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Chitosan microspheres prepared by spray dying method
Relating to Invited Lecture 5-Material
Sl73
Science (P3.031-P3.089)
The importance of vesick size and drug entrapment control in the use of liposomcs in drug delivery
and targeting is well established ‘.
microfluidization
of solub-containing
leads to
the formation of smaller
originally
entrapped solute.
Previous wo&
dehydration-rchydmtion vesicles retaining
(“washed”
of DRV
or “unwashed”
mathematical
considwabk
liposomes)
amounts
of the
The size of, and soIu(e retention by, such vesicles was
found’ to depend on the number of microfluidization microfluidization
hss shown that
vesicks (DRV
WBS carrkd DRV).The
cycles and on whether or not
out in the presence of non-entrapped solute aim
of the present study was to establish
correlations which would allow the prediction of such characteristics es
size and polydispenity the microfluidization
index and solute retention values in vnicks of solute-containing
those behveen the above characteristics
DRV
liposomes.
and operational
generated through
Correlations studied were variabks
such as pressure
applied (P, 20-60 psi), number of cycles (N; I -I 0) and the presence or absence of nonentrapped material during the process ofmicmfluidization Preparations (Microfluidizer
of
“C-labelled
S-l IO; Micmfluidics,
sucrose-containing
(W). DRV
were
micmfluidizcd
USA) according to a compkte factorial
designof
thethreevariables at hvo levels, with interactions. Results show that all three operational variables exerted a significant effect on the vesicle characteristics studied. By carving out five unperformed experiments (with unwashed DRV liposomes) in the factorial design ofthe two variables (P. N) at three levels of P (20.40.66 psi) and N (I, end IO cycles) and using regression analysis (SPSS PC’ sofhvare) the following correlations were established:
5
% of initial 82.2094*5.34
entrapment ??SE = 0.3988
N’ + 0.01440
P’
_ 6.3338 N -I ,303s P +
(~0.9252)
size (nm) f SE = 0.07268 NP - I .0759P - 6.3874N + 204.6885i 16.86(r-0.8136) Polydispenity index ?? SE = 0.001713 P + 0.008872 N - 0.0003508 NP
+
0.159240+0.022 (1=0.8595)
(1) MC. Woodle & D. L&c, Biochim. Biop s.Acro,1113, 171299, (1992) (2) J.H. Cmwe C L.M. Crowe, in Li some P c&nolo Vol I 2 ed., CRC Press, Boa Raton, 229-252 &3). ISBN 0-883-67Oi-7 (3)M.Diim,J.Ha&er &!&hr, Ew~JPharmBiopharm 40(3) 147-156 (1994) (4) R.R.C. New (ed.) in Liposomes - a practical a pro&h, O;ford University Press, pp. 33-104, (1990). ISBN O-19-96307&3
Chitosan is a polycationic poiysaccharide. it has the advantages of being non-toxic, biodegradable, and positively charged. During recent years, it has found increasing kppliiation as a drug carrier. In the present study, chitosan microspheres with entrapped Hz-receptor antagonists (cimetidine and famotidine) have been prepared by a spray drying method. The inlet air spray drying conditions were set up as follows: Chitosan temperature, 150 “C; spray flow rate, 5-15 mllmin. microspheres so prepared have good sphericity, convoluted surfaces, narrow size distribution and are positively charged (20 mv). Particle size was 3-5 pm. An in vitro release study was carried out in a USP-2 dissolution apparatus. Cimetidine was rapidly released from the microspheres. There was a clear ‘burst effect” during the first stage of dissolution. and most of the drug was released in few minutes. This is most likely due to (1) the small size and porous morphology; (2) hydrophillic nature of the polymer and drug (cimetidine) which both have a high affinity with water. When famotidine was used (its solubilii in water is 10 times tower than that of cimetidiie). the release rate was reduced. Differential scanning calorimetry(DSC) was used to evaluate the cimetidine and chitosan materials, blank chitosan microspheres. a cimetidine/chitosan physical mixture and cimetidine-loaded microspheres. The endothermic peak of cimetidine. due to the melting of the drug at 417 K, which was present in the DSC scan for the physical mixture of chitosan and cimetidine, no longer appeared in that for the drug-loaded microspheres. This suggests that the drug has been molecularly dispersed as a solid solution inside the microspheres. The microspheres could be used mucoadhesive delivery such as nasal or gastric muco-delivery.
These
correlations
have been used successfully
for the prediction
of vesicle
characteristics as above under a set of given conditions of micmfluidization. I. Gregoriadis. G., (I 995) Trends m Biok~hno/ogy, 13: 527-537 2. Gregoriadis, G. et al, (I 990) Inr. J Phorm., 65: 235-242
One of the most significant side affects of oral dosage forms is their irritative effect cn stomach mumsa. This problem can be solved intmducing entefic coating. In thtt shrdy. entark microcapsules were prepared for this purpose acccrding to the solvent evaporation technique using a new polymer, CAT. Tenoxicam (TNX). an antinflammatory drug causing irrttation on stomach mucosa upon p.o. administratton in the form of a tabtet or a hard gelatin capsule, was selected as a model drug. There are not any published reports on the prepatatton of entertc mlaocapsules of TNX or any other drug using CAT. Particle size, drug loading capacity, disintegration and dissolution rates in both simulated gastric and intestinal media were determined. plsaolutton studii were performed according to the methods statad in the USP XXlt (paddele and basket methods). Entertc coat+d miaocapwles showed insignificant dlsintegratbn in simulated gaatrtc media. Dissotution rate of enteric m&ocapsules wae compared to that of commercially available hard geMn capsufes and conventbnai tablets of TNX. in simulated inteatinal meua at dIffereM pH values (6.0, 6.4, 6.6 and 7.2) 100 96 of TNX in en&c rndissolved in two hours wMreas TNX i n unntnenMy avatlable conventtonal gelattn capsules and tablets didnot ctissohrsd at all.
Sl73
Science (P3.031-P3.089)
The importance of vesick size and drug entrapment control in the use of liposomcs in drug delivery
and targeting is well established ‘.
microfluidization
of solub-containing
leads to
the formation of smaller
originally
entrapped solute.
Previous wo&
dehydration-rchydmtion vesicles retaining
(“washed”
of DRV
or “unwashed”
mathematical
considwabk
liposomes)
amounts
of the
The size of, and soIu(e retention by, such vesicles was
found’ to depend on the number of microfluidization microfluidization
hss shown that
vesicks (DRV
WBS carrkd DRV).The
cycles and on whether or not
out in the presence of non-entrapped solute aim
of the present study was to establish
correlations which would allow the prediction of such characteristics es
size and polydispenity the microfluidization
index and solute retention values in vnicks of solute-containing
those behveen the above characteristics
DRV
liposomes.
and operational
generated through
Correlations studied were variabks
such as pressure
applied (P, 20-60 psi), number of cycles (N; I -I 0) and the presence or absence of nonentrapped material during the process ofmicmfluidization Preparations (Microfluidizer
of
“C-labelled
S-l IO; Micmfluidics,
sucrose-containing
(W). DRV
were
micmfluidizcd
USA) according to a compkte factorial
designof
thethreevariables at hvo levels, with interactions. Results show that all three operational variables exerted a significant effect on the vesicle characteristics studied. By carving out five unperformed experiments (with unwashed DRV liposomes) in the factorial design ofthe two variables (P. N) at three levels of P (20.40.66 psi) and N (I, end IO cycles) and using regression analysis (SPSS PC’ sofhvare) the following correlations were established:
5
% of initial 82.2094*5.34
entrapment ??SE = 0.3988
N’ + 0.01440
P’
_ 6.3338 N -I ,303s P +
(~0.9252)
size (nm) f SE = 0.07268 NP - I .0759P - 6.3874N + 204.6885i 16.86(r-0.8136) Polydispenity index ?? SE = 0.001713 P + 0.008872 N - 0.0003508 NP
+
0.159240+0.022 (1=0.8595)
(1) MC. Woodle & D. L&c, Biochim. Biop s.Acro,1113, 171299, (1992) (2) J.H. Cmwe C L.M. Crowe, in Li some P c&nolo Vol I 2 ed., CRC Press, Boa Raton, 229-252 &3). ISBN 0-883-67Oi-7 (3)M.Diim,J.Ha&er &!&hr, Ew~JPharmBiopharm 40(3) 147-156 (1994) (4) R.R.C. New (ed.) in Liposomes - a practical a pro&h, O;ford University Press, pp. 33-104, (1990). ISBN O-19-96307&3
Chitosan is a polycationic poiysaccharide. it has the advantages of being non-toxic, biodegradable, and positively charged. During recent years, it has found increasing kppliiation as a drug carrier. In the present study, chitosan microspheres with entrapped Hz-receptor antagonists (cimetidine and famotidine) have been prepared by a spray drying method. The inlet air spray drying conditions were set up as follows: Chitosan temperature, 150 “C; spray flow rate, 5-15 mllmin. microspheres so prepared have good sphericity, convoluted surfaces, narrow size distribution and are positively charged (20 mv). Particle size was 3-5 pm. An in vitro release study was carried out in a USP-2 dissolution apparatus. Cimetidine was rapidly released from the microspheres. There was a clear ‘burst effect” during the first stage of dissolution. and most of the drug was released in few minutes. This is most likely due to (1) the small size and porous morphology; (2) hydrophillic nature of the polymer and drug (cimetidine) which both have a high affinity with water. When famotidine was used (its solubilii in water is 10 times tower than that of cimetidiie). the release rate was reduced. Differential scanning calorimetry(DSC) was used to evaluate the cimetidine and chitosan materials, blank chitosan microspheres. a cimetidine/chitosan physical mixture and cimetidine-loaded microspheres. The endothermic peak of cimetidine. due to the melting of the drug at 417 K, which was present in the DSC scan for the physical mixture of chitosan and cimetidine, no longer appeared in that for the drug-loaded microspheres. This suggests that the drug has been molecularly dispersed as a solid solution inside the microspheres. The microspheres could be used mucoadhesive delivery such as nasal or gastric muco-delivery.
These
correlations
have been used successfully
for the prediction
of vesicle
characteristics as above under a set of given conditions of micmfluidization. I. Gregoriadis. G., (I 995) Trends m Biok~hno/ogy, 13: 527-537 2. Gregoriadis, G. et al, (I 990) Inr. J Phorm., 65: 235-242
One of the most significant side affects of oral dosage forms is their irritative effect cn stomach mumsa. This problem can be solved intmducing entefic coating. In thtt shrdy. entark microcapsules were prepared for this purpose acccrding to the solvent evaporation technique using a new polymer, CAT. Tenoxicam (TNX). an antinflammatory drug causing irrttation on stomach mucosa upon p.o. administratton in the form of a tabtet or a hard gelatin capsule, was selected as a model drug. There are not any published reports on the prepatatton of entertc mlaocapsules of TNX or any other drug using CAT. Particle size, drug loading capacity, disintegration and dissolution rates in both simulated gastric and intestinal media were determined. plsaolutton studii were performed according to the methods statad in the USP XXlt (paddele and basket methods). Entertc coat+d miaocapwles showed insignificant dlsintegratbn in simulated gaatrtc media. Dissotution rate of enteric m&ocapsules wae compared to that of commercially available hard geMn capsufes and conventbnai tablets of TNX. in simulated inteatinal meua at dIffereM pH values (6.0, 6.4, 6.6 and 7.2) 100 96 of TNX in en&c rndissolved in two hours wMreas TNX i n unntnenMy avatlable conventtonal gelattn capsules and tablets didnot ctissohrsd at all.