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BACKGROUND
This invention relates to an antithrombogenic-containing polymeric material
and process for making the same. More particularly, the invention relates
to a method for preparing antithrombogenic polymeric articles which employ
covalently bonded hydrophobic groups bonded to the polymeric surface to
provide increased antithrombgenic activity.
Extensive investigations have been undertaken over many years to find
materials that will be biologically and chemically stable towards body
fluids. This area of research has become increasingly important with the
development of various objects and articles which can be in contact with
blood, such as artificial organs, vascular grafts, probes, cannulas,
catheters, hyperalimentation catheters and other long indwelling vascular
catheters and the like.
Artificial materials are being increasingly used as blood contact devices
and may be subject to potential generation of thrombus. When blood
contacts foreign materials a complex series of events occur. These involve
protein deposition, cellular adhesion and aggregation, and activation of
blood coagulation schemes. Considerable research effort has been focused
on this blood-material-interaction in the last twenty years with such
devices. The overall objective of these investigations has been to
minimize the potential for thrombus formation, such as the device when
introduced into the body upon contact with blood.
Various methods have been devised for producing such a material, most of
which involve chemically bonding a quaternary ammonium salt to the polymer
and then heparinizing the same. Usually, this is done by incorporating an
amine in the polymer, quaternizing the amine, and then heparinizing or
bonding an antibiotic to the quaternized material.
In one method taught by R. I. Leininger and G. A. Grode, U.S. Pat. No.
3,457,098, a quaternary amine is incorporated into an epoxy resin.
Subsequent exposure to sodium heparinate dissolved in water then results
in ionically bound heparin. The polymer systems are essentially epoxy
resins which are rigid polymers which are not suitable for forming medical
devices such as catheters or other devices requiring extrusion. These
polymers also are not appropriate where flexibility in the device is
required.
R. I. Leininger and R. D. Falb disclose in U.S. Pat. No. 3,617,344 another
process for binding heparin. This system differs from the previous system
in that low molecular weight chloromethyl groups are absorbed to the
surface of a polymer substrate. Subsequent amination by a tertiary amine
and quaternization resulted in a positively charged surface for binding
with heparin. The concept, in general, embodies the use of low molecular
weight quaternized groups to ionically bind heparin.
U.S. Pat. No. 3,846,353 to H. M. Grotta involves use of long chain alkyl
quaternary amines on the surface of a polymer wherein the positively
charged surface is exposed to a solution of sodium heparinate. The amines
are dissolved in an organic solvent consisting of toluene, petroleum ether
and mixtures thereof. One primary deficiency of the Grotta method is the
use of toluene as a coating solvent. Toluene, when used with latex
materials, results in a swelling of the products and destruction of
essential elastic properties, rendering itself practically useless. In
particular, this effect is seen with balloons present on balloon catheters
wherein the balloon component becomes extremely fragile and is basically
destroyed. Residues of toluene that may remain on the devices from
processing which are targeted for internal use are thus harmful to the
ultimate user. A second deficiency of ionically bonded systems is the
short lifetime of the ionically bonded heparin due to desorption.
S. Yen and A. Rembaum prepared a neutral polyurethane elastomer which is
subsequently quaternized and ionically bonded to heparin, U.S. Pat. No.
3,853,804. The main disadvantage of this system is that it is a chemical
complex and toxic solvents are used to achieve solubility when coating.
The coating technique, however, is difficult to perform due to the solvent
(DMF) requirement. The patent of N. Harumiya et al., U.S. Pat. No.
3,844,989, describes a polymer composition of water-insoluble cationic
copolymers having hydrophilic components, quaternary amine groups, and
hydrophobic moieties. Heparin is bonded ionically to the quaternary
ammonium groups via absorption after the polymer components are contacted
with a heparin solution. This method involves use of complex synthesis
procedures and is not readily applicable to coating other polymeric or
non-polymeric materials.
U.S. Pat. No. 4,521,564 to Solomon et al. discloses antithrombogenic
polyurethane polymers having the antithrombogenic material covalently
bound to the polyurethane. The polyurethane polymer material is treated
with a solution of a polymeric amine selected from the group consisting of
a polyvinyl amine, a polyalkylenimine having 2 to 4 carbon atoms per amine
unit and mixtures thereof so that the polymeric amine becomes covalently
bonded to the polyurethane substrate. An antithrombogenic agent is then
covalently bonded to the polymeric amine.
It would be desirable to provide a material which has excellent biological
and chemical stability towards body fluids, namely blood, and which
retains its antithrombogenic agent and antibiotic effect for a long term
while being slowly leachable when in contact with blood. It would also be
desirable to provide materials which have enhanced antithrombogenic
activity.
The present invention accomplishes all of these needs and improves on the
prior art compositions and methods of enhancing the availability of the
antithrombogenic agent to blood, thereby increasing the agent's activity.
Consequently, enhanced hemocompatibility of the products of this invention
is also achieved. More particularly, the present invention concerns
articles having antithrombogenic properties comprising:
(a) a polymeric solid support structure
(b) a polymeric material rich in amine content which serves as a substrate
for an antithrombogenic agent, said polymeric material being selected from
the group consisting of primary amines having a carbon chain length of
from 2 to 10,000. a polyalkylenimine having 2 to 4 carbon atoms per amine
unit and mixtures thereof bonded to said polymeric support structure; and
(c) an antithrombogenic agent covalently bonded to said polymeric material
rich in amine content; wherein the activity of the antithrombogenic agent
is enhanced by the hydrophobic material or functional groups covalently
bonded to the substrate surface.
Those polymeric materials rich in amine content which serve as a substrate,
e.g., bonding site, for the antithrombogenic agent, are preferably amine
rich polyurethane urea polymers (referred to herein as APU polymers).
These polymers are prepared as solutions which are then used to coat the
polymeric support structure. For example, if the support structure is a
catheter, tubing or other device, it can be dipped, brushed, sprayed or
otherwise coated with the amine rich material. The coating bonds to the
support structure surface, providing a site on which antithrombogenic
materials can subsequently be attached covalently. However, unlike the
prior art, the instant invention further prepares the amine rich substrate
surface prior to bonding the antithrombogenic agent to the amine
substrate. This further treatment comprises the introduction of
hydrophobic materials or groups onto the substrate surface.
Preferred polymeric material rich in amine content include polyether based
urethaneureas such an poly(ethylene oxide) urethane-urea, poly(propylene
oxide) urethaneurea, poly(tetramethylene oxide) urethaneurea; polyester
based urethaneureas such as poly(ethylene adipate) urethaneurea,
poly(propylene adipate) urethaneurea, poly(tetramethylene adipate)
urethaneurea, poly(hexamethylene adipate) urethane urea: other types of
polyurethane ureas such as polycaprolactone urethaneurea and polybutadiene
urethaneurea. Mixtures of these are also useful.
While the present invention has been described in terms of using the
preferred amine rich polyurethane urea polymers as the substrate on which
to attach the antithrombogenic agent, it should be recognized that other
substrate materials having active amine groups or groups such as
polyamides, polyimides, polyalkylenimines, and polyvinyl amines may be
used.
The enhanced antithrombogenic activity of the articles is believed to be
due to the greater hydrophobic character imparted to the substrate
surface. This effect is achieved by covalently bonding to the substrate
surface a moiety selected from the group consisting of a flourine
compound, a siloxane compound, a silazane compound, a silane compound, and
mixtures thereof. In the case of the fluorine-containing compounds, the
fluorine group is believed to covalently bond to the substrate surface. In
the case of the siloxane, silane and silazane compounds, the silicone
group is believed to covalently bond to the substrate surface.
Useful flourine-containing compounds include Freon.RTM. compounds such as
dichlorodifluoromethane, chlorotrifluoromethane, bromotrifluoromethane,
tetrafluoromethane, chlorodifluoromethane, fluoroform,
1,1,2-trichlorotrifluoroethane, 1,2-dichlorotetrafluoroethane,
hexafluoroethane, tetrafluoroethylene, as well as hexafluoropropylene,
boron trifluoride, silicon tetrafluoride, sulfur hexafluoride, sulfur
tetrafluoride, tungsten hexafluoride, and fluorine among others. The
preferred fluorinated compound is, however, hexafluoropropylene. Mixtures
of these compounds are contemplated.
Those siloxane compounds useful have the formula:
##STR1##
wherein R.sub.1, R.sub.2 and R.sub.3 are aliphatic or substituted
aliphatic groups having an aliphatic carbon chain of 1-4 carbons; and n is
an integer from 1 to 100, preferably from 3 to 20. Thus, aliphatic chains
of up to 4 carbons having a benzene ring or other aromatic or aliphatic
group substitution thereon are contemplated.
Those silazanes useful include compounds corresponding to the formula:
##STR2##
wherein R.sub.1, R.sub.2, R.sub.3 and R.sub.4 can be alkyl C.sub.1-4 or
hydrogen.
Those silane compounds useful have the formula:
##STR3##
wherein, R.sub.1, R.sub.2, R.sub.3 and R.sub.4 are selected from the group
consisting of aliphatic groups, substituted aliphatic groups, aromatic
groups, substituted aromatic groups, halogens, alkoxyl groups, vinyl
groups and mixtures thereof.
The bonding of the fluorine, siloxane, silane and/or silazane moieties to
the polymeric substrate surface is accomplished via glow discharge
(ionized gas) treatment. This process is generally referred to in the art
as plasma treatment. Plasma treatment is accomplished using a glow
discharge ionization chamber, whereby samples are placed in the chamber
and the chamber pressure is reduced to a minimal level, e.g., 0.1 torr or
less, via a vacuum pump. The fluorine, siloxane, silane and/or silazane
compounds are introduced in gaseous form into the plasma chamber to a
desired level, e.g., about 0.3 torr, and purged to a level of about 0.1
torr to minimize potential contamination from other gases such as air.
Purging is then repeated, and the final desired pressure of the gas is
reached. For example, a pressure of about 0.1 to about 5 torrs is desired,
and most preferably about 0.3 torrs. Radio frequency power is then
generated and applied to the gas in the chamber for a fixed period of
time. For example, about 10 to about 100 watts might be applied for a
period of about 10 to about 20 minutes. The ionization reaction is allowed
to proceed during this interval, at which time the power and vacuum are
terminated and air or nitrogen gas is introduced to open the chamber.
It is necessary to maintain a balance of four factors during the plasma
treatment of the substrate surface: power (wattage); exposure time
(reaction time); gas flow rate; and chamber pressure. If too much wattage
is applied for too long a period of time, the polymeric amine compound
which serves as the site for bonding the antithrombogenic agent, could
lose its functionality through cleavage or substitution by the gaseous
moieties in the ionization chamber. Too little wattage and/or exposure
produce insufficient bonding of the hydrophobic moieties to the substrate
surface. Thus, the wattage (power applied), exposure time of the substrate
surface to the gaseous chamber, flow rate of the gas, as well as the
chamber pressure, must be controlled within specified ranges. Variation of
one of these factors may cause adjustment of the other factors in order to
produce the desired result. The wattage applied should be from about 1 to
700 watts, preferably less than about 200 watts and most preferably from
about 5 to about 50 watts. The flow rate of the gas in the chamber should
be about 1 to about 500 standard cubic centimeters per minute (cc/min),
preferably about 1 to about 100 cc/min, and most preferably about 1 to
about 50 cc/min. The chamber pressure, during the treatment of the
substrate surface, should be maintained in the range of about 0.1 to about
100 torrs (mm of mercury), preferably about 0.2 to about 10 torrs and most
preferably about 0.3 to about 5 torrs. Exposure time of the substrate
surface to the chamber atmosphere under the above ranges vary widely from
a few minutes or hours to about 24 hours. Preferably, at 50 watts, 0.3
torrs and 5 cc/min, a time of about 10 minutes to 1 hour is sufficient to
impart excellent hydrophobic character to the substrate surface.
The plasma treatment covalently bonds radicals produced from the gas to the
substrate surface. A graphic illustration is given in FIG. 1 using
hexafluoropropylene as an example. As can be seen from the illustration,
hexafluoropropylene dissociates into a number of different products.
The term antithrombogenic agent or material as used herein refers to any
material which inhibits thrombus formation on its surface, such as by
reducing platelet aggregation, dissolving fibrin, enhancing passivating
protein deposition, or inhibiting one or more steps within the coagulation
cascade and which forms an ionic complex with quaternary ammonium salts.
Illustrative antithrombogenic materials may be selected from the group
consisting of heparin, prostaglandins, sulfated polysaccharides, and
mixtures thereof. Heparin is preferred. It should be understood that these
materials are used in their natural form or as salts thereof, such as the
sodium, or lithium salt. In addition to the foregoing antithrombogenic
agents, optional supplemental amounts of antithrombogenic agents may also
be used that are not reactive within the scope of the invention to further
enhance the effects of the materials. Exemplary materials include
urokinase, streptokinase, albumin and so forth.
The polymeric materials used in the invention as the solid support
structure may be selected from a wide range of polymeric materials. The
particular formulations do not constitute a critical aspect of this
invention other than to serve as a solid support structure for further
treatment according to the inventive process.
Illustrative plastic materials useful as the support structure may be
selected from the group consisting of polyethylene, polypropylene,
polyurethanes, polyurethane-silicone copolymers, polyurethane-ureas,
polycarbonates, silicone rubber, polyesters, nylons, natural rubber,
polyvinyl chloride, acrylics, polystyrene, copolymers of polycarbonate and
silicone rubber and mixtures thereof. The plastic materials are preferably
preformed into the desired shape or structure for the particular
application prior to treatment according to the invention.
The sequence of steps used to prepare the articles of this invention are
essential to obtaining the desired antithrombogenic activity. The support
structure should first be coated with the amine substrate. The coated
support structure is then subjected to plasma treatment. Finally, the
antithrombogenic agent is bonded to the amine substrate and the article is
complete. If plasma treatment is performed as after the antithrombogenic
agent is bonded to the amine substrate, it is likely that the ionization
process may denature, inactivate or otherwise modify the antithrombogenic
agent. Similarly, plasma treatment as a first step to coating with the
amine substrate, would tend to increase adhesion of the coating to the
support structure rather than increase the activity of the subsequently
bonded antithrombogenic agent. Thus, it is essential to the inventive
process and articles produced via this process that the steps be carried
out in the sequence recited.
A preferred embodiment of the instant invention uses hexafluoropropylene as
the gas for plasma treatment and uses a polyurethane solid support
structure having an amine rich polyurethane urea coating bonded to
heparin. FIG. 2 is a graphic illustration of the process of producing the
articles of the invention, as well as depicting the prior art route of
U.S. Pat. No. 4,521,564. The polymeric support structure (PSS) is shown as
being coated with an amine rich polyurethane compound (APU). The prior art
then bonded the antithrombogenic agent (heparin) to the APU. Heparin is
shown as being closely held to the surface of the final product. The
inventive process, however, is distinct in that prior to bonding of the
heparin to the APU, the coated support structure is plasma treated to
introduce hydrophobic character onto the substrate surface. FIG. 2 shows
one of the probable chemical structures of the substrate surface
subsequent to plasma treatment (PT-APU). The final product of the
inventive process is intended to depict the physical extension of the
heparin away from the surface of the substrate and the support structure
due to repulsion by the hydrophobic character of the substrate surface,
whereby the heparin is more available for contacting blood.
In the reaction equation scheme depicted, the polymeric solid support
structure is contacted with an amine rich polyurethane urea substrate,
which substrate provides a means for coupling with the antithrombogenic
agent. The next step is plasma treatment with the desired gas
(hexafluoropropylene) yielding hydrophobic groups on the surface of the
substrate which "repel" the antithrombogenic group (heparin) next to be
added. In the final step, aldehyde activated heparin is reacted with the
substrate to form a structure wherein heparin is convalently coupled to
the substrate. The resulting product demonstrates improved
antithrombogenic efficacy as well as permanency and nonleachability.
Modification of the surface of the polymeric substrate using plasma
treatment renders the substrate surface more hydrophobic. These
hydrophobic groups minimize the interaction of the hydrophilic
antithrombogenic group (e.g., heparin molecules) causing the latter to
stay extended outwardly from the substrate surface, thereby making them
more available for contacting blood and consequently more active in
preventing thrombus formation.
As previously mentioned, one particularly preferred plastic solid support
material is polyurethane polymers, which may contain conventional
polyisocyanates, low molecular weight glycols and high molecular weight
glycols. The polyisocyanates useful in the invention in introducing the
urethane linkage into the polymer chain may be selected from a wide range
of aliphatic, cycloalipathic and aromatic polyisocyanates. Useable
diisocyanates may contain noninterferring groups, e.g., aliphatic
hydrocarbon radicals such as lower alkyl or other groups, having
substantially nonreactive hydrogens as determined by the Zerewitinoff
test, J. Am. Chem. Soc. 49,3181 (1927). The diisocyanate often has at
least 6 carbon atoms and usually does not have more than about 40 carbon
atoms. Diisocyanates of about 8 to 20 atoms in the hydrocarbon group are
preferred. Suitable diisocyanates include 2,4-toluene diisocyanate;
2,6-toluene diisocyanate; 1,4-cyclohexane diisocyanate;
dicyclohexylmethane 4,4'-diisocyanate; xylene diisocyanate;
1-isocyanate-3-isocyanatomethyl-3,5,5-trimethylcyclohexane; hexamethylene
diisocyanate; methylcyclohexyl diisocyanate;
2,4,4-trimethylhexyl-methylene diisocyanate, isocyanates such as
m-phenylene diisocyanate; mixtures of 2,4- and 2,6
hexamethylene-1,5-diisocyanate; hexahydrotolylene diisocyanate (and
isomers), naphtylene-1,5-diisocyanate; 1-methoxyphenyl 2,4-diisocyanate;
diphenylmethane 4,4'-diisocyanate; 4,4'biphenylene diisocyanate;
3,3'-dimethoxy-4, 4biphenyl diisocyanate; 3,3'dimethyl-4,4'-biphenyl
diisocyanate; and 3,3'dimethyl-diphenylmethane-4,4'diisocyanate and
mixtures thereof. The aliphatic and alicyclic diisocyanates employed in
the process of this invention and the products made therefrom generally
exhibit good resistance to the degradative effects of ultraviolet light.
The polyisocyanate compound used to form the prepolymers may contain a
portion of polyisocyanates having two or more isocyanate (NCO) groups per
molecule providing the urethane polymer compositions are not unduly
deleteriously affected. The preferred polyisocyanate is selected from the
group consisting of 4,4'-diphenylmethane diisocyanate, toluene
diisocyanate, isophorone diisocyanate and methylene bis (4-cyclohexyl)
diisocyanate.
The low molecular weight glycols and/or diamines may also be used to
prepare the polymer which materials may have from 2 to 10 carbon atoms.
Exemplary of these glycols are ethylene glycol, diethylene glycol,
triethylene glycols, 1,4-butanediol, neopentyl glycol, 1,6-hexanediol,
1,8-octanediol, 1,2- and 1,3-propylene glycol, 2,3-butylene glycol, cyclo-
hexane dimethanol (1,4-bis hydroxymethyl cyclohexane), dipropylene glycol,
dibutylene glycol and 2-ethyl-2-(hydroxymethyl)-1,3- propanediol.
Exemplary diamines include ethylenediamine, propanediamines,
butanediamine, pentanediamine, hexanediamine, heptanediamine,
octanediamine, O-xylenediamine, 1,4-diaminocyclohexane,
p-phenylenediamine, 1-methyl-2,4,diaminobenzene, bis(p-aminocylohexyl)
methane, among others.
The high molecular weight glycols useful in the present invention may be a
polyether diol or polyester diol and range in number average molecular
weight from about 400 to about 3,000 and preferably about 500 to about
2,000. Examples of suitable polyhydric alcohols are polypropylene glycols,
polyethylene glycols and polybutylene glycols. Polyesters of lactones, for
example, .epsilon.-caprolactone or hydroxy carboxylic acids, for example,
.omega.-hydroxycaproic acid, may also be used. Illustrative polyesters may
contain hydroxyl groups, for example, reaction products of polyhydric
alcohols reacted with divalent carboxylic acids. It is also possible to
use the corresponding polycarboxylic acid anhydrides or corresponding
polycarboxylic acid esters of lower alcohols or mixtures thereof, for
producing the polyesters. The polycarboxylic acids may be aliphatic,
cycloaliphatic, aromatic and/or heterocyclic and may optionally be
substituted, for example, by halogen atoms and/or unsaturated. Examples of
polycarboxylic acids of this kind include succinic acid, adipic acid,
suberic acid, azelaic acid, sebacic acid, phthalic acid, phthalic acid
anhydride, tetrachlorophthalic acid anhydride, endomethylene
tetrahydrophthalic acid anhydride, glutaric acid anhydride, maleic acid,
maleic acid anhydride, fumaric acid, dimeric and trimeric fatty acids such
as oleic acid, optionally in admixture with monomeric fatty acids,
terephthalic acid dimethyl ester and terephthalic acid dimethyl ester and
terephthalic acid bis-glycol ester.
The polyethers containing at least 2, generally 2 to 8, but preferably 2 to
3 hydroxyl groups used in accordance with the invention are also known per
se and are obtained, for example, by polymerizing epoxides, such as
ethylene oxide, propylene oxide, tetrahydrofuran, styrene oxide or
epichlorohydrin on their own, for example, in the presence of BF.sub.3, or
by adding these epoxides, optionally in admixture or in succession, to
starter components containing reactive hydrogen atoms, such as water,
alcohols, or amines, for example, ethylene glycol, 1,3- or 1,2-propylene
glycol, 4,4'-dihydroxy diphenyl propane, aniline, ammonia, ethanolamine or
ethylene diamine. The most preferred polyether diols are polybutylene
glycols.
While the preferred polyurethane and/or polyurethane urea compositions of
the invention are thermoplastic, it has been found possible to employ
small amounts of crosslinking agents to the compositions when they are
coated onto the support in order to render them thermosetting. Suitable
crosslinking agents are discussed above and include the listed
diisocyanate compounds.
It should be recognized that the products of this invention are useable in
a wide variety of devices designed for contacting body fluids. Exemplary
articles which can be in contact with body fluids such as blood, include
artificial organs, vascular grafts, probes, cannulas, catheters,
hemodialysis tubing, hyperalimentation catheters and other long indwelling
vascular catheters, and the like. A particularly preferred application, of
the products of the invention is in catheter type devices wherein the
inventive compositions are coated on either or both interior and exterior
surfaces of the catheter.
The invention will be further illustrated by the following non-limiting
examples. All parts and percentages given throughout the specification are
by weight unless otherwise indicated.
EXAMPLE 1
This example demonstrates the preparation of the amine compound. This
compound is used to coat the support structure of the instant invention
prior to plasma treatment. Trimethylolpropane (44.73 grams) and 337.59
grams of a low molecular weight polyether polyol (Terathane 650) were
added together in a mixing vessel (1 equivalent of each) and heated to
about 45.degree. C. The materials were then mixed throughly and 524.00
grams (4 equivalents) of hydrogenated diphenylmethylene diisocyanate were
added. Dibutyl tin dilaurate in the amount of 14 grams (0.015%) was added
to the mixing solution. After 5 minutes of mixing, the reactants were
transferred to a 90.degree. C. oven for 60 minutes. The prepolymer was
then purged with nitrogen and stored.
Fifteen grams of this prepolymer were added to 30 grams of toluene to make
a 33% wt/wt solution. A separate diamine solution was prepared by adding
4.1 grams of 1.6-hexanediamine to 20 grams of isopropanol and 10 grams of
toluene. The diamine solution was stirred vigorously with a magnetic stir
bar under nitrogen. The prepolymer solution was then added dropwise to the
diamine solution over a two hour period. The reaction was stirred for an
additional two hours. Glacial acetic acid (2.3 grams) was then added
dropwise to the reaction mixture. The resulting composition was an amine
rich polyurethaneurea polymer, which was then dried with nitrogen gas and
finally with a vacuum.
The amine rich polyurethane urea composition was then dissolved in methanol
to a 20% wt/wt solution for deposition on the polymeric support structure.
EXAMPLE 2
This example demonstrates a method of preparing an aldehyde activated
heparin which is to be covalently bonded to the amine substrate prepared
in Example 1. (A) shows radioactive labelled heparin. (B) shows
non-labelled heparin.
(A) PREPARATION OF ALDEHYDE ACTIVATED RADIOACTIVE LABELLED HEPARIN
Seventy-five (75) mls of water were added to a beaker which contained 150
mls of 1% .sup.3 H-Heparin solution. Then 1.5 grams of sodium acetate was
transferred to the beaker. The pH of this solution was adjusted to 4.5
with glacial acetic acid. Sodium periodate (NaIO.sub.4) in the amount of
0.075 grams of was added and the solution was reacted for 20 minutes in a
light protected reaction vessel with constant stirring. At the end of the
reaction, 2.26 grams of glycerin was added to neutralize any remaining
periodate. The solution was dried down overnight under nitrogen. Then the
solution was reconstituted to 2% and the pH of the solution was adjusted
to 6.6 by the dropwise addition of 10N NaOH. The aldehyde activated .sup.3
H-heparin solution was ready for bonding to the amine compound. It should
be noted that other types of radioactive labelled heparin other than
.sup.3 H are useful.
(B) Preparation of Aldehyde Activated Heparin
7.5 grams of heparin was dissolved in 1125 mls of distilled water. Three
(3.0) grams of sodium acetate was weighted and transferred to the heparin
solution. The pH of this solution was then adjusted to 4.5 with glacial
acetic acid. Sodium periodate (NaIO.sub.4) was added in the amount of
0.375 grams and the solution was reacted for 20 minutes in a light
protected reaction vessel with constant stirring. At the end of the
reaction, 11.30 grams of glycerin was added to neutralize any remaining
periodate. Then the solution was reconstituted to 2%. The pH of the
solution was adjusted to 6.6 by the dropwise addition of 10N NaOH. The
aldehyde activated heparin solution was ready for bonding to the amine
compound.
EXAMPLE 3
This example illustrates the preparation of an article having increased
antithrombogenic activity utilizing the concepts of the present invention.
The amine rich polyurethane urea (APU) substrate of Example 1 was
dissolved in methanol to a 20% wt/wt solution. A polyurethane support
structure was coated with the APU. After coating, the substrate was placed
in the nitrogen atmosphere at ambient temperature for 60 minutes. The
coated tubing was then treated with hexafluoropropylene plasma (0.3 torr
and 50 watts) for 15 minutes, using the plasma treatment unit manufactured
by Branson/IPC (Model P-2075).
The samples were then placed in a reaction vessel which contained 0.025 g
(2.5% weight heparin) sodium cyanoborohydride and 2% aldehyde activated
.sup.3 H-heparin, prepared via Example 2. The reaction was performed in a
pH 6.6 aqueous solution at 50.degree. C. Two hours later, the samples were
removed and placed in a 3M saline solution for one hour to remove any
loosely bonded or adsorbed heparin. Then these samples were re-reacted for
a second two hour period at the same conditions as described above.
Initial radiolabel assays showed that 87.8.+-.12.9 micrograms of heparin
was bonded per cm.sup.2 of surface area as compared to the control samples
(143.4.+-.3.3 micrograms per cm.sup.2) which were identically treated in
all respects except without plasma treatment. After a dynamic leach study
in 3M saline solution for 24 hours, the radiolabelled assay still showed
79.4.+-.6.3 micrograms of heparin bonded per cm.sup.2 of surface area. In
comparison, the controls showed 103.7.+-.13.1 micrograms of heparin bonded
per cm.sup.2 of surface area. This demonstrates the permanency of the
covalently bonded heparin of this invention.
EXAMPLE 4
This example demonstrates the increased antithrombogenic activity of the
present invention compared to control samples prepared identically in all
respects except without plasma treatment.
Two sets of polyurethane tubings were coated with the amine rich
polyurethaneurea compound having heparin bonded thereon as described in
Example 3. One set of samples was exposed to hexafluoropropylene plasma
treatment and the other set of samples used as the control did not receive
the plasma treatment.
Those samples to be plasma treated were then placed in a reaction vessel
which contained 0.25 g (2.5% of heparin weight) sodium cyanoborohydride
and 2% aldehyde activated heparin. The plasma reaction was conducted as
described in Example 3.
An in vivo study was performed in such a way that one plasma treated sample
was inserted into one external jugular vein of a dog, while the control
sample was inserted in the other jugular vein of the same animal. The
activity of bonded heparin was demonstrated by the loss of platelet
adhesion (platelet uptake slope) and low thrombus weight. The average
slope and thrombus weight of three dogs are listed as follows:
______________________________________
Plasma Treated
Samples Control Samples
______________________________________
Slope 0.0188 .+-. 0.0025
0.0413 + 0.0266
Thrombus weight
4.53 mg .+-. 1.89 mg
14.13 mg .+-. 3.09 mg
______________________________________
It is clear that the activity of the bonded heparin was enhanced through
plasma treatment as indicated by the lower slope value and the lower
thrombus weight. The photographs in FIGS. 3 and 4 clearly show the
enhanced antithrombogenic activity of the instant invention. FIG. 3 shows
a picture of the tubing treated with the control sample and FIG. 4 shows
the tubing treated with the inventive composition. Both pictures were
taken after leaving the tubes in the animal for 40 minutes.
EXAMPLE 5
This example demonstrates the use of a poly-ethyleneimine compound as the
amine substrate. Thermoplastic polyurethane tubing (support structure) was
placed in a borate buffer solution (pH 9) containing 0.5% glutaraldehyde
and 0.1% polyethyleneimine (PEI) at room temperature for 30 minutes to
allow deposition and bonding of the amine compound to the tubing. After
rinsing with water the tubing was incubated in an aqueous solution of
dextran sulfate (1 mg/ml, 0.15M Nacl, 50.degree. C., pH 3) for 5 minutes
and was then rinsed with water. Then the tubing was incubated in a 1% PEI
solution at pH 9 for 5 minutes and was carefully rinsed with water. After
drying the tubing in the nitrogen atmosphere at ambient temperature for 60
minutes, the tubing was treated with hexafluoropropylene plasma (0.3 torr
and 50 watts) for 15 minutes, using the plasma treatment unit manufactured
by Branson/IPC (Model P-2075).
The sample was then placed in a reaction vessel which contained 0.25 g
(2.5% of heparin weight) sodium cyanoborohydride and 2% aldehyde activated
heparin. The reaction was conducted as described in Example 3, producing a
product with excellent antithrobogenic properties.
The invention being thus described, it will be obvious that the same may be
varied in many ways. Such variations are not to be regarded as a departure
from the spirit or scope of the invention and all such modifications are
intended to be included within the scope of the claims.
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