Modeling and design of an electromagnetic actuation system for the manipulation of microrobots in blood vessels

Tese de mestrado integrado em Física, apresentada à Universidade de Lisboa, através da Faculdade de Ciências, 2015A navegação de nano/microdispositivos apresenta um grande potencial para aplicações biomédicas, oferecendo meios de diagnóstico e procedimentos terapêuticos no interior do corpo humano. Dada a sua capacidade de penetrar quase todos os materiais, os campos magnéticos são naturalmente adequados para controlar nano/microdispositivos magnéticos em espaços inacessíveis. Uma abordagem recente é o uso de um aparelho personalizado, capaz de controlar campos magnéticos. Esta é uma área de pesquisa prometedora, mas mais simulações e experiências são necessárias para avaliar a viabilidade destes sistemas em aplicações clínicas. O objectivo deste projecto foi a simulação e desenho de um sistema de atuação eletromagnética para estudar a locomoção bidimensional de microdispositivos. O primeiro passo foi identificar, através da análise de elementos finitos, usando o software COMSOL, diferentes configurações de bobines que permitiriam o controlo de dispositivos magnéticos em diferentes escalas. Baseado nos resultados das simulações, um protótipo de um sistema de atuação magnética para controlar dispositivos com mais de 100 m foi desenhado e construído de raiz, tendo em conta restrições de custos. O sistema consistiu num par de bobines de Helmholtz e rotacionais e um par de bobines de Maxwell dispostas no mesmo eixo. Além disso, componentes adicionais tiveram de ser desenhados ou selecionados para preencher os requisitos do sistema. Para a avaliação do sistema fabricado, testes preliminares foram realizados. A locomoção do microrobot foi testada em diferentes direções no plano x-y. As simulações e experiências confirmaram que é possível controlar a força magnética e o momento da força que atuam num microdispositivo através do campos produzidos pelas bobines de Maxwell e Helmholtz, respectivamente. Assim, este tipo de atuação magnética parece ser uma forma adequada de transferência de energia para futuros microdispositivos biomédicos.Navigation of nano/microdevices has great potential for biomedical applications, offering a means for diagnosis and therapeutic procedures inside the human body. Due to their ability to penetrate most materials, magnetic fields are naturally suited to control magnetic nano/microdevices in inaccessible spaces. One recent approach is the use of custom-built apparatus capable of controlling magnetic devices. This is a promising area of research, but further simulation studies and experiments are needed to estimate the feasibility of these systems in clinical applications. The goal of this project was the simulation and design of an electromagnetic actuation system to study the two dimensional locomotion of microdevices. The first step was to identify, through finite element analysis using software COMSOL, different coil configurations that would allow the control of magnetic devices at different scales. Based on the simulation results, a prototype of a magnetic actuation system to control devices with more than 100 m was designed and built from the ground up, taking into account cost constraints. The system comprised one pair of rotational Helmholtz coils and one pair of rotational Maxwell coils placed along the same axis. Furthermore, additional components had to be designed or selected to fulfil the requirements of the system. For the evaluation of the fabricated system, preliminary tests were carried out. The locomotion of a microdevice was tested along different directions in the x-y plane. The simulations and experiments confirmed that it is possible to control the magnetic force and torque acting on a microdevice through the fields produced by Maxwell and Helmholtz coils, respectively. Thus, this type of magnetic actuation seems to provide a suitable means of energy transfer for future biomedical microdevices

Evolutionary and Physical Properties of Meteoroids

Astrophysical models for meteoroid formation and stellar and planetary evolutions are developed from simulation composition studies

Aerospace Medicine and Biology: A continuing bibliography with indexes, supplement 140

This bibliography lists 306 reports, articles, and other documents introduced into the NASA scientific and technical information system in March 1975

Mise au point de microparticules polysaccharides injectables pour l'imagerie moléculaire de pathologies artérielles

Cardiovascular diseases and their consequences constitute nowadays a major health issue. Their treatment could be substantially improved with the development of new non invasive diagnostic techniques. The aim of this doctoral project is to develop injectable into blood stream polysaccharide microparticles that would permit molecular imaging of arterial pathologies. From an emulsion- crosslinking process, we synthesized these microparticles which are on the one hand functionalized with fucoidan to target P-Selectin which is expressed at damaged arterial wall, and on the other hand combined with contrast agents to bring an imaging signal. We developed 2 molecular imaging tools dedicated to 2 classical medical imaging modalities. In order to track the microparticles by single photon emission computed tomography, we radiolabeled them with technetium 99m and to detect them by MRI, we loaded them with superparamagnetic nanoparticles of iron oxide. We then have validated the efficiency of these 2 molecular imaging tools with preclinical studies of in vivo small animal imaging of arterial disease models. The obtained results are very promising and these 2 molecular imaging tools have a strong clinical potential for the diagnosis of arterial pathologies. We also have observed that the microparticles tend to migrate though the damaged arterial wall. This specific property could turn out to be very interesting for future works which will consist in using this technology to convey therapeutic molecules directly into the core of the arterial pathologies.Les pathologies cardiovasculaires et leurs conséquences représentent actuellement un problème de santé publique majeur dont la prise en charge pourrait être considérablement améliorée par le développement de nouvelles méthodes de diagnostic non invasives. Ce projet doctoral vise à développer des microparticules polysaccharides injectables dans la circulation sanguine permettant l’imagerie moléculaire des pathologies artérielles. Grâce à un procédé d’émulsion-réticulation, nous avons synthétisé ces microparticules qui sont d’une part fonctionnalisées avec du fucoïdane afin de pouvoir cibler la P-Sélectine qui est une molécule d’adhésion exprimée au niveau de la paroi artérielle lésée, et d’autre part, conjuguées à des agents de contraste afin d’apporter un signal en imagerie. Nous avons alors développé 2 outils d’imagerie moléculaire propres à 2 modalités classiques d’imagerie médicale. Afin de suivre les microparticules en tomographie par émission monophotonique de positons (TEMP), nous les avons radiomarquées avec du technétium 99m et pour les détecter en imagerie par résonance magnétique (IRM), nous les avons chargées avec des nanoparticules d’oxyde de fer superparamagnétiques. Nous avons ensuite validé l’efficacité de ces 2 outils d’imagerie moléculaire avec des essais précliniques en imagerie in vivo chez le petit animal sur des modèles de pathologies artérielles. Les résultats obtenus sont très encourageants et ces 2 outils d’imagerie moléculaire ont un fort potentiel clinique pour le diagnostic des pathologies artérielles. Nous avons également observé que les microparticules migrent dans la paroi artérielle dégradée au niveau des pathologies étudiées. Cette propriété singulière pourrait s’avérer très intéressante pour les futurs travaux qui consisteront à utiliser ce support pour véhiculer des molécules thérapeutiques au cœur des différentes pathologies artérielles

A Pilot Study of Dietary Nitrate Supplementation in Anaemic Patients

Introduction Anaemia causes debilitating symptoms in people with cancer, partly through reduced tissue oxygenation. Nitrate supplementation, via reduction to nitrite then nitric oxide, attenuates the effects of systemic hypoxia on muscle metabolism. Nitric oxide also influences cerebral blood flow, neurotransmission and platelet aggregation. Aims To examine the feasibility of recruiting patients with cancer-related anaemia to a pilot study, and to estimate differences in outcome measures and predict resources required for a larger study investigating how nitrate supplementation affects thrombogenicity, muscle phosphocreatine recovery, exercise tolerance, cognition and quality of life. Methods This prospective, balanced randomised crossover study recruited 33 participants. Cycle ergometry, bloods, 31P-magnetic resonance spectroscopy and quality of life & cognition questionnaires were completed at two baseline visits and two visits post-supplementation with either nitrate-rich (BR) or nitrate-depleted (PL) beetroot juice. Results 85% of 33 screened patients were enrolled. 26 completed all visits. Plasma nitrate concentration was 8.4±58.8µM (mean±SD) at baseline and 78±33.5µM post-BR (p=<0.001*). Nitrite was 142±79nM (baseline) and 923±1006nM post-BR (p=0.000*). Haemoglobin concentration was 111.4±9.8g/l (baseline), 109.1±10.9g/l post-BR but 114.6±12g/l post-PL (p=0.028*). FACT-An quality of life score was 146±20 at baseline and improved to 152±24 post-PL and 150±25 post-BR (p=0.025*). Baseline FACT-cog cognitive function was 105±23 and improved to 109±24 post-PL and 108±23 post-BR (p=0.03*). Gas exchange threshold was53±11W post-PL; baseline was 51±12W, BR 50±12W, p=0.0238*. Baseline systolic blood pressure was 122±15mmHg, higher than post-BR (117±15mmHg) and post-PL (116±15mmHg), p=0.0081*). Oxygen uptake, peak power, phosphocreatine recovery, diastolic blood pressure and platelet aggregometry were not significantly affected. Conclusion This pilot study recruited and retained participants well. The enterosalivary circulation of nitrate was intact. The study was not powered to prove or disprove its hypotheses, but demonstrated that clinical factors (particularly haemoglobin concentration which varied because of chemotherapy and cancer progression/response) in this unstable population should influence future study design.Exeter Leukaemia Fund National Institute for Health Researc

Oxidative stress and its haemodynamic consequences in chronic kidney disease

Chronic kidney disease (CKD) is associated with increased cardiovascular risk in comparison with the general population. This can be observed even in the early stages of CKD, and rises in proportion to the degree of renal impairment. Not only is cardiovascular disease (CVD) more prevalent in CKD, but its nature differs too, with an excess of morbidity and mortality associated with congestive cardiac failure, arrhythmia and sudden death, as well as the accelerated atherosclerosis which is also observed. Conventional cardiovascular risk factors such as hypertension, dyslipidaemia, obesity, glycaemia and smoking, are highly prevalent amongst patients with CKD, although in many of these examples the interaction between risk factor and disease differs from that which exists in normal renal function. Nevertheless, the extent of CVD cannot be fully explained by these conventional risk factors, and non-conventional factors specific to CKD are now recognised to contribute to the burden of CVD. Oxidative stress is a state characterised by excessive production of reactive oxygen species (ROS) and other radical species, a reduction in the capacity of antioxidant systems, and disturbance in normal redox homeostasis with depletion of protective vascular signalling molecules such as nitric oxide (NO). This results in oxidative damage to macromolecules such as lipids, proteins and DNA which can alter their functionality. Moreover, many enzymes are sensitive to redox regulation such that oxidative modification to cysteine thiol groups results in activation of signalling cascades which result in adverse cardiovascular effects such as vascular and endothelial dysfunction. Endothelial dysfunction and oxidative stress are present in association with many conventional cardiovascular risk factors, and can be observed even prior to the development of overt, clinical, vascular pathology, suggesting that these phenomena represent the earliest stages of CVD. In the presence of CKD, there is increased ROS production due to upregulated NADPH oxidase (NOX), increase in a circulating asymmetric dimethylarginine (ADMA), uncoupling of endothelial nitric oxide synthase (eNOS) as well as other mechanisms. There is also depletion in exogenous antioxidants such as ascorbic acid and tocopherol, and a reduction in activity of endogenous antioxidant systems regulated by the master gene regulator Nrf-2. In previous studies, circulating markers of oxidative stress have been shown to be increased in CKD, together with a reduction in endothelial function in a stepwise fashion relating to the severity of renal impairment. Not only is CVD linked to oxidative stress, but the progression of CKD itself is also in part dependent on redox sensitive mechanisms. For example, administration of the ROS scavenger tempol attenuates renal injury and reduces renal fibrosis seen on biopsy in a mouse model of CKD, whilst conversely, supplementation with the NOS inhibitor L-NAME causes proteinuria and renal impairment. Previous human studies examining the effect of antioxidant administration on vascular and renal function have been conflicting however. The work contained in this thesis therefore examines the effect of antioxidant administration on vascular and endothelial function in CKD. Firstly, 30 patients with CKD stages 3 – 5, and 20 matched hypertensive controls were recruited. Participants with CKD had lower ascorbic acid, higher TAP and ADMA, together with higher augmentation index and pulse wave velocity. There was no difference in baseline flow mediated dilatation (FMD) between groups. Intravenous ascorbic acid increased TAP and O2-, and reduced central BP and augmentation index in both groups, and lowered ADMA in the CKD group only. No effect on FMD was observed. The effects of ascorbic acid on kidney function was then investigated, however this was hindered by the inherent drawbacks of existing methods of non-invasively measuring kidney function. Arterial spin labelling MRI is an emerging imaging technique which allows measurement of renal perfusion without administration of an exogenous contrast agent. The technique relies upon application of an inversion pulse to blood within the vasculature proximal to the kidneys, which magnetically labels protons allowing measurement upon transit to the kidney. At the outset of this project local experience using ASL MRI was limited and there ensued a prolonged pre-clinical phase of testing with the aim of optimising imaging strategy. A study was then designed to investigate the repeatability of ASL MRI in a group of 12 healthy volunteers with normal renal function. The measured T1 longitudinal relaxation times and ASL MRI perfusion values were in keeping with those found in the literature; T1 time was 1376 ms in the cortex and 1491 ms in the whole kidney ROI, whilst perfusion was 321 mL/min/100g in the cortex, and 228 mL/min/100g in the whole kidney ROI. There was good reproducibility demonstrated on Bland Altman analysis, with a CVws was 9.2% for cortical perfusion and 7.1% for whole kidney perfusion. Subsequently, in a study of 17 patients with CKD and 24 healthy volunteers, the effects of ascorbic acid on renal perfusion was investigated. Although no change in renal perfusion was found following ascorbic acid, it was found that ASL MRI demonstrated significant differences between those with normal renal function and participants with CKD stages 3 – 5, with increased cortical and whole kidney T1, and reduced cortical and whole kidney perfusion. Interestingly, absolute perfusion showed a weak but significant correlation with progression of kidney disease over the preceding year. Ascorbic acid was therefore shown to have a significant effect on vascular biology both in CKD and in those with normal renal function, and to reduce ADMA only in patients with CKD. ASL MRI has shown promise as a non-invasive investigation of renal function and as a biomarker to identify individuals at high risk of progressive renal impairment

Book of abstracts of the 10th International Chemical and Biological Engineering Conference: CHEMPOR 2008

This book contains the extended abstracts presented at the 10th International Chemical and Biological Engineering Conference - CHEMPOR 2008, held in Braga, Portugal, over 3 days, from the 4th to the 6th of September, 2008. Previous editions took place in Lisboa (1975, 1889, 1998), Braga (1978), Póvoa de Varzim (1981), Coimbra (1985, 2005), Porto (1993), and Aveiro (2001). The conference was jointly organized by the University of Minho, “Ordem dos Engenheiros”, and the IBB - Institute for Biotechnology and Bioengineering with the usual support of the “Sociedade Portuguesa de Química” and, by the first time, of the “Sociedade Portuguesa de Biotecnologia”. Thirty years elapsed since CHEMPOR was held at the University of Minho, organized by T.R. Bott, D. Allen, A. Bridgwater, J.J.B. Romero, L.J.S. Soares and J.D.R.S. Pinheiro. We are fortunate to have Profs. Bott, Soares and Pinheiro in the Honor Committee of this 10th edition, under the high Patronage of his Excellency the President of the Portuguese Republic, Prof. Aníbal Cavaco Silva. The opening ceremony will confer Prof. Bott with a “Long Term Achievement” award acknowledging the important contribution Prof. Bott brought along more than 30 years to the development of the Chemical Engineering science, to the launch of CHEMPOR series and specially to the University of Minho. Prof. Bott’s inaugural lecture will address the importance of effective energy management in processing operations, particularly in the effectiveness of heat recovery and the associated reduction in greenhouse gas emission from combustion processes. The CHEMPOR series traditionally brings together both young and established researchers and end users to discuss recent developments in different areas of Chemical Engineering. The scope of this edition is broadening out by including the Biological Engineering research. One of the major core areas of the conference program is life quality, due to the importance that Chemical and Biological Engineering plays in this area. “Integration of Life Sciences & Engineering” and “Sustainable Process-Product Development through Green Chemistry” are two of the leading themes with papers addressing such important issues. This is complemented with additional leading themes including “Advancing the Chemical and Biological Engineering Fundamentals”, “Multi-Scale and/or Multi-Disciplinary Approach to Process-Product Innovation”, “Systematic Methods and Tools for Managing the Complexity”, and “Educating Chemical and Biological Engineers for Coming Challenges” which define the extended abstracts arrangements along this book. A total of 516 extended abstracts are included in the book, consisting of 7 invited lecturers, 15 keynote, 105 short oral presentations given in 5 parallel sessions, along with 6 slots for viewing 389 poster presentations. Full papers are jointly included in the companion Proceedings in CD-ROM. All papers have been reviewed and we are grateful to the members of scientific and organizing committees for their evaluations. It was an intensive task since 610 submitted abstracts from 45 countries were received. It has been an honor for us to contribute to setting up CHEMPOR 2008 during almost two years. We wish to thank the authors who have contributed to yield a high scientific standard to the program. We are thankful to the sponsors who have contributed decisively to this event. We also extend our gratefulness to all those who, through their dedicated efforts, have assisted us in this task. On behalf of the Scientific and Organizing Committees we wish you that together with an interesting reading, the scientific program and the social moments organized will be memorable for all.Fundação para a Ciência e a Tecnologia (FCT

New magnetic stimulation routes with magnetic nanoparticles from process intensification in chemical engineering

Tableau d’honneur de la Faculté des études supérieures et postdoctorales, 2012-2013.Les nanoparticules magnétiques (NPM) suscitent un vif intérêt dans plusieurs branches de l’ingénierie et de la recherche. En effet, la taille de ces dernières ainsi que leur propriétés magnétiques lorsqu’en suspension permettent leur manipulation à distance en utilisant des champs magnétiques externes appropriés. Cela ouvre la voie à l’activation de fonctionnalités supplémentaires lorsqu’ancrées à des catalyseurs métalliques, des enzymes ou des agents thérapeutiques. Conséquemment, les NPM ont été impliquées au sein de plusieurs applications dans lesquelles le mélange à l’échelle microscopique est une problématique importante, par exemple dans les réactions catalytiques, la séparation et l’administration de médicaments. Le présent travail de thèse explore l’utilisation de NPM en tant que dispositifs nanométriques pour manipuler le mélange à l’échelle microscopique lorsque le système complet est soumis à des champs magnétiques. Toutes les expérimentations ont été menées à l’intérieur d’un électro-aimant à bobines tubulaire statique possédant deux pôles et trois phases. Ce dernier génère des champs magnétiques rotatifs uniformes (CMR), des champs magnétiques oscillatoires (CMO) ainsi que des champs magnétiques stationnaires (CMS). En premier lieu, une technique de mélange dans laquelle un CMR transforme des NPM en agitateurs nanométriques créant de petits tourbillons dans la phase liquide est présentée. L’utilisation de cette technique permet l’augmentation du coefficient de diffusion de l’eau quiescente dans une cellule de diffusion statique jusqu’à 200 fois. Les études systématiques des paramètres d’opération révèlent que l’ampleur de l’augmentation dépend de la fraction volumique en NPM ainsi que de la force et de la fréquence du champ magnétique. En second lieu, un écoulement convectif est utilisé afin de comprendre l’effet du couple hydrodynamique sur le comportement des NPM en champs magnétiques. Des tests de distribution de temps de séjour par impulsion sont effectués avec et sans champ magnétique dans le but d’examiner la dispersion axiale d’un écoulement laminaire de Poiseuille à l’intérieur d’un tube capillaire (Tests de dispersion de Taylor). Les résultats obtenus démontrent que le mélange latéral au long du tube est favorisé en présence de NPM et d’un champ magnétique. De plus, l’effet hydrodynamique observé de ce mélange latéral sur le profil de vitesse laminaire est interprété comme provenant d’une approche d’un profil de vitesse plat similaire à celui d’un écoulement piston. À l’aide de la même technique, l’effet des CMO et des CMS sur la dispersion de Taylor et sur le profil de vitesse laminaire est aussi examiné en écoulement capillaire. Alors que les CMO n’induisent pas de mélange nano-convectif dans le capillaire et ont un impact négligeable sur la dispersion axiale, les CMS pour leur part, détériorent le mélange latéral du traceur et créent des profils de vitesse déviant de la forme parabolique vers une forme plus saillie. Une discussion détaillée de la vorticité du fluide en fonction de l’orientation du champ magnétique est aussi présentée. Finalement, un écoulement multiphasique est étudié en ciblant le transfert de matière gaz-liquide entre des bulles de Taylor d’oxygène et la phase liquide, composée d’une solution diluée de NPM, à l’intérieur de tubes capillaires soumis à des CMR, des CMO et des CMS. Les résultats indiquent que les NPM qui tournent sous l’action d’un CMR améliorent le mélange dans le film lubrificateur qui entoure les bulles de Taylor comme cela est révélé par une augmentation mesurable du kLa. À l’opposé, les CMS immobilisent les NPM, menant à des taux de transfert de matière systématiquement plus faibles alors que les CMO n’ont pas d’effet détectable sur le coefficient de transfert de matière. Par ailleurs, l’interaction entre le couple magnétique et le couple hydrodynamique nécessaire pour dominer la direction de rotation des NPM est tirée de ces résultats.Magnetic nanoparticles (MNPs) have attracted significant interest in diverse areas of engineering and research. Particle size and magnetic properties of suspended MNPs in a suspension allow their manipulation at a distance using appropriate external magnetic fields. In particular by enabling additional functionality in forms anchored to metal catalysts, enzymes or therapeutic drug agents. Owing to this feature, MNPs have been involved in many applications where mixing in micro-scale is also a critical issue, e.g., catalytic reaction, separation and drug delivery. This thesis explores MNPs as nano-scale devices to manipulate mixing in micro-scale when the whole system is subject to magnetic fields. All the experiments were performed in tubular two-pole, three-phase stator winding magnet, generating uniform rotating magnetic field (RMF), oscillating magnetic field (OMF) and stationary magnetic field (SMF). Initially, we present a mixing technique in which a RMF converts MNPs into nano-stirrers generating small vortices in liquid phase. Using this technique, self-diffusion coefficient of motionless water in a static diffusion cell was intensified up to 200 folds. Systematic studies of operating parameters revealed that the extent of enhancement depends on MNP volume fraction, and strength and frequency in magnetic field. In order to understand the effect of hydrodynamic torque on the MNPs behavior under magnetic fields, convective flow was also included. As such, axial dispersion of pressure-driven laminar Poiseuille flows in a capillary tube (Taylor dispersion test) was examined through a series of impulse (residence time distribution) RTD tests with and without RMF. This resulted in lateral mixing along the channel that was promoted relative to that in absence of MNPs or magnetic field. Moreover, we interpreted the observed hydrodynamic effects of such lateral mixing on laminar velocity profile as resulting from an approach to plug flow-like flat velocity profile. Using the same technique, the effect of OMF and SMF on Taylor dispersion and laminar velocity profile was examined in capillary flows. OMF did not induce nano-convective mixing in the capillary and had negligible impact on axial dispersion. On the contrary, SMF deteriorated lateral mixing of solute tracer and led to velocity profiles deviating from parabolic shape towards more protruded ones. A detailed discussion of magnetic field orientation versus fluid vorticity vector was presented. Finally a multiphase flow case concerned gas-liquid mass transfer from oxygen Taylor bubbles to the liquid in capillaries which was studied using dilute concentration of MNPs as the liquid phase under RMF, OMF and SMF. Experimental results implied that spinning MNPs under RMF improved mixing in the lubricating film that surrounds Taylor bubbles which reflected in a measurable enhancement of kLa. On the contrary, SMF pinned MNPs leading to systematically degraded gas-liquid mass transfer rates whereas axial oscillating magnetic field had no detectable effects on the mass transfer coefficient. Moreover, interaction between magnetic torque and hydrodynamic torque to dominate MNP spin direction was conceived from these results

Magnetic Resonance Imaging Studies of Angiogenesis and Stem Cell Implantations in Rodent Models of Cerebral Lesions

Molecular biology and stem cell research have had an immense impact on our understanding of neurological diseases, for which little or no therapeutic options exist today. Manipulation of the underlying disease-specific molecular and cellular events promises more efficient therapy. Angiogenesis, i.e. the regrowth of new vessels from an existing vascular network, has been identified as a key contributor for the progression of tumor and, more recently, for regeneration after stroke. Donation of stem cells has proved beneficial to treat cerebral lesions. However, before angiogenesis-targeted and stem cell therapies can safely be used in patients, underlying biological processes need to be better understood in animal models. Noninvasive imaging is essential in order to follow biological processes or stem cell fate in both space and time. We optimized steady state contrast enhanced magnetic resonance imaging (SSCE MRI) to monitor vascular changes in rodent models of tumor and stroke. A modification of mathematical modeling of MR signal from the vascular network allowed for the first time simultaneous measurements of relaxation time T2 and SSCE MRI derived blood volume, vessel size, and vessel density. Limitations of SSCE MRI in tissues with high blood volume and non-cylindrically shaped vessels were explored. SSCE MRI detected angiogenesis and response to anti-angiogenic treatment in two rodent tumor models. In both tumor models, reduction of blood volume in small vessels and a shift towards larger vessels was observed upon treatment. After stroke, decreased vessel density and increased vessel size was found, which was most pronounced one week after the infarct. This is in agreement with two initial, recently published clinical studies. Overall, very little signs of angiogenesis were found. Furthermore, superparamagnetic iron oxide (SPIO) labels were used to study neural stem cells (NSCs) in vivo with MRI. SPIO labeling revealed a decrease in volume of intracerebral grafts over 4 months, assessed by T2* weighted MRI. Since SPIO labels are challenging to quantify and their MR contrast can easily be confounded, we explored the potential of in vivo 19F MRI of 19F labeled NSCs. Hardware was developed for in vitro and in vivo 19F MRI. NSCs were labeled with little effect on cell function and in vivo detection limits were determined at ~10,000 cells within 1 h imaging time. A correction for the inhomogeneous magnetic field profile of surface coils was validated in vitro and applied for both sensitive and quantitative in vivo cell imaging. As external MRI labels do not provide information on NSC function we combined 19F MRI with bioluminescence imaging (BLI). The BLI signal allowed quantification of viable cells whereas 19F MRI provided graft location and density in 3D over 4 weeks both in the healthy and stroke brain. A massive decrease in number of viable cells was detected independent of the microenvironment. This indicates that functional recovery reported in many studies of NSC implantation after stroke, is rather due to release of factors by NSCs than direct tissue replacement. In light of these indirect effects, combination of the imaging methods developed in this dissertation with other functional and structural imaging methods is suggested in order to further elucidate interactions of NSCs with the vasculature