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Plateformes biocompatibles et approches innovantes pour la vectorisation de nanoparticules en décorporation pulmonaire du plutonium / Biocompatible platforms and innovative approaches for the vectorization of nanoparticles in pulmonary decorporation of plutoniumLéost, Laurane 22 November 2018 (has links)
L'utilisation du plutonium (Pu(IV) pour des applications militaires et civiles peut engendrer des contaminations internes chez les personnes exposées. Plusieurs voies de contamination sont possibles : par ingestion, par inhalation ou par blessure. En cas d'inhalation, le plutonium se présente le plus souvent sous forme de particules d'oxyde de plutonium qui vont se localiser au sein des alvéoles pulmonaires. Par un mécanisme de phagocytose, les particules sont internalisées par les macrophages de l'épithélium pulmonaire. Actuellement, le seul agent de décorporation administré en cas de contamination au plutonium est le DTPA (l'acide diethylenetriaminepentaacetique). Il est administré en France sous forme de CaNa3-DTPA par injection intraveineuse et est efficace pour les contaminations par ingestion et par blessure. Les nanoparticules fonctionnalisées à base de polymères naturels sont un concept innovant de décorporation du Pu(IV) solubilisé dans les macrophages pulmonaires et ouvrent la voie au développement de nouvelles familles de décorporants. C'est dans ce contexte que deux stratégies ont été développées : des nanoparticules à base de N-trimethyl chitosan fonctionnalisées par le ligand DTPMP (l'acide diéthylènetriaminepentamethylene phosphonique) qui est l'analogue phosphonique du DTPA et des nanoparticules chélatantes à base de -cyclodextrines amphiphiles anioniques. Ce travail a consisté en la synthèse et la caractérisation des nano-objets puis de l'étude de leur complexation avec les actinides (Th/Pu) en utilisant la spectroscopie EXAFS. Et enfin, des tests préliminaires biologiques in vitro ont été réalisés. Les résultats obtenus, avec les nanoparticules à base de chitosan et de DTPMP montrent que les nanoparticules présentent des tailles et une stabilité compatible avec l’application visée. D’autre part, leur affinité pour les actinides (IV) (Th,Pu) est comparable à celle du chélatant de référence, le DTPA. Enfin, les tests, effectués sur deux lignées de macrophages montrent que les nanoparticules sont internalisées très rapidement et que la matrice polysaccharidique semble se dégrader, permettant le relargage du chélateur DTPMP au niveau des sites de rétention du Pu(IV). Cette thèse constitue un travail préliminaire au développement d'une nouvelle famille d’agents décorporants plus ciblés pour une contamination au plutonium par inhalation. / The use of plutonium (Pu(IV) for military and civil applications can lead to internal contamination. There are several possible routes of contamination: ingestion, inhalation or injury. In case of plutonium inhalation, the plutonium forms oxide particles that reach the pulmonary alveoli. Through a phagocytosis mechanism, the particles are internalized by the macrophages of the pulmonary epithelium and continue to exert their toxicity. Currently, the only decorporating agent administered in the event of contamination with plutonium is DTPA (diethylenetriaminepentaacetic acid). in France, it is administered as CaNa3-DTPA by intravenous injection. This standard is effective for contamination by ingestion and injury. However, it is not effective in case of contamination by inhalation. Functionalized nanoparticles based on natural polymers constitute an innovative concept for decorporating Pu(IV) solubilized in pulmonary macrophages and open the way for the development of new families of decorporants. We investigated two strategies: chitosan-based nanoparticles functionalized by the DTPMP (diethylenetriaminepentamethylene phosphonic acid) which is the phosphonic analog of DTPA and self-organized chelating β-cyclodextrin-based nanoparticles. This work was first focused on the synthesis and characterization of the nano-objects and then on the study of their complexation abilities with actinides (Th/Pu) using EXAFS spectroscopy. Finally, preliminary in vitro biological tests were carried out. Our obtained results with DTPMP and chitosan based nanoparticles showed that these aggregates exhibit size and stability compatible with the application. Furthermore, we demonstrate their affinity for the actinides(IV) (Th, Pu) is comparable to the reference DTPA. Finally, in vitro tests realized onto macrophages show that our nanoparticles are rapidly internalized through phagocytosis and that the polysaccharide matrix seems to undergo degradation which allows the DTPMP to be released and targeted right into the sequestration sites of Pu(IV). This work constitutes a first step in the development of new family of decorporating agents with a higher efficiency in case of plutonium contamination through inhalation.
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Formulation, characterisation and in vivo efficacy of dapsone and proguanil in trimethylated chitosan microparticles / Jacobus van HeerdenVan Heerden, Jacobus January 2014 (has links)
Malaria is an infectious disease caused by various forms of the Plasmodium parasite. It is
responsible for thousands of deaths yearly with 90 % of those deaths being in sub-Saharan
Africa, thus making it a disease of global importance. The global burden of malaria is
worsened by resistance to current treatment, a lack in funding and limited research outputs.
More alternative ways of treatment must be explored and may include the co-formulation of
antimalarial drug substances as well as alternative ways of drug delivery.
Antifolates are drugs which interfere with an organism’s folate metabolism by inhibiting
dihydropteroate synthase (DHPS) or dihydrofolate reductase (DHFR). Dapsone is a synthetic
sulfone which has a mechanism of action that is very similar to that of sulphonamides. The
mechanism of action is characterised by the inhibition of folic acid synthesis through the
inhibition of dihydropteroate synthase (DHPS). Another antifolate drug, proguanil, is the
prodrug of cycloguanil. Its mechanism involves the inhibition of dihydrofolate reductase
(DHFR), thus inhibiting the malaria parasite to metabolise folates and therefore stunting its
growth. Unfortunately, dapsone has a serious side-effect in people with a deficiency of the
enzyme glucose-6-phosphate dehydrogenase (G6PD) causing oxidative stress on the red
blood cells leading to the rupturing of these cells.
The main objective of this study was to formulate and characterise TMC-TPP microparticles
loaded with the effective but toxic drug combination of dapsone and proguanil and to
determine if these drug-containing microparticles had in vivo efficacy against malaria.
N-trimethyl chitosan chloride (TMC), a partially quaternised chitosan derivative, shows good
water solubility across a wide pH range thus having mucoadhesive properties and excellent
absorption enhancing effects even at neutral pH. A faster, more efficient microwave
irradiation method was developed as an alternative to the conventional synthesising method
of TMC. TMC with the same degree of quaternisation (DQ), ± 60 %, was obtained in a quarter
of the reaction time (30 min) by using the newly developed method. The TMC synthesised
with the microwave irradiation method also exhibited less degradation of the polymer
structure, thus limiting the chance for the formation of any unwanted by-products (Omethylation,
N,N-dimethylation and N-monomethylation).
The formation of complexes by ionotropic gelation between TMC and oppositely charged
macromolecules, such as tripolyphosphate (TPP), has been utilised to prepare microparticles
which are a suitable drug delivery system for the dapsone-proguanil combination. Both these
drugs were successfully entrapped. These particles were characterised and the in vivo
efficacy against the malaria parasites was determined. The microparticles with both the
drugs, separately and in combination, displayed similar or better in vivo efficacy when
compared to the drugs without the TMC microparticles.
An in vitro dissolution study was also performed by subjecting the dapsone and proguanil
TMC formulations to 0.1N HCl dissolution medium. Samples were withdrawn after
predetermined time points and the drug concentration was determined with HPLC. It was
found that the TMC microparticles resulted in a sustained release profile since only 73.00 ±
1.70 % (dapsone) and 55.00 ± 1.90 % (proguanil) was released after 150 minutes. The in vivo
bioavailability of the dapsone and proguanil TMC formulations was evaluated in mice by
collecting blood samples at predetermined time points and analysing the samples with a
sensitive and accurate LC-MS/MS method. The in vivo bioavailability of the dapsone TMC
formulation relative to the normal dapsone formulation was found to be 244 % and 123 % for
the proguanil TMC formulation relative to the normal proguanil formulation.
These TMC-TPP microparticles formulations showed better in vivo efficacy and bioavailability
when compared to the normal formulation. Together with the sustained release, these
formulations may be a promising cheaper and more effective treatment against malaria. / PhD (Pharmaceutics), North-West University, Potchefstroom Campus, 2015
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Formulation, characterisation and in vivo efficacy of dapsone and proguanil in trimethylated chitosan microparticles / Jacobus van HeerdenVan Heerden, Jacobus January 2014 (has links)
Malaria is an infectious disease caused by various forms of the Plasmodium parasite. It is
responsible for thousands of deaths yearly with 90 % of those deaths being in sub-Saharan
Africa, thus making it a disease of global importance. The global burden of malaria is
worsened by resistance to current treatment, a lack in funding and limited research outputs.
More alternative ways of treatment must be explored and may include the co-formulation of
antimalarial drug substances as well as alternative ways of drug delivery.
Antifolates are drugs which interfere with an organism’s folate metabolism by inhibiting
dihydropteroate synthase (DHPS) or dihydrofolate reductase (DHFR). Dapsone is a synthetic
sulfone which has a mechanism of action that is very similar to that of sulphonamides. The
mechanism of action is characterised by the inhibition of folic acid synthesis through the
inhibition of dihydropteroate synthase (DHPS). Another antifolate drug, proguanil, is the
prodrug of cycloguanil. Its mechanism involves the inhibition of dihydrofolate reductase
(DHFR), thus inhibiting the malaria parasite to metabolise folates and therefore stunting its
growth. Unfortunately, dapsone has a serious side-effect in people with a deficiency of the
enzyme glucose-6-phosphate dehydrogenase (G6PD) causing oxidative stress on the red
blood cells leading to the rupturing of these cells.
The main objective of this study was to formulate and characterise TMC-TPP microparticles
loaded with the effective but toxic drug combination of dapsone and proguanil and to
determine if these drug-containing microparticles had in vivo efficacy against malaria.
N-trimethyl chitosan chloride (TMC), a partially quaternised chitosan derivative, shows good
water solubility across a wide pH range thus having mucoadhesive properties and excellent
absorption enhancing effects even at neutral pH. A faster, more efficient microwave
irradiation method was developed as an alternative to the conventional synthesising method
of TMC. TMC with the same degree of quaternisation (DQ), ± 60 %, was obtained in a quarter
of the reaction time (30 min) by using the newly developed method. The TMC synthesised
with the microwave irradiation method also exhibited less degradation of the polymer
structure, thus limiting the chance for the formation of any unwanted by-products (Omethylation,
N,N-dimethylation and N-monomethylation).
The formation of complexes by ionotropic gelation between TMC and oppositely charged
macromolecules, such as tripolyphosphate (TPP), has been utilised to prepare microparticles
which are a suitable drug delivery system for the dapsone-proguanil combination. Both these
drugs were successfully entrapped. These particles were characterised and the in vivo
efficacy against the malaria parasites was determined. The microparticles with both the
drugs, separately and in combination, displayed similar or better in vivo efficacy when
compared to the drugs without the TMC microparticles.
An in vitro dissolution study was also performed by subjecting the dapsone and proguanil
TMC formulations to 0.1N HCl dissolution medium. Samples were withdrawn after
predetermined time points and the drug concentration was determined with HPLC. It was
found that the TMC microparticles resulted in a sustained release profile since only 73.00 ±
1.70 % (dapsone) and 55.00 ± 1.90 % (proguanil) was released after 150 minutes. The in vivo
bioavailability of the dapsone and proguanil TMC formulations was evaluated in mice by
collecting blood samples at predetermined time points and analysing the samples with a
sensitive and accurate LC-MS/MS method. The in vivo bioavailability of the dapsone TMC
formulation relative to the normal dapsone formulation was found to be 244 % and 123 % for
the proguanil TMC formulation relative to the normal proguanil formulation.
These TMC-TPP microparticles formulations showed better in vivo efficacy and bioavailability
when compared to the normal formulation. Together with the sustained release, these
formulations may be a promising cheaper and more effective treatment against malaria. / PhD (Pharmaceutics), North-West University, Potchefstroom Campus, 2015
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Nasal delivery of recombinant human growth hormone with pheroid technology / Dewald SteynSteyn, Johan Dewald January 2006 (has links)
Over the past couple of years there has been rapid progress in the development and design of
safe and effective delivery systems for the administration of protein and peptide drugs. The
effective delivery of these type of drugs are not always as simple as one may think, due to
various inherent characteristics of these compounds.
Due to the hydrophilic nature and molecular size of peptide and protein drugs, such as
recombinant human growth hormone, they are poorly absorbed across mucosal epithelia,
both transcellularly and paracellularly. This problem can be overcome by the inclusion of
absorption enhancers in peptide and protein drug formulations but this is not necessarily the
best method to follow.
This investigation focussed specifically on the evaluation of the ability of the PheroidTM
carrier system to transport recombinant human growth hormone across mucosal epithelia
especially when administered via the nasal cavity. The PheroidTM delivery system is a
patented system consisting of a unique submicron emulsion type formulation. The PheroidTM
delivery system, based on PheroidTM technology, will for ease of reading be called Pheroid(s)
only throughout the rest of this dissertation.
The Pheroid carrier system is a unique microcolloidal drug delivery system. A Pheroid is a
stable structure within a novel therapeutic system which can be manipulated in terms of
morphology, structure, size and function. Pheroids consist mainly of plant and essential fatty
acids and can entrap, transport and deliver pharmacologically active compounds and other
useful substances to the desired site of action.
The specific objectives of this study can be summarised as follows:
a literature study on Pheroid technology;
a literature study on chitosan and N-trimethyl chitosan chloride;
a literature study on recombinant human growth hormone (somatropin);
a literature study on nasal drug administration;
formulation of a suitable Pheroid carrier;
entrapment of somatropin in the Pheroid carrier, and
in vivo evaluation of nasal absorption of somatropin in Sprague-Dawley rats. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2007.
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Nasal delivery of insulin with Pheroid technology / Tanile de BruynDe Bruyn, Tanile January 2006 (has links)
Approximately 350 million people worldwide suffer from diabetes mellitus (DM) and this
number increases yearly. Since the discovery and clinical application of insulin in 1921,
subcutaneous injections have been the standard treatment for DM. Because insulin is hydrophilic
and has a high molecular weight and low bioavailability, this molecule is poorly absorbed if
administered orally.
The aim of this study is to evaluate nasal delivery systems for insulin, using Sprague Dawley rats
as the nasal absorption model. Pheroid technology and N-trimethyl chitosan chloride (TMC)
with different dosages of insulin (4, 8 and 12 IU/kg bodyweight insulin) was administered in the
left nostril of the rat by using a micropipette. Pheroid technology is a patented (North-West
University) carrier system consisting of a unique oil/water emulsion that actively transports drug
actives through various physiological barriers. These formulations were administered nasally to
rats in a volume of 100 p/kg bodyweight in different types of Pheroids (vesicles, with a size of
1.7 1 - 1.94 pm and microsponges, with a size of 5.7 1 - 8.25 pm).
The systemic absorption of insulin was monitored by measuring arterial blood glucose levels
over a period of 3 hours. The TMC formulation with 4 IU/kg insulin produced clinically relevant
levels of insulin in the blood and as a result also the maximal hypoglycaemic effect. TMC is a
quaternary derivative of chitosan and is able to enhance the absorption of various peptide drugs
by opening tight junctions between epithelial cells. Pheroid formulations were also effective in
lowering blood glucose levels but only at higher doses (8 and 12 IU/kg) of insulin. This study
indicated that Pheroid rnicrosponges had a faster onset of action and a slightly better absorption
of insulin when compared to Pheroid vesicles, but many more studies are needed in this field.
Although the results of this study with absorption enhancers are encouraging, nasal insulin
bioavailability is still very low, and the Pheroid formulations and long-term safety of nasal
insulin therapy have yet to be investigated. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2007.
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Nasal drug delivery of calcitonin with pheroid technology / Jeanéne Celesté KotzéKotzé, Jeanéne Celesté January 2005 (has links)
Advances in biotechnology and recombinant technologies have lead to the
production of several classes of new drugs such as peptide and protein drugs.
These compounds are mostly indicated for chronic use but their inherent
characteristics such as size, polarity and stability prevent them from
incorporation in novel dosage forms. The bioavailability of nearly all peptide
drugs is very low due to poor absorption from the administration site. Several
challenges confront the pharmaceutical scientist in developing effective and
innovative dosage forms for these classes of drugs. A lot of attention has
been given to the nasal route of drug administration for delivery of peptide
drugs. The availability of several promising classes of absorption enhancers
and new drug delivery technologies has also prompt scientists to develop new
delivery systems for nasal administration of peptide drugs.
It has been shown in recent years that N-trimethyl chitosan chloride (TMC), a
quaternary derivative of chitosan, is effective in enhancing the absorption of
several peptide drugs, both in the peroral route and in the nasal route of drug
administration. Early indications are that new drug delivery technologies such
as Pheroid technology will also be able to enhance peptide drug absorption in
the nasal route. The aim of this study was to evaluate and compare the
absorption enhancing abilities of TMC and Pheroid technology in the nasal
delivery of calcitonin, a peptide hormone with low bioavailability.
Pheroid vesicles and Pheroid microsponges were prepared and characterized
for their morphology and size distribution. Calcitonin was entrapped into these
vesicles and microsponges and TMC and TMO solutions (0.5 % w/v),
containing calcitonin, was also prepared. These formulations were
administered nasally to rats in a volume of 100 μl/kg body-weight to obtain a
final concentration of 10 IU/kg body-weight of calcitonin. Plasma calcitonin
and calcium levels were determined over a period of 3 hours.
The results of this study clearly indicated that both Pheroid formulations and
the TMC formulation increase the nasal absorption of calcitonin with a
resulting decrease in plasma calcium levels, indicating an increased
absorption of calcitonin. The highest increase in calcitonin absorption was
obtained with the TMC formulation and this was explained by the difference in
the mechanism of action in enhancing peptide absorption between TMC and
Pheroid technology. It was concluded that Pheroid technology is also a potent
system to enhance peptide drug delivery and that the exact mechanism of
action should be investigated further. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2006.
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Permeation of excised intestinal tissue by insulin released from Eudragit® L100/Trimethyl chitosan chloride microspheres /E.B. Marais.Marais, Etienne Barend January 2013 (has links)
The purpose of this research project was to develop and characterise matrix type microspheres prepared from Eudragit® L100, containing insulin as model peptide drug as well as an absorption enhancer, N-trimethyl chitosan chloride (TMC), to improve intestinal absorption via the paracellular route. Insulin loaded microspheres were prepared using a single water in oil emulsification/evaporation method in accordance with a fractional factorial design (23) and subsequently characterised in terms of morphology as well as internal structure. Also, insulin and TMC loading were determined using a high pressure liquid chromatography analysis (HPLC) and colorimetric assay, respectively.
Scanning electron microscopic characterisation revealed that most microsphere formulations showed a spherical shape and smooth surface with a sponge-like internal structure as well as relatively good homogeneity in terms of size distribution. Insulin loading ranged from 27.9 ± 14.25 – 52.4 ± 2.72% between the different formulations. TMC loading was lower than for insulin and ranged from 29.1 ± 3.3 - 37.7 ± 2.3% between the different formulations. The pronounced difference in insulin and TMC loading between the microsphere formulations is probably the result of the multitude parameters involved as well as the complex physicochemical processes which govern emulsification/solvent evaporation. Based on the microsphere characterisation results, two formulations were selected (i.e. B and F) for further characterisation (i.e. particle size distribution, dissolution behaviour, and enteric nature) and for in vitro evaluation of insulin transport across excised Fischer (FSR) rat intestinal tissue using a Sweetana-Grass diffusion chamber. Particle size analysis by means of laser light diffraction of the two selected microsphere formulations revealed that the mean particle size (based on volume) ranged from 135.7 ± 41.05 to 157.3 ± 31.74 m. Dissolution results for microsphere Formulations B and F revealed that both insulin and TMC were released from the microsphere formulations in an alkaline environment (pH 7.4). The mean dissolution time (MDT) for insulin ranged from 34.5 ± 4.01 to 42.6 ± 9.06 min, while the MDT for TMC ranged from 1.2 ± 1.73 to 6.8 ± 6.42 min. Statistical analysis revealed no significant differences in the MDT of either insulin or TMC (p-value > 0.05) between the two formulations, although the difference between insulin and TMC of each formulation was significant (p-value < 0.05). Microsphere formulations B and F released 36.92 and 48.21% of their total drug content over a period of 1 h in 0.1 M HCl.
Microsphere Formulation B showed 8.3 ± 0.52% and formulation F 8.9 ± 2.26% transport of the initial insulin dose after a period of 120 min across excised rat intestinal tissue. The increase in insulin transport by the microsphere formulations compared to that of the control group (i.e. insulin alone) correlated well with the decrease in transepithelial electrical resistance (TEER) caused by the microsphere formulations. The transport of insulin from Formulations B and F represented transport enhancement ratios of 10.67 and 9.68, respectively.
Insulin loaded EudragitL100 microspheres containing TMC were successfully prepared by emulsification/solvent evaporation that demonstrated promising potential to serve as oral drug delivery systems for insulin. The microspheres exhibited improved insulin permeability across intestinal epithelial tissue; however, its enteric properties should be improved and clinical effectiveness need to be confirmed by future in vivo studies. / Thesis (MSc (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013.
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Permeation of excised intestinal tissue by insulin released from Eudragit® L100/Trimethyl chitosan chloride microspheres /E.B. Marais.Marais, Etienne Barend January 2013 (has links)
The purpose of this research project was to develop and characterise matrix type microspheres prepared from Eudragit® L100, containing insulin as model peptide drug as well as an absorption enhancer, N-trimethyl chitosan chloride (TMC), to improve intestinal absorption via the paracellular route. Insulin loaded microspheres were prepared using a single water in oil emulsification/evaporation method in accordance with a fractional factorial design (23) and subsequently characterised in terms of morphology as well as internal structure. Also, insulin and TMC loading were determined using a high pressure liquid chromatography analysis (HPLC) and colorimetric assay, respectively.
Scanning electron microscopic characterisation revealed that most microsphere formulations showed a spherical shape and smooth surface with a sponge-like internal structure as well as relatively good homogeneity in terms of size distribution. Insulin loading ranged from 27.9 ± 14.25 – 52.4 ± 2.72% between the different formulations. TMC loading was lower than for insulin and ranged from 29.1 ± 3.3 - 37.7 ± 2.3% between the different formulations. The pronounced difference in insulin and TMC loading between the microsphere formulations is probably the result of the multitude parameters involved as well as the complex physicochemical processes which govern emulsification/solvent evaporation. Based on the microsphere characterisation results, two formulations were selected (i.e. B and F) for further characterisation (i.e. particle size distribution, dissolution behaviour, and enteric nature) and for in vitro evaluation of insulin transport across excised Fischer (FSR) rat intestinal tissue using a Sweetana-Grass diffusion chamber. Particle size analysis by means of laser light diffraction of the two selected microsphere formulations revealed that the mean particle size (based on volume) ranged from 135.7 ± 41.05 to 157.3 ± 31.74 m. Dissolution results for microsphere Formulations B and F revealed that both insulin and TMC were released from the microsphere formulations in an alkaline environment (pH 7.4). The mean dissolution time (MDT) for insulin ranged from 34.5 ± 4.01 to 42.6 ± 9.06 min, while the MDT for TMC ranged from 1.2 ± 1.73 to 6.8 ± 6.42 min. Statistical analysis revealed no significant differences in the MDT of either insulin or TMC (p-value > 0.05) between the two formulations, although the difference between insulin and TMC of each formulation was significant (p-value < 0.05). Microsphere formulations B and F released 36.92 and 48.21% of their total drug content over a period of 1 h in 0.1 M HCl.
Microsphere Formulation B showed 8.3 ± 0.52% and formulation F 8.9 ± 2.26% transport of the initial insulin dose after a period of 120 min across excised rat intestinal tissue. The increase in insulin transport by the microsphere formulations compared to that of the control group (i.e. insulin alone) correlated well with the decrease in transepithelial electrical resistance (TEER) caused by the microsphere formulations. The transport of insulin from Formulations B and F represented transport enhancement ratios of 10.67 and 9.68, respectively.
Insulin loaded EudragitL100 microspheres containing TMC were successfully prepared by emulsification/solvent evaporation that demonstrated promising potential to serve as oral drug delivery systems for insulin. The microspheres exhibited improved insulin permeability across intestinal epithelial tissue; however, its enteric properties should be improved and clinical effectiveness need to be confirmed by future in vivo studies. / Thesis (MSc (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013.
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Nasal delivery of insulin with Pheroid technology / Tanile de BruynDe Bruyn, Tanile January 2006 (has links)
Approximately 350 million people worldwide suffer from diabetes mellitus (DM) and this
number increases yearly. Since the discovery and clinical application of insulin in 1921,
subcutaneous injections have been the standard treatment for DM. Because insulin is hydrophilic
and has a high molecular weight and low bioavailability, this molecule is poorly absorbed if
administered orally.
The aim of this study is to evaluate nasal delivery systems for insulin, using Sprague Dawley rats
as the nasal absorption model. Pheroid technology and N-trimethyl chitosan chloride (TMC)
with different dosages of insulin (4, 8 and 12 IU/kg bodyweight insulin) was administered in the
left nostril of the rat by using a micropipette. Pheroid technology is a patented (North-West
University) carrier system consisting of a unique oil/water emulsion that actively transports drug
actives through various physiological barriers. These formulations were administered nasally to
rats in a volume of 100 p/kg bodyweight in different types of Pheroids (vesicles, with a size of
1.7 1 - 1.94 pm and microsponges, with a size of 5.7 1 - 8.25 pm).
The systemic absorption of insulin was monitored by measuring arterial blood glucose levels
over a period of 3 hours. The TMC formulation with 4 IU/kg insulin produced clinically relevant
levels of insulin in the blood and as a result also the maximal hypoglycaemic effect. TMC is a
quaternary derivative of chitosan and is able to enhance the absorption of various peptide drugs
by opening tight junctions between epithelial cells. Pheroid formulations were also effective in
lowering blood glucose levels but only at higher doses (8 and 12 IU/kg) of insulin. This study
indicated that Pheroid rnicrosponges had a faster onset of action and a slightly better absorption
of insulin when compared to Pheroid vesicles, but many more studies are needed in this field.
Although the results of this study with absorption enhancers are encouraging, nasal insulin
bioavailability is still very low, and the Pheroid formulations and long-term safety of nasal
insulin therapy have yet to be investigated. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2007.
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Nasal drug delivery of calcitonin with pheroid technology / Jeanéne Celesté KotzéKotzé, Jeanéne Celesté January 2005 (has links)
Advances in biotechnology and recombinant technologies have lead to the
production of several classes of new drugs such as peptide and protein drugs.
These compounds are mostly indicated for chronic use but their inherent
characteristics such as size, polarity and stability prevent them from
incorporation in novel dosage forms. The bioavailability of nearly all peptide
drugs is very low due to poor absorption from the administration site. Several
challenges confront the pharmaceutical scientist in developing effective and
innovative dosage forms for these classes of drugs. A lot of attention has
been given to the nasal route of drug administration for delivery of peptide
drugs. The availability of several promising classes of absorption enhancers
and new drug delivery technologies has also prompt scientists to develop new
delivery systems for nasal administration of peptide drugs.
It has been shown in recent years that N-trimethyl chitosan chloride (TMC), a
quaternary derivative of chitosan, is effective in enhancing the absorption of
several peptide drugs, both in the peroral route and in the nasal route of drug
administration. Early indications are that new drug delivery technologies such
as Pheroid technology will also be able to enhance peptide drug absorption in
the nasal route. The aim of this study was to evaluate and compare the
absorption enhancing abilities of TMC and Pheroid technology in the nasal
delivery of calcitonin, a peptide hormone with low bioavailability.
Pheroid vesicles and Pheroid microsponges were prepared and characterized
for their morphology and size distribution. Calcitonin was entrapped into these
vesicles and microsponges and TMC and TMO solutions (0.5 % w/v),
containing calcitonin, was also prepared. These formulations were
administered nasally to rats in a volume of 100 μl/kg body-weight to obtain a
final concentration of 10 IU/kg body-weight of calcitonin. Plasma calcitonin
and calcium levels were determined over a period of 3 hours.
The results of this study clearly indicated that both Pheroid formulations and
the TMC formulation increase the nasal absorption of calcitonin with a
resulting decrease in plasma calcium levels, indicating an increased
absorption of calcitonin. The highest increase in calcitonin absorption was
obtained with the TMC formulation and this was explained by the difference in
the mechanism of action in enhancing peptide absorption between TMC and
Pheroid technology. It was concluded that Pheroid technology is also a potent
system to enhance peptide drug delivery and that the exact mechanism of
action should be investigated further. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2006.
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