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Tantalum-loaded polyurethane microspheres for particulate embolization: preparation and properties
Tantalum-loadedpolyurethanemicrospheres for particulate embolization: preparation and properties B. Chithambara Tbanoo, M.C. Sunny and A. Jayakrishnan Polymer
Chemistry
Satelmond
Division,
Palace
(Received
29
January
Polyurethane
Biomedical
Campus, 1990;
accepted
microspheres
polymerization
Technology
Trivandrum
695
28 August
powder
Microspheres
radiation lumen.
These
Keywords:
Polyurethanes physical
Microspheres,
in
found
recent
a large
and fabrication
thanes
form
the
of
membranes
and tapes
knowledge,
polyurethane
any attention
number
have been
late embolization. nature
with
radiopaque
polyure-
tubings,
foams,
properties
in general
properties
of Ta7, polyurethane
deals with the preparation
acid (MA)
Teflon@ catheters embolization
without
emboli,
suspension
Methacrylic reduced
acid (MA)
pressure
In a 100
ml beaker
centration
Fluka were used without
The solution
PTMG
of such micro-
succinate
(DOS)
Company,
USA. Clinical-grade
was
diisocyanate
purchased
from
Ta powder
obtained
was (TDI) from
Dioctyl sulpho-
Aldrich
Engineering,
0
1991
to Dr A. Jayakrishnan, MAE
31 7. University
Butterworth-Helnemann
Department
of Florida,
water
was
of required
con-
PTMG
of Materials FL 3261
Science
Et
(i: 10%).
medium.
The
and finally
was introduced 60 min at 60°C.
admixed
with
several
times
60°C
and
India)
Polyurethane of MA
distilled
sieved
using
into different
modification
water,
of two different
The
micro-
were filtered dried
standard
of microspheres (0.5
TDI.
In the
was mixed off,
in an air
test
sieves
fractions.
slipperinesswasachieved
microspheres
slowly
for 30 min at
the Ta powder
washed at
it in
for 1 min. 5 ml
continued
at the end of the reaction
oven
of
of the two
dispersing
the contents
microspheres,
with
A mixture
mixing
1 min before
solution of DABCO
it was
at half-
ratio was then added and dis-
and the stirring
before
Surface
1, USA.
rev min-’
formed
was from Ingenor,
Gainesville,
using a motor-driven
spheres
(Filterwel,
Chemical
stirred
After stirring
30 min at 50°C
hydrophilicityand Correspondence
was distilled
was taken and thermostated
was done exactly
the DOS solution.
with
was
in the dispersion
ingredients
emboliza-
of a 10% aqueous
purification.
water
and TDI in the desired
persed
microspheres
(DABCO)
further
USA) Distilled
45 ml of DOS solution
in distilled
moon paddle stirrer at 200
having mol wt 990
Inc., USA. Toluene
used.
METHODS
4O”C,
Chemicals
(Aldrich,
and
throughout.
case of Ta-loaded
and 1,4-diazabicyclo[2.2.2]octane
and
the catheter
polymerization
and elasto-
MATERIALS
from DO.
obstructing
40°C.
properties.
glycol) (PTMG)
on to them using y-
agents.
into the system
Poly(tetramethylene
Technology,
of average mol wt
for particu-
and the excellent
with Ta could be useful for particulate of their
and that
on the use of poly-
radiocontrast
and some
and
have not received
encapsulated
tion. This report
methacrylic
employed
‘. While
In view of the biocompatible
of polyurethanes
glycol) (PTMG)
France.
used, to the best of our
reported
Sciences
into its sodium salt imparted hydrophilicity
under
biocompatibility
fibres,
microspheres
for Medical
500 ,um were prepared by condensation
embolization,
excellent
so far. Research from our laboratory3-5
meric microspheres
spheres
encapsulation,
their
good
MA
as radiopaque
of biomedical
of
versatility’,
sheets,
of Horak et A6 have recently
meric
tantalum,
because
properties,
and formulation in
by grafting
them to pass through
may find application
years
and mechanical
enabling
polyurethane,
Institute
containing dioctyl sulphosuccinate (DOS) as the suspension (DABCO) as the catalyst for polymerization. Incorporation phase led to the formation of Ta-loaded microspheres with good
were surface-modified
microspheres
have
applications
in the polymerizing
to the microspheres
Tirunal
with poly(tetramethylene
from a Co”’ source. Conversion of the grafted
slipperiness
Chitra
in the range 150-l
(TN)
990 in an aqueous dispersion medium stabilizer and 1,4-diazabicyclo[2.2.2]octane of tantalum
Sree
1990)
having diameters
of toluene diisocyanate
radiopacity.
Wing,
0 12. India
to impart
high
bygrafting
MA.
g) wereequilibrated
concentrations
(5 and
in 5 ml
10%)
over-
12 July
525
Ltd. 0142-9612/91/050525-04
B/omater/als
199 1, Vol
Po~orerhane
microspheres: B.C. Thanoo et al.
night and subjected to various radiation doses (0.1 to 1 .O Mrad). After irradiation, beads were washed for 7 d with several changes of water to remove all ungrafted material and dried. The grafted beads were further treated with 5% NaOH to convert the carboxylic acid functions into its sodium salt. Scanning electron micrographs of the microspheres were taken using a Jeol instrument (JSM 35C) after vacuum coating with gold. X-ray images were recorded using a Mimer III skull X-ray unit. Haemolytic potential of the microspheres was examined by incubating 5 mg of beads swollen to equilibrium in PBS (0.15 M, pH 7.4) with 1 ml of heparinized calf blood for 1 h at 37°C. Haemoglobin released was assayed according to the method of Raphael*.
RESULTS AND DISCUSSION Polyurethane microspheres Attempts were first made to prepare microspheres by a solvent evaporation process. A commercially available biomedical-grade polyurethane such as Tecoflex@ 80A (Therm~ics Inc., USA) was employed because of its solubility in volatile organic solvents such as di~hloromethane (DCM). Evaporation of a DCM solution of the polymer from an aqueous dispersion medium containing poly(vinyl alcohol) or DOS as the stabilizer gave rise to microspheres which were partially agglomeratory and sticky. Aromatic polyurethanes could not be used since they were soluble only in high-boiling solvents. It was therefore considered worthwhile to conduct the urethane formation reaction in suspension, directly leading to the formation of microspheres in one step. Reaction of TDI with PTMG in an aqueous suspension medium at 40°C without catalyst resulted in an uncured heter~eneous white mass due to the almost complete consumption of TDI for urea formation leaving the PTMG unutilized. Reaction at elevated temperatures resulted in the formation of large rigid foamy particles devoid of any spherical shape. Introduction of a catalyst such as DABCO into the dispersion medium after the reactants were dispersed led to a surface hardening of droplets preventing further contact of TDI with water. Further reaction at elevated temperatures (50 and 60°C) was predominantly urethane formation inside the droplets leading to the formation of elastomeric beads with good transparency and spherical geometry. The amount of TDI required to obtain beads having good transparency, elasticity and sphericity was found to be nearly twice the stoichiometric equivalent of PTMG, as the reaction of TDI with water was unpredictable and depended on several factors. TDI below this amount resulted in microspheres with poor mechanical properties.
Particle size control The particle size distribution of microspheres formed at three different concentrations of DOS as the stabilizer is shown in Figure 1. In general, a higher concentration of the stabilizer resulted in a larger fraction of smaller beads. The ratio of the amount of dispersed phase to the dispersion medium also influenced the particle size distribution of the final product. Table 7 shows the distribution pattern at three different ratios of the dispersed phase to the dispersion medium. An increase in the ratio of the dispersed phase to the dispersion medium resulted in a larger proportion of
526
Biomaterials
199 1. Vol 12 Ju/y
SIZE
RANGE (PM)
Figure 1 Particle size distribution ofpolyurethane microspheres formed at three different concentrations of dioctyl solphosuccinate in the dispersion medium. A 0.2%. 8: 0.550, C: 1.0%. Dispersed phase consisted of 1.5 g of poty(tetramethylene glycol) and 0.75 g of toluene diisocyanate.
Table t Percentage weight fraction ofpolyurethane microspheres formed at different weight ratios of the dispersed phase to the dispersion medium’ Percentage weight fraction at wt ratio 0.044 1200- 1500 1000-l 200 850-1000 710-850 600-710 425-600 355-425 300-355 250-300 180-250 150-180 go- 150
8.4 18.2 34.6 5.4 8.2 9.6 7.9 5.6 2.4
wt ratio 0.088 1.8 11.5 8.6 34.6 16.3 17.4 1.9 3.3 2.6 1.6 0.5
wt ratio 0.176
3.4 4.4 36.7 19.6 22.0 2.3 4.2 3.7 2.5 1.1 0.3
*Dispersed phase is poly(tetramethylene glycol) and toluene diisocyanate at a weight ratioof 0.5. Dispersion medium is 50 ml aqueous solution having 1% dioctyl sulphosuccinate and 1% 1.4-diazablcyclo[2.2.2]octane.
bigger particles. Experiments were conducted in duplicate and triplicate to assess the reproducibility of the particle size distribution data. A 20-30% deviation in data was observed in some cases. Such variation could be attributed to the lack of control of the extent of reaction between diisocyanate and the polyol during themixing process which results in unpredictable viscosity changes in the polymerizing phase before dispersion was effected. Particle size distribution could also be altered to a significant extent by incorporating a low-viscosity inert solvent in the dispersed phase. Size distribution of microspheres prepared in the absence and in
Polyurethane mIcrospheres: B.C. Thanoo et al.
c
I I
I
200
--I LOO PARTICLE
600 SUE
800
501
O-2
0, L
0.6
08
IRRADIATION
1000
‘0 DOSE
(Mrod)
Figure 3 Effecr of radiarion dose on the grafr yield of merhactylic acid (MA) and rhe equilibrium water content (EWC(%)J of the grafred MA in rhe sodium salt form. With 5% MA (eJ and 10% MA (mJ.
( pm)
Figure 2 Effect of 20% bury1 acetate in the dispersedphase on the pamcle size disrnburion of polyurerhane microspheres: ( -J with 1.5 g of poly(rerramerhylene glycolJ (PTMGJ and 0.75 g of roloene diisocyanare (TDIJ, (- - - -J wlrh 1.5 g of PTMG, 0.75 g of TDI and 0.55 g of bury1 acetate Dispersion medium is 50 ml aqueous solurion having 1% diocryl sulphosuconare and 1% 1,4-diazabicyclo[Z.Z.Z]ocrane
_____~
-I
the presence of 20% butyl acetate in the dispersed phase is shown in Figure 2. This could be attributed to a viscosity and surface tension lowering effect.
Surface
modified
microspheres
While the polyurethane microspheres prepared were soft and elastomeric, they were not sufficiently hydrophilic for their smooth and unhindered transit through hydrophobic microcatheters. Therefore, attempts were made to surface modifythem by grafting MA. Whilethegraftyield was highly dependent on the concentration of MA employed in the grafting medium, the dependence on irradiation dose was not found to be that high (Figure 3). The conversion of the grafted MA into its sodium salt improved the hydrophilicity and slipperiness of the particles remarkably. The extent of swelling as determined by the equilibrium water content (EWC) of the grafted beads in their Na+ form is proportional to the graft yield at low radiation doses (Figure 3). However, at high doses the swelling was found to level off at 5% MA concentration whereas at 10% the swelling was found to actually decrease beyond a dose of 0.25 Mrad. This could be attributed to the fact that at higher doses, along with grafting, cross-linking of the polyurethane matrix also occurred which impeded the swelling of the particles.
I__-_
_ _._. ‘:, ril n
-7
r--
:
1
1
_._l
_:
.
200
LOO
PARTICLE
600
SIZE
800
1000
(pm)
Figure 4 Effect of Ta encapsularlon on rhe pamcle sue disrriburion ofpolyJ wirh 1.5g of PTMG and 0.75g of TDI, urethane microspheres: ((- _- -) with 1.5 g of PTMG, 0.75 g of TDI and 0.9 g of Ta. Dispersion medium is 50 ml aqueous solurion containing 1% DOS and 1% DABCO. PTMG. poly(rerramerhylene glycol): TDI, roluene diisocyanare; DOS, diocryl sulphosoccinare; DABCO, 1,4-diazabicyclo[Z.Z.ZJocrane.
B/omarenals
199 1. Vol 12 July
527
Polyurethane microspheres: B.C. Thanoo et al.
Table 2 Blood haemolysis potential of polyurethane microspheres using heparinized calf blood Sample
Haemoglobin released (mg%)*
Control Polyurethane Polyurethane Polyurethane Polyurethane ~lyurethane
12.7 8.4 13.8 13.5 14.5 12.9
30% Ta loaded 7% MA grafted, Na+ form 17% MA grafted, Nat form 35% MA grafted, Na+ form
*Average of three values. MA, methacrylic acid.
formation of thrombus by interaction with the vascular endothelium and fix the emboli in the vascular lumen”.
Blood haemolysis by the microspheres Haemolysis studies showed that microspheres virgin, Ta loaded and MA grafted were all non-haemolytic. Plasma haemoglobin released in the presence of the particles was more or less close to the control value indicating their nonhaemol~ic nature in vitro (Table 2).
CONCLUSIONS
Figure 5 SEM of 30% Ta-loaded polyurethane microspheres. (a) At lower magnification and (bj At higher magnification showing Ta particles on the surface.
Reaction of TDI with PTMG in an aqueous dispersion medium containing DOS as the stabilizer generates polyurethane microspheres having good transparency, elasticity and spherical geometry. A small amount of catalyst such as DABCO is essential to facilitate the formation of microspheres. Grafting of MA imparts hydrophilicity and slipperiness to the microspheres. Encapsulation of Ta powder in the microspheres renders them radiopaque. In vitro tests show that the microspheres are non-haemol~ic.
ACKNOWLEDGEMENTS The authors thank the Director, SCTIMST, for permission to publish this manuscript and MS Janette Chesters of the University of Liverpool, UK, for the electron micrographs.
REFERENCES 1 2
3
Figure 6
X-ray images of 30% Ta-loaded polyurethane microspheres.
Tantalum-loaded
microspheres
4
5 6
Because of its high atomic number, Ta is highly radiopaque when compared with barium or iodine-based compounds. Moreover, Ta is well tolerated by the living tissue’. The particle size distribution of microspheres prepared in the presence of 30% Ta is shown in Figure 4. The presence of Ta does not modify the particle size distribution. The SEM and X-ray images of Ta-loaded microspheres are shown in Figures 5 and 6 respectively. The SEM at higher magnification clearly shows the Ta particles on the surface of microspheres. These particles are expected to impart a surface roughness to the microspheres which would help the
528
Biomaterials
199 1, Vol 12 July
7 8 9 10
Lelah, M.D. and Cooper, S.L., &&urethanes in Medicine, CRC Press, Boca Raton, FL, USA, 1986 Ulrich, H. and Bank, H.W., Emerging biomedical applications of polyurethane elastomers, tn Po/yo~thaoes in Biomedical Engineering (Eds H. Planck. G. Egbers and I. Syre). Elsevier, Amsterdam, 1984, pp 165-T 79 Jayakrishnan, A., Thanoo. B.C., Rathinam, K. and Mohanty, M., Preparation and broevaluahon of radiopaque hydrogel microspheres based on PHEMAYiothalmic acid and PHEMA/ropanoic acrd as particulate emboli. J. Biomed. Mater. Res., 1990. 24, 993-l 004 Thanoo, B.C. and Jayakrishnan. A., Barium sulphate encapsulated poiy(2~hydroxyethyi methacrylate) microspheres as artificial emboh: preparation and properties, Biomaterials, 1990, 11, 477-48 1 Thanoo, B.C. and Jayakrishnan. A., Radiopaque hydrogel microspheres, J. Microencapsulation 1989, 6, 233-244 Horak, D., Metalova, M.. Svec, F., Drobnik, J., Kalal, J., Borovick, M., Adamyan, A.A., Voronkova, OS. and Gumargalieva, K.Z.. Hydrogels in endovascular embolization. Ill. Radiopaque spherical particles, their preparation and properties, Biomaterials 1987. 8, 142- 145 Kunstlinger. F.. Brunelle. F., Chaumont. P. and Doyen, D.. Vascular occlusrve agents: a review, Am. J. Radio/. 198 t , 136, 15 l-1 56 Raphael, S.S. Lynch’s Medical Laboratory Technology, 4th edn, W.B. Saunders, Philadelphia, USA, 1983, p 265 McFadden, J.T., Tissue reactions to standard neurosurgical metallic implants, J. Neurosurg. 1972, 26, 598-603 Benoit, J.P. and Puisieux. F., Microcapsules and microspheres for embolization and chemoembolization, in Polymeric Nanopartices and Microspheres (Eds P. Guiot and P. Courreur), CRC Press, Boca Raton, FL. USA, 1986, p 150
Chemistry
Satelmond
Division,
Palace
(Received
29
January
Polyurethane
Biomedical
Campus, 1990;
accepted
microspheres
polymerization
Technology
Trivandrum
695
28 August
powder
Microspheres
radiation lumen.
These
Keywords:
Polyurethanes physical
Microspheres,
in
found
recent
a large
and fabrication
thanes
form
the
of
membranes
and tapes
knowledge,
polyurethane
any attention
number
have been
late embolization. nature
with
radiopaque
polyure-
tubings,
foams,
properties
in general
properties
of Ta7, polyurethane
deals with the preparation
acid (MA)
Teflon@ catheters embolization
without
emboli,
suspension
Methacrylic reduced
acid (MA)
pressure
In a 100
ml beaker
centration
Fluka were used without
The solution
PTMG
of such micro-
succinate
(DOS)
Company,
USA. Clinical-grade
was
diisocyanate
purchased
from
Ta powder
obtained
was (TDI) from
Dioctyl sulpho-
Aldrich
Engineering,
0
1991
to Dr A. Jayakrishnan, MAE
31 7. University
Butterworth-Helnemann
Department
of Florida,
water
was
of required
con-
PTMG
of Materials FL 3261
Science
Et
(i: 10%).
medium.
The
and finally
was introduced 60 min at 60°C.
admixed
with
several
times
60°C
and
India)
Polyurethane of MA
distilled
sieved
using
into different
modification
water,
of two different
The
micro-
were filtered dried
standard
of microspheres (0.5
TDI.
In the
was mixed off,
in an air
test
sieves
fractions.
slipperinesswasachieved
microspheres
slowly
for 30 min at
the Ta powder
washed at
it in
for 1 min. 5 ml
continued
at the end of the reaction
oven
of
of the two
dispersing
the contents
microspheres,
with
A mixture
mixing
1 min before
solution of DABCO
it was
at half-
ratio was then added and dis-
and the stirring
before
Surface
1, USA.
rev min-’
formed
was from Ingenor,
Gainesville,
using a motor-driven
spheres
(Filterwel,
Chemical
stirred
After stirring
30 min at 50°C
hydrophilicityand Correspondence
was distilled
was taken and thermostated
was done exactly
the DOS solution.
with
was
in the dispersion
ingredients
emboliza-
of a 10% aqueous
purification.
water
and TDI in the desired
persed
microspheres
(DABCO)
further
USA) Distilled
45 ml of DOS solution
in distilled
moon paddle stirrer at 200
having mol wt 990
Inc., USA. Toluene
used.
METHODS
4O”C,
Chemicals
(Aldrich,
and
throughout.
case of Ta-loaded
and 1,4-diazabicyclo[2.2.2]octane
and
the catheter
polymerization
and elasto-
MATERIALS
from DO.
obstructing
40°C.
properties.
glycol) (PTMG)
on to them using y-
agents.
into the system
Poly(tetramethylene
Technology,
of average mol wt
for particu-
and the excellent
with Ta could be useful for particulate of their
and that
on the use of poly-
radiocontrast
and some
and
have not received
encapsulated
tion. This report
methacrylic
employed
‘. While
In view of the biocompatible
of polyurethanes
glycol) (PTMG)
France.
used, to the best of our
reported
Sciences
into its sodium salt imparted hydrophilicity
under
biocompatibility
fibres,
microspheres
for Medical
500 ,um were prepared by condensation
embolization,
excellent
so far. Research from our laboratory3-5
meric microspheres
spheres
encapsulation,
their
good
MA
as radiopaque
of biomedical
of
versatility’,
sheets,
of Horak et A6 have recently
meric
tantalum,
because
properties,
and formulation in
by grafting
them to pass through
may find application
years
and mechanical
enabling
polyurethane,
Institute
containing dioctyl sulphosuccinate (DOS) as the suspension (DABCO) as the catalyst for polymerization. Incorporation phase led to the formation of Ta-loaded microspheres with good
were surface-modified
microspheres
have
applications
in the polymerizing
to the microspheres
Tirunal
with poly(tetramethylene
from a Co”’ source. Conversion of the grafted
slipperiness
Chitra
in the range 150-l
(TN)
990 in an aqueous dispersion medium stabilizer and 1,4-diazabicyclo[2.2.2]octane of tantalum
Sree
1990)
having diameters
of toluene diisocyanate
radiopacity.
Wing,
0 12. India
to impart
high
bygrafting
MA.
g) wereequilibrated
concentrations
(5 and
in 5 ml
10%)
over-
12 July
525
Ltd. 0142-9612/91/050525-04
B/omater/als
199 1, Vol
Po~orerhane
microspheres: B.C. Thanoo et al.
night and subjected to various radiation doses (0.1 to 1 .O Mrad). After irradiation, beads were washed for 7 d with several changes of water to remove all ungrafted material and dried. The grafted beads were further treated with 5% NaOH to convert the carboxylic acid functions into its sodium salt. Scanning electron micrographs of the microspheres were taken using a Jeol instrument (JSM 35C) after vacuum coating with gold. X-ray images were recorded using a Mimer III skull X-ray unit. Haemolytic potential of the microspheres was examined by incubating 5 mg of beads swollen to equilibrium in PBS (0.15 M, pH 7.4) with 1 ml of heparinized calf blood for 1 h at 37°C. Haemoglobin released was assayed according to the method of Raphael*.
RESULTS AND DISCUSSION Polyurethane microspheres Attempts were first made to prepare microspheres by a solvent evaporation process. A commercially available biomedical-grade polyurethane such as Tecoflex@ 80A (Therm~ics Inc., USA) was employed because of its solubility in volatile organic solvents such as di~hloromethane (DCM). Evaporation of a DCM solution of the polymer from an aqueous dispersion medium containing poly(vinyl alcohol) or DOS as the stabilizer gave rise to microspheres which were partially agglomeratory and sticky. Aromatic polyurethanes could not be used since they were soluble only in high-boiling solvents. It was therefore considered worthwhile to conduct the urethane formation reaction in suspension, directly leading to the formation of microspheres in one step. Reaction of TDI with PTMG in an aqueous suspension medium at 40°C without catalyst resulted in an uncured heter~eneous white mass due to the almost complete consumption of TDI for urea formation leaving the PTMG unutilized. Reaction at elevated temperatures resulted in the formation of large rigid foamy particles devoid of any spherical shape. Introduction of a catalyst such as DABCO into the dispersion medium after the reactants were dispersed led to a surface hardening of droplets preventing further contact of TDI with water. Further reaction at elevated temperatures (50 and 60°C) was predominantly urethane formation inside the droplets leading to the formation of elastomeric beads with good transparency and spherical geometry. The amount of TDI required to obtain beads having good transparency, elasticity and sphericity was found to be nearly twice the stoichiometric equivalent of PTMG, as the reaction of TDI with water was unpredictable and depended on several factors. TDI below this amount resulted in microspheres with poor mechanical properties.
Particle size control The particle size distribution of microspheres formed at three different concentrations of DOS as the stabilizer is shown in Figure 1. In general, a higher concentration of the stabilizer resulted in a larger fraction of smaller beads. The ratio of the amount of dispersed phase to the dispersion medium also influenced the particle size distribution of the final product. Table 7 shows the distribution pattern at three different ratios of the dispersed phase to the dispersion medium. An increase in the ratio of the dispersed phase to the dispersion medium resulted in a larger proportion of
526
Biomaterials
199 1. Vol 12 Ju/y
SIZE
RANGE (PM)
Figure 1 Particle size distribution ofpolyurethane microspheres formed at three different concentrations of dioctyl solphosuccinate in the dispersion medium. A 0.2%. 8: 0.550, C: 1.0%. Dispersed phase consisted of 1.5 g of poty(tetramethylene glycol) and 0.75 g of toluene diisocyanate.
Table t Percentage weight fraction ofpolyurethane microspheres formed at different weight ratios of the dispersed phase to the dispersion medium’ Percentage weight fraction at wt ratio 0.044 1200- 1500 1000-l 200 850-1000 710-850 600-710 425-600 355-425 300-355 250-300 180-250 150-180 go- 150
8.4 18.2 34.6 5.4 8.2 9.6 7.9 5.6 2.4
wt ratio 0.088 1.8 11.5 8.6 34.6 16.3 17.4 1.9 3.3 2.6 1.6 0.5
wt ratio 0.176
3.4 4.4 36.7 19.6 22.0 2.3 4.2 3.7 2.5 1.1 0.3
*Dispersed phase is poly(tetramethylene glycol) and toluene diisocyanate at a weight ratioof 0.5. Dispersion medium is 50 ml aqueous solution having 1% dioctyl sulphosuccinate and 1% 1.4-diazablcyclo[2.2.2]octane.
bigger particles. Experiments were conducted in duplicate and triplicate to assess the reproducibility of the particle size distribution data. A 20-30% deviation in data was observed in some cases. Such variation could be attributed to the lack of control of the extent of reaction between diisocyanate and the polyol during themixing process which results in unpredictable viscosity changes in the polymerizing phase before dispersion was effected. Particle size distribution could also be altered to a significant extent by incorporating a low-viscosity inert solvent in the dispersed phase. Size distribution of microspheres prepared in the absence and in
Polyurethane mIcrospheres: B.C. Thanoo et al.
c
I I
I
200
--I LOO PARTICLE
600 SUE
800
501
O-2
0, L
0.6
08
IRRADIATION
1000
‘0 DOSE
(Mrod)
Figure 3 Effecr of radiarion dose on the grafr yield of merhactylic acid (MA) and rhe equilibrium water content (EWC(%)J of the grafred MA in rhe sodium salt form. With 5% MA (eJ and 10% MA (mJ.
( pm)
Figure 2 Effect of 20% bury1 acetate in the dispersedphase on the pamcle size disrnburion of polyurerhane microspheres: ( -J with 1.5 g of poly(rerramerhylene glycolJ (PTMGJ and 0.75 g of roloene diisocyanare (TDIJ, (- - - -J wlrh 1.5 g of PTMG, 0.75 g of TDI and 0.55 g of bury1 acetate Dispersion medium is 50 ml aqueous solurion having 1% diocryl sulphosuconare and 1% 1,4-diazabicyclo[Z.Z.Z]ocrane
_____~
-I
the presence of 20% butyl acetate in the dispersed phase is shown in Figure 2. This could be attributed to a viscosity and surface tension lowering effect.
Surface
modified
microspheres
While the polyurethane microspheres prepared were soft and elastomeric, they were not sufficiently hydrophilic for their smooth and unhindered transit through hydrophobic microcatheters. Therefore, attempts were made to surface modifythem by grafting MA. Whilethegraftyield was highly dependent on the concentration of MA employed in the grafting medium, the dependence on irradiation dose was not found to be that high (Figure 3). The conversion of the grafted MA into its sodium salt improved the hydrophilicity and slipperiness of the particles remarkably. The extent of swelling as determined by the equilibrium water content (EWC) of the grafted beads in their Na+ form is proportional to the graft yield at low radiation doses (Figure 3). However, at high doses the swelling was found to level off at 5% MA concentration whereas at 10% the swelling was found to actually decrease beyond a dose of 0.25 Mrad. This could be attributed to the fact that at higher doses, along with grafting, cross-linking of the polyurethane matrix also occurred which impeded the swelling of the particles.
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-7
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:
1
1
_._l
_:
.
200
LOO
PARTICLE
600
SIZE
800
1000
(pm)
Figure 4 Effect of Ta encapsularlon on rhe pamcle sue disrriburion ofpolyJ wirh 1.5g of PTMG and 0.75g of TDI, urethane microspheres: ((- _- -) with 1.5 g of PTMG, 0.75 g of TDI and 0.9 g of Ta. Dispersion medium is 50 ml aqueous solurion containing 1% DOS and 1% DABCO. PTMG. poly(rerramerhylene glycol): TDI, roluene diisocyanare; DOS, diocryl sulphosoccinare; DABCO, 1,4-diazabicyclo[Z.Z.ZJocrane.
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Polyurethane microspheres: B.C. Thanoo et al.
Table 2 Blood haemolysis potential of polyurethane microspheres using heparinized calf blood Sample
Haemoglobin released (mg%)*
Control Polyurethane Polyurethane Polyurethane Polyurethane ~lyurethane
12.7 8.4 13.8 13.5 14.5 12.9
30% Ta loaded 7% MA grafted, Na+ form 17% MA grafted, Nat form 35% MA grafted, Na+ form
*Average of three values. MA, methacrylic acid.
formation of thrombus by interaction with the vascular endothelium and fix the emboli in the vascular lumen”.
Blood haemolysis by the microspheres Haemolysis studies showed that microspheres virgin, Ta loaded and MA grafted were all non-haemolytic. Plasma haemoglobin released in the presence of the particles was more or less close to the control value indicating their nonhaemol~ic nature in vitro (Table 2).
CONCLUSIONS
Figure 5 SEM of 30% Ta-loaded polyurethane microspheres. (a) At lower magnification and (bj At higher magnification showing Ta particles on the surface.
Reaction of TDI with PTMG in an aqueous dispersion medium containing DOS as the stabilizer generates polyurethane microspheres having good transparency, elasticity and spherical geometry. A small amount of catalyst such as DABCO is essential to facilitate the formation of microspheres. Grafting of MA imparts hydrophilicity and slipperiness to the microspheres. Encapsulation of Ta powder in the microspheres renders them radiopaque. In vitro tests show that the microspheres are non-haemol~ic.
ACKNOWLEDGEMENTS The authors thank the Director, SCTIMST, for permission to publish this manuscript and MS Janette Chesters of the University of Liverpool, UK, for the electron micrographs.
REFERENCES 1 2
3
Figure 6
X-ray images of 30% Ta-loaded polyurethane microspheres.
Tantalum-loaded
microspheres
4
5 6
Because of its high atomic number, Ta is highly radiopaque when compared with barium or iodine-based compounds. Moreover, Ta is well tolerated by the living tissue’. The particle size distribution of microspheres prepared in the presence of 30% Ta is shown in Figure 4. The presence of Ta does not modify the particle size distribution. The SEM and X-ray images of Ta-loaded microspheres are shown in Figures 5 and 6 respectively. The SEM at higher magnification clearly shows the Ta particles on the surface of microspheres. These particles are expected to impart a surface roughness to the microspheres which would help the
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