 |
Description  |
|
|
BACKGROUND OF THE INVENTION
This invention relates to implantable prostheses and to methods for making
them less susceptible to degradation when inplanted in vivo for extended
periods of time. In particular, it concerns elastomeric polyurethane
insulators for implantable electrical leads such as those used in cardiac
pacing.
Background on biostability of implantable polyurethane elastomers and
devices such as pacing leads can be found in Coury et al., "Biostability
Considerations for Implantable Polyurethanes" Life Support Systems, (1987)
5, 25-39 and in Stokes, "The Biostability of Polyurethane Leads" Modern
Cardiac Pacing, Barold S. Serge, Ed., Mount Kisco, N.Y.: Futura Pub. Co,
1985, pp. 173-98. In general, it is acknowledged that there are a number
of mechanisms for degradation of elastomeric polyurethane pacing leads in
vivo. One is environmental stress cracking (ESC), the generation of crazes
or cracks in the polyurethane elastomer produced by the combined
interaction of a medium capable of acting on the elastomer and a stress
level above a specific threshold. Another is metal ion induced oxidation
(MIO) in which polyether urethane elastomers exhibit accelerated
degradation from metal ions such as cobalt ions, chromium ions,
molybdenium ions and the like which are used alone or in alloys in pacing
lead conductors.
It is believed that the ether linkages in the polyether urethane elastomers
are susceptible to in vivo attack by these mechanisms. Unfortunately, the
most desirable polyether urethane elastomers for pacing lead insulators
are the most flexible polyurethanes which contain the most ether groups
which are subject to ESC and MIO attack. For example, PELLETHANE 2363-80A
is regarded as having nearly ideal flexural properties for pacing lead
designs while PELLETHANE 2363-55D is regarded as being too stiff for many
pacing lead designs. It is well known, however, that the 55D material (and
other harder polyether urethane elastomers) has fewer ether linkages than
the 80A material and is therefore superior in resistance to the identified
mechanisms of in vivo degradation. Efforts have also been made to develop
polyurethane elastomers for pacing lead insulators which have essentially
no ether linkages such as those disclosed in U.S. Pat. No. 4,875,308 to
Coury et al.; International Patent Application WO 92/04390; U.S. Pat. No.
5,133,742 to Pinchuk; and U.S. Pat. No. 5,109,077 to Wick. However, it is
not yet clear whether any of these efforts to make a substantially
ether-free polyurethane elastomer will provide a biostable polyurethane
elastomer with mechanical properties as desirable as the mechanical
properties of the PELLETHANE 80A now favored for use in polyurethane lead
insulators.
U.S. Pat. No. 4,851,009 issued to Pinchuk employs a silicone rubber,
typically a siloxane as a barrier coating over polyurethane to prevent in
vivo cracking of the polyurethane. Unfortunately, the application of the
silicone may require extensive treatments including the use of coupling
agents, primer coats, exposure to a free radical initiator and the like.
In addition, placing silicone over the polyurethane deprives the pacing
lead some of the main advantages of polyurethane; the low coeficient of
friction of polyurethane when wet that makes polyurethane leads easier to
insert and maneuver when two or more leads are inserted in one vein and
the toughness of polyurethane in resisting surface mechanical damage.
Additional background on the problem with polyurethanes can be found in
Zhao et al., "Foreign-body giant cells and polyurethane biostability: In
vivo correlation of cell adhesion and surface cracking", J. Biomedical
Materials Research, Vol. 25, 177-183 (1991); and Zhao et al., "Cellular
interactions with biomaterials: in vivo cracking of pre-stressed
PELLETHANE 2363-80A", J. Biomedical Materials Research, Vol. 24, 621-627
(1990). Dolezel et al in "In vivo degradation of polymers" Biomaterials
1989, Vol. 10, 96-100, describes problems with polyethylene and silicone
rubber in vivo.
It is therefore an object of the present invention to provide a
polyurethane pacing lead insulator with improved resistance to in vivo
degradation.
It is also an object of the present invention to provide a pacing lead
insulator having excellent flexibility and mechanical properties.
SUMMARY OF THE INVENTION
These and other objects have been accomplished by the present invention. We
have discovered that where a flexible pacing lead insulator has a body of
a polyurethane elastomer which is susceptible to degradation cracking when
implanted in vivo over substantial time periods due to a high
concentration of ether linkages, a thin layer of a second polyurethane
elastomer can be applied with a second, lower concentration of ether
linkages to provide a lead insulator with resistance to ESC and MIO while
maintaining the flexibility of the base elastomer. The second elastomer is
selected from the group consisting of a polyether urethane elastomer
having a hardness at least about 90A on the Shore A scale and a
substantially ether-free biostable polyurethane elastomer.
The overlayer may be applied by dip coating, spraying or co-extrusion to
provide a favorable combination of the properties of the two different
materials. The bulk of the insulator material would be a soft polyurethane
having the desired flexibility, preferably a polyether urethane elastomer
having a hardness of 80A on the Shore A scale. Since ESC and MIO are
surface phenomena, a thin layer of the second polyurethane overlayer (e.g.
about 5 microns to about 0.002 inches (0.005 cm) thick) provides favorable
resistance to these degradation mechanisms without appreciably changing
the overall flexibility the lead insulator. Therefore, even if the
mechanical properties of the ESC and MIO resistant polyurethane are
suboptinal for use in pacing lead insulators alone, they can be used in
combination with a material that will provide the desired mechanical
properties. Also, since the materials employed for the base material and
the overlayer are both polyurethanes, they have similar chemical and
physical properties so that the thin layer of the second elastomer can be
applied without the need for cumbersome and expensive surface treatments
to the base material. The lamination may overlay the base polyurethane on
the outside of the lead insulator to prevent ESC, the inner lumen of the
lead insulator to prevent MIO or both.
DETAILED DESCRIPTION OF THE INVENTION
The present invention provides a base insulation of soft polyurethane
elastomer overcoated with a thin layer of a polyurethane elastomer with a
relatively low concentration of ether linkages such as an aliphatic or
aromatic polyether urethane having a hardness at least about 90A on the
Shore A scale or a biostable ether-free polyurethane elastomer. Since the
environmental stress cracking (ESC) in such implantable devices is a
surface phenomenon, very little of the second elastomer needs to overlay
the softer layer. A thin layer, on the order of 0.001 inches (0.0254 mm),
of the is all that is required to impart superior ESC and MIO resistance
to implantable devices. Such thicknesses do not appreciably change the
overall handling characteristics of the completed device, while increasing
the ESC resistance.
METHODS OF APPLICATION
The lamination of the second material layer may be accomplished using any
of the existing well known methods including dipping, spraying, and
co-extrusion, with co-extrusion being preferred. The layer of second
material should generally be in the range of about 0.001 inches (0.0254
mm) in thickness, although it may be thinner or thicker depending on the
application needs.
Coating of polymeric biomedical devices by dipping, spraying, or
co-extrusion techniques are known to those skilled in the art. Special
care and understanding of polymer biostability are required to provide the
optimum product performance. For example, care must be exercised to
minimize antioxidant removal (by thermal or extractive means), to minimize
residual stress in the parts, and to engineer consistent reliable
processes.
ACCEPTABLE OVERLAYING MATERIALS
The acceptable second, overlaying material will be a polyurethane
elastomer; either a polyether urethane elastomer having a hardness on the
Shore A durometer scale of at least about 90A or a substantially
ether-free polyurethane elastomer. The elastomer must also be oxidatively
and hydrolytically stable and have a toughness in the range of
polyurethanes generally. A suitable urethane is PELLETHANE 2363-55D or
PELLETHANE 2363-55DE of Dow Chemical Co. of Midland, Mich. Polyurethanes
essentially equivalent to PELLETHANE 2363-55D are available from other
sources such as B. F. Goodrich, Inc. The PELLETHANE 2363 family of
polymers, including 2363-80A and 2363-55D, are composed of methylene bis
isocyanato benzene (MDI), butane diol (BD) hard segments and
polytetramethylene ether oxide (PTMO) soft segments. The proportion of
hard to soft segments is higher for the harder (Shore 55D) polymer than
for the softer (Shore 80A) material thereby providing fewer ether linkages
which may be subject to in vivo degradation.
Preferably, the urethane is a substantially ether-free polyurethane since
stress cracking appears to have a relation to the ether content of the
polymer, with fewer ether linkages being desirable. A polymer without
ether linkages may be made by substituting aliphatic, polycarbonate or
polydimethylsiloxane groups for the polyether groups of the soft segments.
Ether-free polyurethanes said to be suitable for in vivo use are disclosed
in U.S. Pat. No. 4,875,308 to Coury et al.; published International Patent
Application WO 92/04390; U.S. Pat. No. 5,133,742 to Pinchuk; and U.S. Pat.
No. 5,109,077 to Wick which are incorporated herein by reference in their
entirety. Biostable ether-free polymers include PolyMedica's Chronoflex
AL-80A and Chronoflex AL-55D, Medtronic, Inc.'s family of biostable
polyurethanes (U.S. Pat. No. 4,873,308) and AKZO/ENKA'S PUR series of
polyurethanes. These materials are coatable over the preferred lead
insulator material, PELLETHANE 2363-80A, by methods such as solution
coating or coextrusion.
IMPLANTABLE DEVICES
The ESC and MIO reduction of the invention may be achieved with many
implantable medical devices. Such medical devices can include insulator
sheaths of cardiac pacemaker leads, artificial heart diaphragms,
artificial heart valve leaflets, sewing cuffs and the like. However, the
preferred use of the invention is to provide improved resistance to
degradation in critical lead insulation applications. In a typical lead
and lead insulator assembly, an elastomeric polyurethane insulator is the
outer element through which coiled conductors pass. The configuration can
include separate, mutually insulated coils in which the multiple coils are
carried in separate insulator passages in coaxial or side-by side
arrangement or multi-polar coiled conductors having individually insulated
coil wires which pass through an outer insulator sheath of polyurethane
elastomer. Such a lead system is disclosed in greater detail in U.S. Pat.
No. 5,040,544 issued to Lessar et al. which is incorporated herein by
reference in its entirety. In such lead systems, the polyurethane lead
insulator is essentially an extruded piece of tubing of the desired shape
and size required to carry the conductors. An outside diameter of the
insulator is typically in the range of about 0.020" to 0.090" with a wall
thickness typically in the range of about 0.005" to 0.010". In the
following examples, implanted tubing samples such as those used for pacing
lead insulators were provided with materials and treatments intended to
address the issues of ESC and MIO.
The effect of using an overlaying material of differing mechanical
properties can be easily calculated for a pacing lead insulator. For a
composite tube having an inner, base material and an overlaying, outer
material, the following formula can be applied to determine its stiffness:
##EQU1##
Where E.sub.1 is the elastic modulus of the base material, E.sub.2 is the
elastic modulus of the overlaying material, d.sub.1 is the inside diameter
of the base material, d.sub.2 is the outside diameter of the base material
and the inside diameter of the overlaying material, and d.sub.3 is the
outside diameter of the overlaying material. Therefore, if one wished to
provide a pacing lead insulator with a base material of PELLETHANE 80A and
with an overlaying layer of PELLETHANE 55D, the relative overall stiffness
of the lead insulator would be as set forth in Table 1.
TABLE 1
__________________________________________________________________________
STIFFNESS OF CO-EXTRUDED PACING LEAD INSULATION
BASE COATING
COATING ELASTIC
ELASTIC
INSIDE OUTSIDE
OUTSIDE
THICKNESS
MODULUS
MODULUS
DIAMETER
DIAMETER
DIAMETER
STIFFNESS (EI)
(in) E.sub.1
E.sub.2
d.sub.1 (in)
d.sub.2 (in)
d.sub.3 (in)
COMPOSITE
__________________________________________________________________________
All P80 A
3,400 0.073 0.093 -- 7.7
0.0005 3,400 10,200 0.073 0.0925
0.093 8.3
0.001 3,400 10,200 0.073 0.092 0.093 8.8
0.0015 3,400 10,200 0.073 0.0915
0.093 9.3
0.002 3,400 10,200 0.073 0.091 0.093 9.9
All P55D 10,200 0.073 0.093 -- 23
__________________________________________________________________________
It is therefore apparent that a co-extruded coating with a stiffer material
causes little change in the stiffness of the lead insulator. A lead
insulator of PELLETHANE 55D would be roughly three times as stiff as a
lead insulator of PELLETHANE 80A and yet a coextruded lead insulator with
a 0.001 inch coating of PELLETHANE 55D over a base of PELLETHANE 80A can
be expected to have a stiffness only about 14% greater than the stiffness
of the insulator made with PELLETHANE 80A alone.
EXAMPLE 1
Five different tubings were fabricated and implanted in rabbits to study
ESC resistance. The tubings had a 0.073 inch (0.185cm) ID (inside
diameter) by a 0.093 inch (0.236 cm) OD (outside diameter). The test
material strands consisted of five polysulfone dumbbell shaped mandrels
(each approximately 0.165 cm diameter by 1.27 cm long). Each dumbbell
supported a sample of strained (400%) or unstrained (0%) test or control
tubing. 2-0 Ticron suture was used to sustain the strain of these samples.
Five individual samples were tied together to form a strand. Each strand
was identified with an attached colored glass bead. There was a total of
130 samples, with 10 samples for each condition explanted at 12 weeks.
Tubing samples were formed by co-extruding either PELLETHANE 2363-55D
(P55D) tubing or PELLETHANE 2363-55DE (P55DE) over PELLETHANE 2363-80A
(P80A). The test tubings were then compared to the ESC resistance of
positive and negative control samples, respectively, P80A tubing and P55D
tubing. Control tubing conditions and test tubing conditions are given
below.
CONTROL TUBING CONDITIONS
A PELLETHANE 2363-80A, PN153097-050, Lot #448907: 0% elongation, annealed
PELLETHANE 2363-80A, PN153097-050, Lot #448907: 400% elongation, annealed
B PELLETHANE 2363-55D, PN153097-064, Mier 39513, 0% elongation PELLETHANE
2363-55D, PN153097-064, Mier 39513, 400% elongation
TEST TUBING CONDITIONS
C P80A/P55DE, wall thickness 0.0045 inches (0.011 cm)/0.002 inches (0.005
cm). 0% elongation. P80A/P55DE, wall thickness 0.0045 inches (0.011
cm)/0.002 inches (0.005 cm). 400% elongation.
D P80A/P55D, wall thickness 0.0045 inches (0.011 cm)/0.002 inches (0.005
cm). 0% elongation. P80A/P55D, wall thickness 0.0045 inches (0.011
cm)/0.002 inches (0.005 cm). 400% elongation.
E P80A/P55D, wall thickness 0.007 inches (0.018 cm)/ 0.001 inches (0.003
cm). 0% elongation. P80A/P55D, wall thickness 0.007 inches (0.018 cm)/
0.001 inches (0.003 cm). 400% elongation.
SAMPLE ANALYSIS
The test material strands were implanted subcutaneously in rabbits and
removed at 12 weeks. The samples were examined at 30.times. to 70.times.
magnification for ESC and defects. The samples were then rated for
environmental stress cracking with results reported as a fraction, X/Y.
The definitions of X and Y are:
X=Depth of cracks
0=No change in the surface
1=A change in the surface but no cracks at 70X
2=Very shallow cracks at 70X
3=Cracks up to half way through the tubing wall
4=Cracks greater than 50% of the tubing wall but not to 100%
5=Cracks 100% through the tubing wall
Y=Surface area affected
0=No change in the surface
1=.ltoreq.20%
2=>20%, .ltoreq.40%
3=>40%, .ltoreq.60%
4=>60%, .ltoreq.80%
5=>80% of surface
The results of the study are tabulated in Table 2.
TABLE 2
__________________________________________________________________________
ESC Resistance of Co-Extruded Tubing P80A/P55D and P80A/P55IDE at 12
weeks
Rabbit #
% Strain
Condition A
Condition B
Condition C
Condition D
Condition E
__________________________________________________________________________
311 0% 1/1 0/0 0/0 0/0 0/0
0% 1/3 0/0 0/0 0/0 0/0
400% 1/3 0/0 0/0 0/0 0/0
400% 1/3 0/0 0/0 0/0 0/0
318 0% 1/2 0/0 0/0 0/0 0/0
0% 1/2 0/0 0/0 0/0 0/0
400% 2/1 0/0 0/0 0/0 0/0
400% 1/2 0/0 0/0 0/0 0/0
320 0% 0/0 0/0 0/0 0/0 0/0
0% 1/2 0/0 0/0 0/0 0/0
400% 2/1 0/0 0/0 0/0 0/0
400% 2/1 0/0 0/0 0/0 0/0
321 0% 0/0 0/0 0/0 0/0 0/0
0% 0/0 0/0 0/0 0/0 0/0
400% 2/1 0/0 0/0 0/0 0/0
400% 0/0 0/0 0/0 0/0 0/0
325 0% 0/0 0/0 0/0 0/0 0/0
0% 0/0 0/0 0/0 0/0 0/0
400% 1/2 0/0 0/0 0/0 0/0
400% 0/0 0/0 0/0 0/0 0/0
__________________________________________________________________________
Conditions:
A = P80A Controls, stress relieved
B = P55D Controls
C = P80A/P55DE
D = P80A/P55D
E = P80A/P55D
No ESC was observed on any of the co-extruded tubing samples. No ESC was
found on the PELLETHANE 55D control (negative) samples, whereas four
PELLETHANE 80A control (positive) samples had areas of shallow ESC.
EXAMPLE 2
PELLETHANE 2363-80A tubing was coated with a solution of Enka polyurethane
PUR 981, Medtronic biostable polyurethane, and alternatively, PELLETHANE
2363-55D. A 12% stock solution of the coating polymer in DMAC was cut to a
2% solution and used to dip coat cut segments of PELLETHANE 80A tubing. A
2% solution of PELLETHANE 80A containing Blue Dextran in DMAC and a 2%
solution of MDX silicone in hexane were also used to dip coat cut segments
of PELLETHANE 80A tubing. The P80A tubing segments were cleaned in
isopropyl alcohol and then dipped and withdrawn smoothly from a cylinder
containing the overcoat polymer. The dipped tubing was allowed to drip
several seconds and then hung in a 40.degree. C. forced air oven with the
circulation off. After 10 to 20 minutes the air and heat were turned on
for at least one hour between each coat. A total of 4 coats was applied.
Finally, the coated tubes were dried overnight at 40.degree. C. in the
oven with heat and air circulation on. The MDX tubing samples were dried
for an additional 2 days.
PELLETHANE 80A tubing segments were also surface-grafted with an acrylamide
solution. Clean P80A tubing segments were placed into a 40% acrylamide in
DI water solution containing ceric ion for 25 minutes. The ceric ion
causes the graft copolymerization of acrylamide on the surface of the
tubing. Following surface-grafting the samples were rinsed thoroughly in
DI water.
Segments of PELLETHANE 80A/55DE coextruded tubing and PELLETHANE 80A tubing
were also tested in this study for ESC resistance. The tubing specimens in
this study were tested and analyzed for ESC according to the procedures
described in Example 1, the results of which are set forth in Table 3
shown below.
TABLE 3
__________________________________________________________________________
Biostability Study of Surface Treatments
on Pellethane 2363-80A Tubing Strained 400%
Rabbit #
Conditions A
B C D E F G H
__________________________________________________________________________
104 0/0 0/0 0/0
1/2 0/0
0/0 0/0
0/0
0/0 0/0 0/0
2/3 0/0
0/0 0/0
0/0
105 5/1 5/3 5/4
5/4 5/1
0/0 0/0
2/2
0/0 0/0 0/0
4/1 5/1
0/0 0/0
5/1
107 5/1 5/2 5/2
5/3 0/0
0/0 0/0
0/0
1/1 2/2 5/1
5/4 5/1
0/0 0/0
5/2
108 5/1 5/1 4/2
5/3 0/0
0/0 0/0
1/2
0/0 0/0 0/0
1/2 5/1
0/0 0/0
1/3
109 1/2 5/1 5/1
5/1 0/0
0/0 0/0
5/3
0/0 4/1 5/4
5/4 5/1
0/0 0/0
4/1
110 0/0 5/2 5/1
5/3 5/1
0/0 0/0
0/0
0/0 0/0 0/0
0/0 5/1
0/0 0/0
1/5
__________________________________________________________________________
Conditions:
A. Enka
B. Biostable
C. MDX Silicone
D. Acrylamide grafted
E. Blue dextran/P80A
F. P55D
G. P55DE coextruded P80A
H. Pellethane 236380A (control)
No ESC was observed on the P55D dip coated and P55DE coextruded samples.
All other tubing specimens had varying amounts of ESC.
This completes the description of the preferred and alternate embodiments
of the invention. Those skilled in the art may recognize other equivalents
to the specific embodiment described herein which equivalents are intended
to be encompassed by the claims attached hereto.
While this invention may be embodied in many different forms, described in
detail herein specific preferred embodiments of the invention. The present
disclosure is an exemplification of the principles of the invention and is
not intended to limit the invention to the particular embodiments
illustrated.
* * * * *
|
|
 |
|
 |
Description |
|
