Some aromatic sulphonamide inhibitors of carbonic anhydrase and their use in nuclear medicine

Singh, J.

January 1986

No description available.

572

Cell labelling

Complexes and aggregates of imino-carboxylates

Doble, Dan

January 1998

No description available.

541.38

Using Flow Cytometry to Evaluate the Functionalization and Targeting of Surface Enhanced Raman Scattering Nanoparticles

Mullaithilaga, Nisa

15 November 2013

The effective diagnosis of leukemia subtypes requires the detection of multiple cell surface markers. Current methods of detection use mostly fluorophores, which are limited by their large spectral bandwidths, photobleaching, and incompatibility with histological stains used for morphological assessments. Antibody-conjugated Surface enhanced Raman scattering (SERS) nanoparticles is an alternative tool that overcomes these limitations. A current drawback of SERS is the lack of available tools to analyze the bioconjugation of antibodies to nanoparticles following EDC/sulfo-NHS cross-linking, which produces inconsistent results and determines the efficacy of SERS probe targeting. This study uses the flow cytometry approach to evaluate SERS particles by incorporating FITC and DyLight650 secondary antibodies. Flow cytometry was also used to assess targeting of particles to markers on LY10 cells and CLL cells and to detect SERS signals by inserting a 710 BP 10nm FWHM filter specific for MGITC.

Flow cytometry

Surface Enhanced Raman Scattering

Diagnostics

Leukemia

Cell labelling

Raman microscopy

0306

0379

0719

0760

0494

Using Flow Cytometry to Evaluate the Functionalization and Targeting of Surface Enhanced Raman Scattering Nanoparticles

Mullaithilaga, Nisa

15 November 2013

The effective diagnosis of leukemia subtypes requires the detection of multiple cell surface markers. Current methods of detection use mostly fluorophores, which are limited by their large spectral bandwidths, photobleaching, and incompatibility with histological stains used for morphological assessments. Antibody-conjugated Surface enhanced Raman scattering (SERS) nanoparticles is an alternative tool that overcomes these limitations. A current drawback of SERS is the lack of available tools to analyze the bioconjugation of antibodies to nanoparticles following EDC/sulfo-NHS cross-linking, which produces inconsistent results and determines the efficacy of SERS probe targeting. This study uses the flow cytometry approach to evaluate SERS particles by incorporating FITC and DyLight650 secondary antibodies. Flow cytometry was also used to assess targeting of particles to markers on LY10 cells and CLL cells and to detect SERS signals by inserting a 710 BP 10nm FWHM filter specific for MGITC.

Flow cytometry

Surface Enhanced Raman Scattering

Diagnostics

Leukemia

Cell labelling

Raman microscopy

0306

0379

0719

0760

0494

Étude de l'activité spontanée dans la moëlle épinière de l'oppossum Monodelphis domestica en développement

Lavallée, Annie

January 2008

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.

Développement

Development

Activité spontanée

Spontaneous activity

Comportements

Behaviour

Locomotion

Locomotion

Mammifères

Mammals

Neuroanatomie

Neuroanatomy

Imagerie calcique

Calcium imaging

Marquage cellulaire

Cell labelling

Sulforhodamine-101

Sulforhodamine-101

Détection et suivi en IRM du macrophage polarisé et marqué aux nanoparticules de fer dans l’athérosclérose et l’imagerie de l’inflammation / MRI Detection and tracking of M1 polarized macrophage labelled with iron nanoparticles for atherosclerosis and inflammation imaging

Bessaad, Mohamed El Amine

24 March 2010

L’athérosclérose est une maladie inflammatoire, caractérisée par une accumulation lipidique et cellulaire, dont le macrophage est l’acteur principal. Dans l’athérosclérose, le macrophage sécrète des cytokines qui favorisent le chimiotactisme et donc la migration et l’internalisation des cellules immunitaires, accentuant le processus pro-inflammatoire et accélérant l’évolution des plaques athéromateuses et leur instabilité jusqu’à éventuellement la rupture et/ou la formation de thrombus. Il est donc important de développer une technique d’imagerie cellulaire permettant de visualiser les macrophages et leur migration dans divers contextes pathologiques pour mieux comprendre leur implication, permettre le suivi thérapeutique et probablement leur utilisation dans la thérapie vectorisée. Le but de ce travail vise principalement à marquer aux nanoparticules de fer des macrophages activés de manière classiques (macrophages dits « M1 ») pour l’évaluation du statut inflammatoire dans un premier temps au sein des plaques d’athérome, et la visualisation de la dynamique de leur recrutement par IRM. Dans un deuxième temps, la méthode est exploitée pour montrer in vivo l’effet d’un traitement permettant de diminuer l’inflammation dans la plaque chez des souris invalidées pour le gène de l’apolipoprotéine E (ApoE-/-). Enfin, l’utilisation du protocole de marquage des macrophages M1 et leur suivi par IRM sont appliqués au diagnostic par imagerie d’une inflammation transitoire et circonscrite au poumon, induite par les lipopolysaccharides (LPS). En conclusion, le marquage des monocytes dirigés vers la voie M1 pour leur détection par IRM représente une méthode solide pour étudier différents phénomènes immunologiques en particulier le processus inflammatoire, et peut être un outil ou une approche de vectorisation permettant le suivi thérapeutique, cellulaire ou génique / Atherosclerosis is an inflammatory disease characterized by vessel wall lipids and cells accumulation, for which the macrophage acts as a central actor. In atherosclerosis the macrophage secretes cytokines that promote chemotaxis and thus migration and internalization of immune cells. This phenomenon emphasizes pro-inflammatory processes and accelerates the development of atherosclerotic plaque unstability to potentially its rupture with or without thrombus formation. It is therefore important to develop a technique for cell imaging to visualize macrophages and their migration in various pathological contexts to better understand their involvement, to allow therapeutic drug monitoring and probably their use in vectorized therapy. The aim of this work is mainly to label activated macrophages in classical way (macrophages called "M1") by iron nanoparticles, first to evaluate the inflammatory status within atherosclerotic plaques, and visualize their dynamic recruitment by MRI. In a second step, the method is used to show in vivo the effect of a treatment to reduce inflammation in the plaque, in mice invalidated for the gene for apolipoprotein E (ApoE-/ -). Finally, the protocol for M1 macrophages labelling and MRI tracking, was used for diagnostic imaging of a transient inflammation confined to the lung induced by lipopolysaccharide (LPS). In conclusion, the labelling of monocytes headed towards M1 polarization for their detection by MRI is a robust method to study various immunological phenomena in particular the inflammatory process, and can be an approach to vectorization and monitoring for gene or cell therapy

Inflammation

Macrophage

Athérosclérose

IRM

Marquage cellulaire

Activation pro-inflammatoire

Cytokines

Nanoparticules

Inflammation

Macrophage

Atherosclerosis

MRI

Cell labelling

Proinflammatory activation

Cytokines

Nanoparticles

616.136

Étude de l'activité spontanée dans la moëlle épinière de l'oppossum Monodelphis domestica en développement

Lavallée, Annie

January 2008

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal

Développement

Development

Activité spontanée

Spontaneous activity

Comportements

Behaviour

Locomotion

Locomotion

Mammifères

Mammals

Neuroanatomie

Neuroanatomy

Imagerie calcique

Calcium imaging

Marquage cellulaire

Cell labelling

Sulforhodamine-101

Sulforhodamine-101

The early development of the inner ear: the role of notch and fgf pathways in aerly otic neural versus non-neural patterning

Abelló Sumpsi, Gina

25 January 2008

Otic neuronal precursors are specified in the otic placode but interestingly do so only in the anterior domain of the otic placode, the proneural domain. In the present study, we have explored why only this territory has the competence to undergo neurogenesis, this means the early events of otic proneural regionalization and neural commitment. The proneural and non-neural domains presented complementary gene expression patterns of transcription factors and members of the Notch pathway. Overall, we propose that proneural character is acquired in the anterior territory by the action of localized ectodermal FGF8-FGF10 signaling that enhances Sox3 function. FGF signals through Sox3 activity would be essential for the specification of the proneural domain versus a non-neural territory, while Notch would be involved in refining this early regionalization. / Els precursors neurals de la oïda són especificats dins un subdomini de la placoda acústica, el domini proneural. En aquesta tesis doctoral, s'ha explorat la raó per la qual la competència neural només és adquirida en aquest subdomini. Els dominis neural i no-neural del territori presenten dominis d'expressió genètica complementaris. Aquest treball proposa que el caràcter proneural és adquirit en el subdomini anterior del territori per l'acció de FGF8 i FGF10 localitzats en l�ectoderm �tic que promouen l�acci� de Sox3. De manera que, les senyals FGF i l�activitat Sox3 s�n essencials per l�especificaci� del domini proneural, mentre que la via Notch �s necess�ria per refinar la regionalitzaci� final entre un domini neural complementari a un domini no-neural.

ratolí

peix

pollet

embrió

cultius d'embrió

electroporació

marcatge cellular

Sox3

resctricció de llinatges

Notch

FGF

territori no-neural

neurona

territori proneural

regionalització

oída

Desenvolupament

lineage restrictions

embryo culturing

cell labelling

electroporation

DiI

mouse

zebrafish

chick

embryo

otic placode

neurogenesis

DAPT

Sox3

patterning

signaling

FGF

proneural

Notch

Development

57

61