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Drug transporters in the nasal epithelia and their contribution in drug deliveryAl-Ghabeish, Manar I. 01 December 2014 (has links)
The nasal route has primarily been used to deliver drugs for the treatment of local diseases such as nasal infections, nasal congestion and allergies. The nasal route can also be used as a non-invasive alternative route to deliver drugs systemically when a rapid onset of action and/or avoidance of hepatic metabolism are desired. Moreover, there is a growing interest in the use of this route for direct transport of drugs from the nose to the brain. Most of the drugs that have been studied for nasal delivery are either small molecules which are lipophilic enough to passively diffuse through the nasal epithelia or macromolecules where bioavailabilities less than 1% are clinically effective and acceptable. This study focused on identifying carrier proteins or transporters in the nasal mucosa that could improve the absorption of specific drug substrates across the nasal respiratory and olfactory epithelia.
The presence of drug transporters in the nasal mucosa of humans and commonly used animal models were investigated. DNA microarray results for nasal samples from humans and two commonly used models, mice and rats, were obtained from GenBank and were analyzed in collaboration with the University of Iowa Center for Bioinformatics and Computational Biology. While cow tissues are frequently used in in-vitro nasal permeability analyses, there is limited information available in GenBank for this species. Both DNA microarray analysis and RT-PCR were performed on bovine nasal explants to determine transporter expression. Good agreement between the microarray and RT-PCR results was observed.
While human and three animal species commonly used as models in nasal drug delivery research (mouse, rat, and cow) show similar patterns of expression for several transporters, interspecies differences in the level of expression were observed. Therefore, the expression level of transporters remains a factor to consider when translating results obtained using animal models to humans.
The nucleoside transporter family was selected for further evaluation of the potential to improve the nasal absorption of substrates. Nucleoside transporters are integral proteins responsible for mediating and facilitating the flux of nucleosides across cellular membranes; they are also known to be responsible for the uptake of nucleoside analog drugs such as anti-cancer and anti-viral agents. RT-PCR and Western blotting were used to verify the presence of two transporter subtypes, ENT1 and CNT3, in the bovine nasal respiratory and olfactory mucosa. The expression level of both transporters in the respiratory mucosa was comparable to that in the olfactory mucosa. Using immunohistochemistry, ENT1 and CNT3 were found to be localized primarily at the apical surface of the nasal epithelial cells. This indicates that the nasal epithelium likely absorbs exogenous nucleosides for intracellular uses such as nucleic acid synthesis and regulating other cellular activities.
The contribution of the nucleoside transporters to the permeation of a nucleoside analogue drug, alovudine, across the nasal epithelia was also studied. The transport of alovudine showed a non-linear increase with increasing donor concentration over the range of 50 to 3000 µM which suggests that nucleoside transporters play a role in its uptake. Polarized transport was not observed suggesting that the facilitative nature of ENT1 plays a major role in alovudine transport. S-(4-nitrobenzyl)-6-thioinosine (NBMPR), an ENT1 inhibitor, incompletely decreased alovudine permeability across the nasal mucosa. This demonstrates that at least one transporter, ENT, plays a significant role in the uptake of this nucleoside drug across the nasal mucosa.
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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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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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Development and Characterization of formulations for the nose-to-brain delivery of ghrelin and the management of cachexiaSalade, Laurent 04 October 2019 (has links) (PDF)
For many years, the nasal route of administration as part of a therapeutic treatment has been used. This route of administration is easy to implement, especially due to its non-invasiveness the ease of administration that it affords for the patient. In addition, it is suitable for chronic treatment as well as for an emergency situation when the patient is unconscious. For instance, the administration of benzodiazepines, such as midazolam, may be done to stop convulsions in a patient.Traditionally, intranasal administration was mainly borrowed to target a local effect (e.g. treatment of a cold with a decongestant agent). Subsequently, its application for systemic delivery (e.g. treatment of migraine with triptans) was more and more frequently considered. However, the administration of a drug in the nasal cavities for systemic delivery still remains limited. Indeed, even if the intravenous route has several major limitations such as its invasiveness or the pain generated during administration, it remains more widely used than the intranasal route. This can be explained, on the one hand, by the knowledge that was relatively limited regarding the nasal delivery but also because of the unavailability of nasal devices allowing precise control of the nasal administration (i.e. accurate dose delivery, strong deposition in the nasal cavity, etc).Subsequently, the intranasal route has led to a third therapeutic targeting, namely, the “nose-to-brain pathway”. In that case, the nasal cavity was considered as an opportunity to access the central nervous system (CNS). Indeed, the nose-to-brain delivery allows reaching the brain while bypassing the blood-brain barrier which is known to be a major obstacle to the diffusion of drugs in the CNS. Moreover, the passage through the nasal cavity would allow the administration of sensitive molecules (e.g. biopharmaceuticals) while avoiding excessive enzymatic degradation.Therefore, the nose-to-brain pathway appears to be an attractive route for the delivery of unstable molecules, requiring an access to the brain to reach their site of action. In this context, the therapeutic target that has been selected was "cachexia". It is a complex metabolic syndrome associated with underlying illness and characterized by loss of muscle with or without loss of fat mass. It usually results in particular from undernutrition and a generalized inflammatory state in the patient. In order to treat this syndrome and to restore the appetite in these patients, the goal was to use ghrelin (GHRL) as a model drug. GHRL is a peptide hormone that exhibits, among other effects, an orexigenic action. This biopharmaceutical needs to reach its receptors, located in the hypothalamus, to exert its therapeutic effect.In this study, the goal was to develop a formulation that was able to protect GHRL during its nasal administration, while increasing its residence time to promote its diffusion through the nasal olfactory epithelium.In the first part of the project, GHRL was mainly characterized in terms of stability (e.g. temperature and pH), but also in terms of surface charge. These results allowed selecting the most suitable strategy of formulation as well as the optimal storage conditions. After these preformulation evaluations, it was decided to work on the development of a liquid formulation. The first formulation was based on micelles composed of lipids with polyethylene glycol "DSPE-PEG (1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N- [amino (polyethylene glycol) -2000] (ammonium salt)" as hydrophilic group. This type of pegylated lipids have already shown, in many scientific studies, interesting properties in the context of intranasal administration, especially in terms of mucopenetration. With a slight adaptation of the protocol found in the literature, it was possible to obtain micelles of an adequate size (~15 nm). The micelles produced also showed good ability to encapsulate GHRL with an encapsulation rate of 98%, but micelles of DSPE-PEG failed to increase the GHRL diffusion through epithelial layer. This step is essential in order to obtain high GHRL levels in the brain. The formulation containing DSPE-PEG micelles has thus been abandoned.Still in the goal of combining lipid excipients with hydrophilic polymer, another formulation strategy based on liposomes coated with chitosan has been considered. Since GHRL has a positive charge at physiological pH, anionic liposomes have been developed to get a high loading. Three types of liposomes have been produced: anionic, neutral and cationic. The objective was to evaluate the influence of the liposomes charge on GHRL encapsulation. By working with anionic liposomes, the loading could be 46% higher than that obtained from the cationic liposomes. In order to evaluate a potential relation between the amount of GHRL that was encapsulated in the liposomes and the amount of GHRL that could potentially be degraded in the presence of enzyme, the three types of liposomes were exposed to trypsin. Following enzyme exposure, anionic liposomes showed enzymatic protection 4 times higher than cationic liposomes. These anionic liposomes have also shown high GHRL protection in the presence of another enzyme with another mechanism of digestion, namely, carboxylesterase-1. Subsequently, isothermal titration calorimetry tests were performed to better understand the interaction mechanisms between GHRL and anionic liposomes. This technique showed that hydrophobic interactions between both compounds were predominant. The coating of anionic liposomes by chitosans was performed and confirmed by an increase of the mean diameter (+48 nm) and charge (+6 mV) as well as by the modification of the morphology of the liposomes. This coating of liposomes with chitosans was supposed to confer additional properties to the formulation such as mucoadhesion and permeation enhancement. These both effects can be obtained thanks to the positive charge of chitosans which allows adhering to the mucins of the mucus, on the one hand, and thanks to the opening of the epithelial tight junctions that enhances drug permeation, on the other hand. The chitosan coating allowed increasing the fixation of the liposomes to mucins by about twenty percent compared to uncoated liposomes. In addition, the "absorption promoter" effect of chitosans was confirmed on cells culture. Then, the formulation was introduced into two distinct nasal devices intended for the administration of liquid nasal sprays, namely, the VP3 device from Aptar Pharma and the SP270 device from Nemera. The aerosols produced by each device allowed generating droplets characterized by a mean diameter higher than 10µm, leading to potential satisfactory impaction onto the olfactory region instead of diffusion throughout posterior region of the nasal cavities. In the second part of the work, a dry formulation was produced by spray-drying from the liquid dispersion of coated liposomes. The objective was to increase the stability of GHRL during storage as well as to enhance its remanence and diffusion through the olfactory epithelium. The optimized parameters allowed producing a powder characterized by a mean diameter higher than 10 μm with an acceptable yield. The powder produced exhibited a low residual moisture and showed good homogeneity in terms of GHRL content. Then, a comparative study was carried out between the powder and the liquid formulation to compare the GHRL stability over time during storage at different temperatures (4°C and 25°C) but also their ability to fix mucins. In both cases, the dry powder showed better results The powder was also re-dispersed in aqueous phase to evaluate the ability of the liposomes to be reconstituted without modifying their physicochemical properties (e.g. size distribution, charges, stability). It was demonstrated that the majority of the initial properties could be preserved after reconstitution (i.e. rate of encapsulation). Similarly to the liquid formulation, the powder was loaded into a specific device developed for the nasal administration of powders that allows targeting the olfactory region to optimize the nose-to-brain transfer. The device, "UDS - Unit Dose System " from Aptar Pharma, has shown excellent properties in terms of particle size distribution in the aerosol but also in terms of targeting the olfactory zone. The latest was studied by means of "nasal cast" that is a 3-printed model of artificial nasal cavities. After impaction in the different cavities of the cast, it was possible to quantify the amount of GHRL that was deposited in the olfactory zone. Using our optimized formulation in combination with the device developed by Aptar, it was shown that 52% of the powder was impacted onto the area corresponding to the olfactory region. Such data demonstrated the relative difficulty to target this section of the nasal cavities.Finally, the formulation loaded with fluorescent GHRL was intranasally administered in mice. It was demonstrated that GHRL could reach the brain after intranasal administration of the formulation and that the formulation was essential to allow this transfer to the brain.The administration of such biopharmaceutical by nose-to-brain with this formulation seems to be an interesting alternative to exploit. However, additional studies to quantify this transfer more precisely, to better define its kinetics and also to evaluate the efficacy of the treatment should be carried out. / Doctorat en Sciences biomédicales et pharmaceutiques (Pharmacie) / info:eu-repo/semantics/nonPublished
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Using Computational Modeling Techniques to Identify and Target Viable Drug Delivery Protocols to Treat Chronic Otitis MediaMalik, Jennifer E. January 2018 (has links)
No description available.
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Studies on a Novel Powder Formulation for Nasal Drug DeliveryFransén, Nelly January 2008 (has links)
Nasal administration has potential for the treatment of indications requiring a fast onset of effect or for drugs with low oral bioavailability. Liquid nasal sprays are relatively common, but can be associated with suboptimal absorption from the nasal cavity; this thesis shows that nasal absorption can be significantly enhanced with a dry powder formulation. It was shown that interactive mixtures, consisting of fine drug particles adhered to the surface of mucoadhesive carrier particles, could be created in a particle size suitable for nasal administration. Sodium starch glycolate (SSG), a common tablet excipient, was used as carrier material. In vitro evaluation of the formulation indicated that the mucoadhesion of the carrier was unlikely to be affected by the addition of a drug. The powder formulation did not improve the in vitro transfer of dihydroergotamine across porcine nasal mucosa compared with a liquid formulation; however, the results were associated with methodological shortcomings. The binding of model substances to SSG and three other excipients was evaluated. Ion exchange interactions were for example detected between SSG and cationic drugs, but these interactions were most extensive at low salt concentrations and should unlikely affect in vivo bioavailability at physiological salt concentrations. Absorption of the peptide drug desmopressin from the SSG nasal formulation, from a novel sublingual tablet formulation and from a commercial nasal liquid spray was evaluated in a clinical trial. While no improvement over the liquid spray was seen with the sublingual tablet, plasma concentrations after the nasal powder formulation were three times higher than those after the liquid spray. All formulations were well accepted by the volunteers. The use of currently available mucoadhesive carrier particles in interactive mixtures offers potential for a new method of producing nasal powder formulations that should also be applicable to large scale production.
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EVALUATION OF THE REGIONAL DRUG DEPOSITION OF NASAL DELIVERY DEVICES USING IN VITRO REALISTIC NASAL MODELSAzimi, Mandana 01 January 2017 (has links)
The overall objectives of this research project were i) to develop and evaluate methods of characterizing nasal spray products using realistic nasal airway models as more clinically relevant in vitro tools and ii) to develop and evaluate a novel high-efficiency antibiotic nanoparticle dry powder formulation and delivery device. Two physically realistic nasal airway models were used to assess the effects of patient-use experimental conditions, nasal airway geometry and formulation / device properties on the delivery efficiency of nasal spray products. There was a large variability in drug delivery to the middle passages ranging from 17 – 57 % and 47 – 77 % with respect to patient use conditions for the two nasal airway geometries. The patient use variables of nasal spray position, head angle and nasal inhalation timing with respect to spray actuation were found to be significant in determining nasal valve penetration and middle passage deposition of Nasonex®. The developed test methods were able to reproducibly generate similar nasal deposition profiles for nasal spray products with similar plume and droplet characteristics. Differences in spray plume geometry (smaller plume diameter resulted in higher middle passage drug delivery) were observed to have more influence on regional nasal drug deposition than changes to droplet size for mometasone furoate formulations in the realistic airway models.
Ciprofloxacin nanoparticles with a mean (SD) volume diameter of 120 (10) nm suitable for penetration through mucus and biofilm layers were prepared using sonocrystallization technique. These ciprofloxacin nanoparticles were then spray dried in a PVP K30 matrix to form nanocomposite particles with a mean (SD) volume diameter of 5.6 (0.1) µm. High efficiency targeted delivery of the nanocomposite nasal powder formulation was achieved using a modified low flow VCU DPI in combination with a novel breathing maneuver; delivering 73 % of the delivered dose to the middle passages. A modified version of the nasal airway model accommodating Transwell® inserts and a Calu-3 monolayer was developed to allow realistic deposition and evaluation of the nasal powder. The nanocomposite formulation was observed to demonstrate improved dissolution and transepithelial transport (flux = 725 ng/h/cm2) compared to unprocessed ciprofloxacin powder (flux = 321 ng/h/cm2).
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