemical agent
20 from the coating 10 may alternatively be managed using additional electrodes
26 which are affixed to the capsule 2 and connected to the circuitry 4 of the
device. Such additional electrodes provide for separate control of the electrical
currents and voltages applied to stimulate the muscle electrically and to control
the rate of elution of chemical agent 20 from the polymeric coating 10. Advantageously,
such multiple electrodes facilitate the use of electrophoretic current through
coating 10 to effect the release of agent 20, independent of the currents required
to charge and discharge those electrodes associated with muscle or nerve stimulation.
As illustrated in FIG. 4, electrode 26 is entirely covered by the polymeric
coating 10, whereas electrodes 6 and 8 are exposed to the body fluids. Electrical
current applied between electrodes 26 and 8 would pass through coating 10 to
effect electrophoretic release of chemical agent 20. Electrical current applied
between electrodes 6 and 8, on the other hand, would pass unobstructed through
the body fluids and tissues to effect electrical stimulation of nearby nerve
or muscle fibers.
Referring now to FIG. 5, an improved microstimulator 28 is shown implanted into
muscle 30. In this embodiment, as well as in those of FIGS. 1-3, the improved
microstimulator receives power from an external control device 40. The external
control device 40 generates an alternating magnetic field, illustrated symbolically
by the lines 36, through an external coil 38, which coil may advantageously
be located underneath the patient in a seat or mattress pad or in a garment
or item of bedclothes. The magnetic field 36 is coupled with an implanted coil
33, which forms part of the microstimulator device 28, and induces a voltage
and current within the coil 33. The induced voltage/current in the coil 33 is
used to power the electronic circuit 4, and fluctuations (e.g., modulation)
of the varying magnetic field 36 are used to control operation of the electronic
circuit 4. That is, the device 28 delivers current to its electrodes 6, 8 according
to instructions encoded in fluctuations of the magnetic field 36. In this preferred
embodiment, electrical current emitted from electrodes 6 and 8 stimulates motor
nerve fibers 32. Muscle fibers themselves are relatively difficult to activate
via such electrical currents, but the motor nerve fibers are more readily stimulated,
particularly if the microstimulator is located near them in the muscle. Each
time a motor nerve fiber is excited, it conveys an electrical impulse through
its highly branched structure to synaptic endings on a large number of muscle
fibers, which results in the activation of essentially all of those muscle fibers.
Electronic circuit 4, then, controls the amplitude and duration of the electrical
current pulse emitted by the microstimulator 28, thereby determining the number
of such motor nerve fibers that are excited by each pulse.
As an example of a preferred use of the improved microstimulator, the prescribing
physician uses a programming station 44 to command external controller 40 to
produce various stimulation pulses, during the initial treatment session after
implantation of the improved microstimulator 28. This is done in order to determine
an exercise program that will provide the desired therapeutic muscle contraction
program for the individual patient. The exercise program is down-loaded into
a memory element 42 of the external controller 40, where it can be reinitiated
at will by, for example, manually activating control 46. This manual control
may be performed, e.g., by the patient or an attending caregiver. In the preferred
embodiment, programming station 44 is a personal computer, external controller
40 contains a microprocessor, and memory element 42 is a nonvolatile memory
bank such as an electrically programmable read-only memory (EEPROM). However,
it will be appreciated by those of skill in the art that many different systems,
architectures and components can achieve a similar function.
In accordance with a variation of the invention, shown in FIG. 6, a battery
46 is included within the implanted device (microstimulator), and is employed
as a continuous source of power for the electronic circuit 4. Such battery also
provides storage and production means for a program of output currents and stimulation
pulses that may then be produced autonomously by the implanted device without
requiring the continuous presence of extracorporeal electronic components, i.e.,
without the need for an external control device 40. In such instance, means
would be provided for transmitting the desired program to each microstimulator
and for commanding each microstimulator to begin or to cease operating autonomously.
Advantageously, such an embodiment as shown in FIG. 6 may provide for continuous
biasing current or voltage applied to coating 10 (when at least one of the electrodes
is positioned to contact the coating 10, as shown in FIG. 2 above, or when a
separate electrode is embedded in the coating 10 as illustrated in FIG. 4, above)
so that the rate of elution of agent 20 would always be well-controlled.
In a preferred implantation method, the microstimulator is injected into the
muscle of interest through an insertion device whose preferred embodiment is
shown in FIG. 7. The external cannula 110 of the insertion tool is comprised
of a rigid, dielectric material
As an example of a preferred use of the improved microstimulator, the prescribing
physician uses a programming station 44 to command external controller 40 to
produce various stimulation pulses, during the initial treatment session after
implantation of the improved microstimulator 28. This is done in order to determine
an exercise program that will provide the desired therapeutic muscle contraction
program for the individual patient. The exercise program is down-loaded into
a memory element 42 of the external controller 40, where it can be reinitiated
at will by, for example, manually activating control 46. This manual control
may be performed, e.g., by the patient or an attending caregiver. In the preferred
embodiment, programming station 44 is a personal computer, external controller
40 contains a microprocessor, and memory element 42 is a nonvolatile memory
bank such as an electrically programmable read-only memory (EEPROM). However,
it will be appreciated by those of skill in the art that many different systems,
architectures and components can achieve a similar function.
In accordance with a variation of the invention, shown in FIG. 6, a battery
46 is included within the implanted device (microstimulator), and is employed
as a continuous source of power for the electronic circuit 4. Such battery also
provides storage and production means for a program of output currents and stimulation
pulses that may then be produced autonomously by the implanted device without
requiring the continuous presence of extracorporeal electronic components, i.e.,
without the need for an external control device 40. In such instance, means
would be provided for transmitting the desired program to each microstimulator
and for commanding each microstimulator to begin or to cease operating autonomously.
Advantageously, such an embodiment as shown in FIG. 6 may provide for continuous
biasing current or voltage applied to coating 10 (when at least one of the electrodes
is positioned to contact the coating 10, as shown in FIG. 2 above, or when a
separate electrode is embedded in the coating 10 as illustrated in FIG. 4, above)
so that the rate of elution of agent 20 would always be well-controlled.
In a preferred implantation method, the microstimulator is injected into the
muscle of interest through an insertion device whose preferred embodiment is
shown in FIG. 7. The external cannula 110 of the insertion tool is comprised
of a rigid, dielectric material with sufficient lubricity to permit the easy
passage of the microstimulator without scratching its external surface. The
central trocar 120 of the insertion tool is an electrically conductive rod whose
sharpened point extends beyond the insertion cannula, where it can be used to
deliver current pulses to the biological tissue near its point. The initial
insertion of the tool is directed either by a knowledge of musculoskeletal landmarks
or radiographic imaging methods to approach the region of muscle 30 in which
motor nerve fibers 32 enter. Optimally, the insertion device is advanced into
the muscle in parallel with the long axis of muscle fiber fascicles. Electrical
stimuli may be delivered through the metallic trocar by connecting a conventional
electrical stimulator 200 to connector 122 on the trocar By observing the contractions
of the muscle 30, these test stimuli can be used to ensure that the tip of the
insertion device is situated sufficiently close to motor nerve fibers 32 to
permit activation of a substantial portion of the muscle 30 without undesirable
activation of other muscles or nerves. Failure to elicit the desired muscle
contractions would suggest a poor site of placement for the microstimulator
and a need to reposition the insertion tool closer to the site of motor nerve
entry.
When the desired position is reached, the trocar 120 is removed from cannula
110, taking care to keep the cannula 110 in position within muscle 30, and a
microstimulator is pushed through cannula 110 and into muscle 30 using a blunt-ended
push-rod 130.
As stated above, the microstimulators provided herein are particularly useful
in the prevention and treatment of various disorders associated with prolonged
immobilization or confinement; such as muscle atrophy, pressure ulcers and venous
emboli. Referring to FIG. 8, there is illustrated, in diagrammatic form, the
general circumstances that give rise to pressure ulcers and a preferred embodiment
whereby one or more microstimulators may be employed to reduce the incidence
of and/or contribute to the healing of such pressure ulcers. As depicted in
FIG. 8, force 52 applied between bone 50 and firm support surface 56 is transmitted
through intervening soft tissues of the skin 34 and muscle 30, resulting in
compression of skin region 54. Skin region 54 is thus in danger of developing
a pressure ulcer. Active contraction of muscles 30 is induced by electrical
stimulation applied by microstimulator48 and its associated electrodes 6 and
8. Such active contraction makes muscle 30 stiffer, causing force 52 to be dissipated
over a larger region of the skin 34. Further, active contraction of muscle 30
tends to shift the position of the body with respect to surface 56, causing
force 52 to be directed to a fresh region of skin 34. Regular active contraction
of muscle 30 induces various trophic mechanisms in the muscle that maintain
or even enhance the bulk and tone of muscle 30 in its passive state, thereby
reducing the concentration of force 52 on skin region 54.
To further aid in the prevention and/or treatment of the pressure ulcer, the
microstimulator as described above and illustrated in FIGS. 3-6 employing a
coating 10 having a chemical agent 20 associated therewith, may be used. In
this alternative, the chemical agent 20 may be a trophic factor employed to
improve the bulk and tone of the muscle 30 or may be an antibiotic or similar
therapeutic drug useful for preventing infection of the pressure ulcer, or the
chemical agent may be a combination of the two different agents. Increasing
the bulk and tone of the muscle 30, can provide additional padding between the
bone 50 and support surface 56, thereby lessening the force 52 against the skin
region 54.
In the embodiment illustrated in FIG. 8, a microstimulator 48 has been injected
into muscle 30 at (or very near) the skin region site 54 where a potential pressure
ulcer may develop However, it may be satisfactory (or even preferred in some
instances) to inject one or more microstimulators into adjacent muscles or near
various nerves that control muscle 30 and/or other muscles that can affect the
magnitude and direction of force 52 upon various regions of skin 34.
It should be appreciated that contraction of many different muscles and groups
of muscles tends to lift the prominence of bone 50 so as to distribute the load
of the body more evenly across the skin 34, thereby reducing the amount of force
52 applied at a particular skin region 54. Optimally, a particular temporal
pattern of stimulation applied by one or more microstimulators generates a sustained
contraction of the respective muscles that is maintained for several seconds
to permit blood flow into vulnerable tissues. Such is accomplished by the extracorporeal
components illustrated in FIG. 5 and described above. Thus, upon an external
command, or at predetermined intervals, power and command signals sent from
controller 40 cause the various microstimulators to emit a series of electrical
current pulses (i.e., a pulse train) at the desired frequency and amplitude
sufficient to cause the muscles to lift the body for the duration of the pulse
train.
Further movement of the body part typically occurs after cessation of such pulse-train
stimulation because of various nervous reflexes or voluntary movements that
are triggered by the concomitant activation of various sensory nerve fibers
resulting either from direct electrical stimulation of the sensory fibers or
the mechanical consequences of the directly stimulated muscle activity. Such
triggered movements are generally just as important, and may even be more important,
than the directly stimulated muscle activity caused by the microstimulator generated
pulse train for shifting body posture.
FIG. 9 illustrates the general circumstances that give rise to venous stasis
and a particular embodiment for the use of microstimulators to reduce such stasis.
Blood flow 64 in veins 66 running through and between muscles 30,62 depends
in part on compressive forces 52 and general metabolic stimulation resulting
from the occasional active contraction of muscles 30 and 62. In the absence
of such contractions, flow is reduced, resulting in stasis and an increased
likelihood of the formation of clots or thrombi in the veins. One common site
for this problem is in the calf muscles of the lower leg, which extend the ankle.
In accordance with one aspect of the present invention, therefore, one or more
microstimulators 58 are injected into the extensor muscles of the ankle, and
one or more microstimulators 60 are injected into the flexor muscles of the
ankle. The programmed sequence of stimulation stored in memory bank 42 is used
by controller 40 to create the necessary transmission of power and command signals
from coil 38 to cause the microstimulators injected into the ankle muscles to
generate a prescribed stimulation sequence. Ideally, this prescribed sequence
elicits muscle contractions sufficient to shift the position of the foot alternately
into extension and flexion for several seconds. The interval between the various
muscle contractions and the strength and duration of the contraction in each
muscle is set by an attending physician or physiotherapist using a programming
station 44 that downloads the desired program into memory bank 42. The rhythmic
intermittent muscle contractions produced each time the program is activated
causes compressive forces to act on deep veins 66, augmenting venous flow 64
out of the muscle by a pumping action that reduces venous stasis.
It should also be noted that a particular pattern of stimulation applied through
a particular microstimulator, or combination of microstimulators, may also be
effective at reducing the incidence of both pressure sores and venous stasis
simultaneously, as well as generating other useful trophic effects on the muscles
themselves, metabolic stimulation of the cardiorespiratory system, and improvements
in the functioning of nervous pathways responsible for various reflexive and
autonomic functions commonly affected adversely by prolonged immobilization.
Other specific dysfunctions that have been reported to be reduced by regular
electrical stimulation of nerves and muscles include autonomic dysreflexia and
sensorimotor spasticity, particularly in patients suffering from spinal cord
injury.
It should also be noted that the particular complications of pressure sores
and venous stasis illustrated respectively in FIGS. 8 and 9 are intended only
to provide specific examples of the beneficial effects of regular, active muscle
exercise that can be induced by microstimulators, and are not intended to limit
the scope of the invention set forth in the claims regarding the utility of
stimulation applied in this manner. The present invention pertains generally
to all beneficial effects that a caregiver might achieve by the appropriate
implantation and programming of one or more microstimulators in any patient
immobilized for a period of more than a few days.
While the invention herein disclosed
has been described by means of specific embodiments and applications thereof,
numerous modifications and variations could be made thereto by those skilled
in the art without departing from the scope of the invention as set forth in
the claims.
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