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Cerebral blood flow in the non-human primate : an in vivo model and drug interventions / Douglas W. OliverOliver, Douglas William January 2003 (has links)
Cerebral blood flow dynamics is an essential component for preserving
cerebral integrity. Cerebral blood flow abnormalities are often seen in patients
with central nervous system pathologies such as epilepsy, migraine,
Alzheimer's Disease, vascular dementia, stroke, and even HIV/AIDS. There is
increasing clinical and experimental evidence implicating cerebral
hypoperfusion during ageing. The determination of cerebral perfusion has
therefore become an important objective in physiological, pathological,
pharmacological, and clinical investigations. The knowledge of regional
cerebral blood flow further provides useful diagnostic information and/or data
for a better understanding of the complex clinical presentations in patients with
neurological and psychiatric disorders. Several cerebrovasoactive drugs have
found application in the clinical setting of cerebrovascular diseases such as
migraine and dementia.
Due to the similarities between humans and non-human primates with
respect to their brains, both structurally and behaviourally, numerous studies
have been conducted and several non-human primate models have been
developed for physiological, pathological, pharmacological, and clinical studies,
amongst others in Parkinson's disease and diabetes. The relatively large size
of the Cape baboon Papio Ursinus with a weight of 27-30 kg for a large male,
makes this primate especially suitable for in vivo brain studies using
radiotracers and Single Photon Emission Computed Tomography (SPECT).
The main aim of the current study was therefore to develop a suitable
radiotracer (99m Tc-hexamethylpropylene amine oxime (HMPAO) or 99m Tc_ethyl_cysteinatedimer (ECD) or 123l-iodoamphetamine (IMP)) for adapted in vivo
cerebral blood flow measurements in a non-human primate (Papio ursinus) as
an investigative model. The model was to be validated and applied in various
drug studies for the evaluation of pharmacological interventions. The study
design made use of split-dose methodology, whereby the radiopharmaceutical
(radiotracer) was administered twice during each study. The first administration
was injected soon after the induction of the anaesthesia, and was followed by
the first SPECT data acquisition. The second administration of the radioligand,
a double dose of radioactivity with respect to the first radioligand injection, was
done at a specific time during the study, which took into account the
pharmacodynamics of the drug. A second SPECT data acquisition followed
subsequently. The drugs that were included in the study were acetazolamide,
a carbonic acid anhydrase inhibitor (often used in nuclear medicine to
determine cerebral reserve); sumaptriptan, a 5-HT (serotonin) agonist used for
treatment of migraine; sodium valproate (an anti-epileptic drug); nimodipine, a
calcium channel blocker and nitro-glycerine, a vasodilator used for angina.
Arterial blood pressures were recorded from a catheter in the femoral artery
and heart rates were concurrently monitored.
The split-dose method was successfully applied to develop a non-human
primate cerebral blood flow model under anaesthesia. The model showed
differences in cerebral perfusion of the different anaesthesia regimes. These
anaesthesia data sets were suitable as control/baseline results for drug
intervention studies. Acetazolamide evaluation through the split-dose method
in the baboon confirmed the sensitivity of the model by presenting comparable
perfusion. This result compared to those already familiar prompted the model
to be applied in pharmacological intervention studies. Subsequent results of
these investigations showed increases in perfusion for single drug nimodipine
treatment (25%). However, nimodipine attenuated the increases in perfusion
when administered in combination with acetazolamide. Sumatriptan was able
to decrease and normalise the increased perfusion after long duration
anaesthesia. Decreased cerebral blood flow was observed for combinations of
nimodipine with sodium valproate suggesting drug-drug interaction with
important clinical implications. Similar decreases were found also for
sumatriptan and nitro-glycerine when administered in combination with
nimodipine.
Studies with the various tracers (99m Tc_HMPAO or 99m Tc_ECD or 123l_IMP)
showed clear differences in the perfusion data, confirming variation in the
biochemical performance of the tracers. These differences, if not taken into
consideration, caution for inappropriate clinical conclusions and subsequent
erroneous therapeutic decisions. Improvement of radiotracer efficacy was
subsequently attempted through application of the cyclodextrine complexation
approach. Although cyciodextrine technology did not markedly improve the
brain disposition of the 99m Tc-ECD, protection of the tracer against degradation
was demonstrated. This study encouraged further exploration of this method for
protection of the tracer against chemical and metabolic degradation.
The current study was aimed to develop and effectively apply a non-human
primate model with nuclear medicine technology for cerebral blood flow
determinations after pharmacological interventions. This was achieved through
the split-dose method and dedicated computer programming, which yielded a
successful model with the non-human primate under anaesthesia. The model
was validated with the application of acetazolamide to confirm familiar
cerebrovascular reserve results, indicating that the model is sensitive to CBF
changes. The model was also effectively applied in several pharmacological
intervention studies, whereby cerebropharmacodynamics of selected drugs
were investigated and established.
This unique model of a non-human primate, Papio ursinus for cerebral blood
flow determinations has served pharmacological research successfully during
the past 12 years and could do so in the future, with scope to investigate new
frontiers with improved technologies. / Thesis (Ph.D. (Pharmacology))--North-West University, Potchefstroom Campus, 2004.
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Cerebral blood flow in the non-human primate : an in vivo model and drug interventions / Douglas W. OliverOliver, Douglas William January 2003 (has links)
Cerebral blood flow dynamics is an essential component for preserving
cerebral integrity. Cerebral blood flow abnormalities are often seen in patients
with central nervous system pathologies such as epilepsy, migraine,
Alzheimer's Disease, vascular dementia, stroke, and even HIV/AIDS. There is
increasing clinical and experimental evidence implicating cerebral
hypoperfusion during ageing. The determination of cerebral perfusion has
therefore become an important objective in physiological, pathological,
pharmacological, and clinical investigations. The knowledge of regional
cerebral blood flow further provides useful diagnostic information and/or data
for a better understanding of the complex clinical presentations in patients with
neurological and psychiatric disorders. Several cerebrovasoactive drugs have
found application in the clinical setting of cerebrovascular diseases such as
migraine and dementia.
Due to the similarities between humans and non-human primates with
respect to their brains, both structurally and behaviourally, numerous studies
have been conducted and several non-human primate models have been
developed for physiological, pathological, pharmacological, and clinical studies,
amongst others in Parkinson's disease and diabetes. The relatively large size
of the Cape baboon Papio Ursinus with a weight of 27-30 kg for a large male,
makes this primate especially suitable for in vivo brain studies using
radiotracers and Single Photon Emission Computed Tomography (SPECT).
The main aim of the current study was therefore to develop a suitable
radiotracer (99m Tc-hexamethylpropylene amine oxime (HMPAO) or 99m Tc_ethyl_cysteinatedimer (ECD) or 123l-iodoamphetamine (IMP)) for adapted in vivo
cerebral blood flow measurements in a non-human primate (Papio ursinus) as
an investigative model. The model was to be validated and applied in various
drug studies for the evaluation of pharmacological interventions. The study
design made use of split-dose methodology, whereby the radiopharmaceutical
(radiotracer) was administered twice during each study. The first administration
was injected soon after the induction of the anaesthesia, and was followed by
the first SPECT data acquisition. The second administration of the radioligand,
a double dose of radioactivity with respect to the first radioligand injection, was
done at a specific time during the study, which took into account the
pharmacodynamics of the drug. A second SPECT data acquisition followed
subsequently. The drugs that were included in the study were acetazolamide,
a carbonic acid anhydrase inhibitor (often used in nuclear medicine to
determine cerebral reserve); sumaptriptan, a 5-HT (serotonin) agonist used for
treatment of migraine; sodium valproate (an anti-epileptic drug); nimodipine, a
calcium channel blocker and nitro-glycerine, a vasodilator used for angina.
Arterial blood pressures were recorded from a catheter in the femoral artery
and heart rates were concurrently monitored.
The split-dose method was successfully applied to develop a non-human
primate cerebral blood flow model under anaesthesia. The model showed
differences in cerebral perfusion of the different anaesthesia regimes. These
anaesthesia data sets were suitable as control/baseline results for drug
intervention studies. Acetazolamide evaluation through the split-dose method
in the baboon confirmed the sensitivity of the model by presenting comparable
perfusion. This result compared to those already familiar prompted the model
to be applied in pharmacological intervention studies. Subsequent results of
these investigations showed increases in perfusion for single drug nimodipine
treatment (25%). However, nimodipine attenuated the increases in perfusion
when administered in combination with acetazolamide. Sumatriptan was able
to decrease and normalise the increased perfusion after long duration
anaesthesia. Decreased cerebral blood flow was observed for combinations of
nimodipine with sodium valproate suggesting drug-drug interaction with
important clinical implications. Similar decreases were found also for
sumatriptan and nitro-glycerine when administered in combination with
nimodipine.
Studies with the various tracers (99m Tc_HMPAO or 99m Tc_ECD or 123l_IMP)
showed clear differences in the perfusion data, confirming variation in the
biochemical performance of the tracers. These differences, if not taken into
consideration, caution for inappropriate clinical conclusions and subsequent
erroneous therapeutic decisions. Improvement of radiotracer efficacy was
subsequently attempted through application of the cyclodextrine complexation
approach. Although cyciodextrine technology did not markedly improve the
brain disposition of the 99m Tc-ECD, protection of the tracer against degradation
was demonstrated. This study encouraged further exploration of this method for
protection of the tracer against chemical and metabolic degradation.
The current study was aimed to develop and effectively apply a non-human
primate model with nuclear medicine technology for cerebral blood flow
determinations after pharmacological interventions. This was achieved through
the split-dose method and dedicated computer programming, which yielded a
successful model with the non-human primate under anaesthesia. The model
was validated with the application of acetazolamide to confirm familiar
cerebrovascular reserve results, indicating that the model is sensitive to CBF
changes. The model was also effectively applied in several pharmacological
intervention studies, whereby cerebropharmacodynamics of selected drugs
were investigated and established.
This unique model of a non-human primate, Papio ursinus for cerebral blood
flow determinations has served pharmacological research successfully during
the past 12 years and could do so in the future, with scope to investigate new
frontiers with improved technologies. / Thesis (Ph.D. (Pharmacology))--North-West University, Potchefstroom Campus, 2004.
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Pathogenesis of orthopoxvirus (OPXV) infection in common CM and identification of immune correlates after vaccination with differently attenuated vaccines / Pathogenesis of orthopoxvirus (OPXV) infection in common CM and identification of immune correlates after vaccination with differently attenuated vaccinesGan, Li Lin 17 January 2018 (has links)
No description available.
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Dynamique des réponses lymphocytaires T locales et systémiques à l'injection d'un vaccin dans la peau / Dynamic of local and systemic cellular responses after vaccination in the skinJoly, Candie 26 September 2019 (has links)
La vaccination est considérée comme l’un des plus grandes découvertes de l’histoire des maladies infectieuses, ayant permis le déclin et l’éradication de plusieurs pathogènes. Cependant, nous ignorons encore tous les mécanismes impliqués dans la protection contre les pathogènes. Cette méconnaissance est la cause de notre incapacité à formuler des nouveaux vaccins contre le VIH, la tuberculose, le paludisme et les pathogènes émergents. Récemment, on note des efforts pour induire une réponse cellulaire efficace après une vaccination, qui joue un rôle crucial dans la clairance des pathogènes.Cette thèse s’appuie sur un modèle de vaccin vivant atténue issu du virus de la vaccine : le MVA (Modified Vaccinia Ankara) et sur le modèle de primate non-humain. Nous avons caractérisé la réponse cellulaire après une immunisation intradermique suivant un schéma en prime-boost homologue, avec un boost à 2, suivi d’un boost à 9 mois. Le MVA a induit une infiltration massive de Lymphocytes T CD8 au niveau du site d’injection, 7 jours après l’immunisation. La réponse cellulaire systémique était modérée et ne reflétait pas l’amplitude de la réponse locale. Les injections du prime et du boost ont orienté la réponse cellulaire de façon différente, ce qui a mené à une importante induction de cellules T CD4 et CD8, persistantes, spécifiques de l’antigène et polyfonctionnelles après l’injection du boost à 9 mois.Cette étude souligne la différence entre les réponses systémiques et locales, démontrant l’importance de se focaliser sur la réponse tissulaire. Elle a également mis en lumière l’impact du schéma d’immunisation sur la qualité de la réponse cellulaire. / Vaccination has been considered as one of the greatest discoveries in the history of infectious diseases by allowing pathogens decline or eradication. However, we still ignore all the mechanism that lead to protection and therefore, fail to elaborate new vaccines against HIV, tuberculosis, malaria and emergent pathogens. Recently, efforts have been made to elicit effective cellular response after vaccination, which is crucial for pathogen clearance.This thesis relied on live-attenuated vaccine model derived from the vaccinia virus: the MVA (Modified Vaccinia Ankara) and a non-human primate model. We characterized the cellular immune response triggered by a homologous prime-boost intradermal injection of MVA, with a 2 months and 9 months boost. The MVA induced a massive infiltration of CD8 T cells at the injection site 7 days post immunization. In comparison, the systemic cellular response was mild and did not reflect the magnitude of the local response. The prime and boost injections elicited distinct orientation of the systemic and local T cells, which led to an important induction of a persistent, antigen-specific and polyfunctional CD8 and CD4 T cell responses after the 9 months boost.This work emphasizes the difference between local and systemic response, demonstrating the importance of the focus on tissue immunity. It also highlights the impact of the immunization schedule on the quality of the cellular response.
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Infections of common marmosets with calpox virusKramski, Marit 29 January 2009 (has links)
Die vorsätzliche Freisetzung von Variola Virus (VARV) und schwere Erkrankungen des Menschen durch zoonotische Affen- (MPXV) und Kuh- (CPXV) pocken Viren stellen nach wie vor eine Bedrohung für die Bevölkerung dar. Klassische Pockenimpfstoffe bergen die Gefahr einer schweren Erkrankung. Deshalb ist die Entwicklung neuer Impfstoffe und Therapeutika von entscheidender Bedeutung. Deren Wirksamkeit und Sicherheit muss zunächst in verschiedenen Tiermodellen bewiesen werden. Existierende Makakken-Primatenmodelle leiden unter sehr artifiziellen Bedingungen der letalen Krankheitsinduktion durch VARV oder MPXV. Aus diesem Grund wurde das Calpox Virus/Krallenaffen-modell etabliert, welches auf einem CPXV aus natürlich infizierten Neuweltaffen (Marmosets) basiert. Das neue Modell hat drei wesentliche Vorteile: Die Arbeit mit Calpox Virus kann unter Sicherheitsstufe 2 durchgeführt werden und ist folglich einfacher in der Handhabung. 2. Die intranasale (i.n.) Infektion von Marmosets (Krallenaffen; Callithrix jacchus) spiegelt den natürlichen Infektionsweg von VARV wieder. Infizierte Affen entwickelten Pocken ähnliche Symptome und verstarben innerhalb von 2-3 Tagen nach Auftreten erster Symptome. Hohe Viruslasten wurden im Blut, Speichel und allen untersuchten Organen nachgewiesen. 3. Die i.n. Titration des Calpox Virus ergab eine 50 % Affen-Infektions-Dosis (MID50) von 8.3x102 pfu. Diese ist um den Faktor 10000 niedriger als in anderen Pocken-Primatenmodellen. Neun bis zehn Wochen nach einer Immunisierung mit dem Lister-Elstree Impfstoff waren alle Krallenaffen gegen eine letale Dosis des Calpox Virus (10 MID50) geschützt. Damit konnte der Nutzen des Calpox Virus/Krallenaffen-modells für die Erforschung neuer Impfstoffe gezeigt werden. Das Calpox Virus/Krallenaffen-modell überwindet wesentliche Nachteile bestehender Primatenmodelle und ist somit ein geeignetes Model für die Evaluierung von neuen Impfstoffen, Impfstrategien und antiviralen Therapien. / The intentional re-introduction of Variola virus (VARV), the agents of smallpox, into the human population remains of concern today. Moreover, zoonotic infections with Cowpox (CPXV) and Monkeypox virus (MPXV) cause severe diseases in humans. Smallpox vaccines presently available can have severe adverse effects that are no longer acceptable. The efficacy and safety of new vaccines and antivirals have to be demonstrated by different animal models. The existing primate models, using VARV and MPXV, need very high viral doses that have to be applied intravenously to induce a lethal infection in macaque monkeys. To overcome these drawbacks, the main objective of this study was to develop a primate model in which a smallpox-like disease could be induced by a CPXV virus designated calpox virus which was isolated from a lethal orthopox virus (OPV) outbreak in New World monkeys (marmosets). The new non-human primate model has three major advantages: 1. Working with calpox virus is less challenging and can be done under bio-safety-level two. 2. Mimicking the natural route of VARV infection, intranasally infected marmosets (Callithrix jacchus) reproducibly developed clinical symptoms of an OPV infection and died within two to three days after onset of the first symptoms. High viral loads of calpox virus were detected in blood, saliva and all analyzed organs. 3. Intranasal titration of the virus resulted in a 50 % monkey infectious dose (MID50) of 8.3x102 pfu, a lethal infectious dose 10,000 lower than those used in any other primate model. Moreover, we showed the aptitude of the primate model for the testing of new vaccines since nine to ten weeks after immunization with Vaccinia virus Lister-Elstree marmosets were completely protected against intranasal challenge with 10 MID50 of calpox virus. As the calpox virus/marmoset model overcomes major limitations of current primate models it is suitable to evaluate new vaccines, new vaccination strategies and antiviral therapies.
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