Ferramenta biofotônica integrada para manipulações e microscopias confocais / Integrates biophotonic tool for manipulations and confocal microscopies

Thomaz, André Alexandre de, 1980-

21 December 2007

Orientador: Carlos Lenz Cesar / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Fisica Gleb Wataghin / Made available in DSpace on 2018-08-11T10:58:51Z (GMT). No. of bitstreams: 1 Thomaz_AndreAlexandrede_M.pdf: 10062018 bytes, checksum: 1e19c55cb5a4e709c2015e2d90f3ac13 (MD5) Previous issue date: 2007 / Resumo: A pesquisa em fotônica biomedica está claramente tomando a direção do entendimento de processos biológicos a nível celular. A resolução necessária para atingir esse objetivo requer praticamente ferramentas fotônicas. Contudo, uma integração de diferentes ferramentes fotônicas e uma aproximação funcional serão necessárias para acessar os processos biomecânicos e bioquímicos celulares. Deste modo nós podemos observar eventos bioquímicos disparados mecanicamente ou eventos mecânicos disparados bioquimicamente, ou até mesmo observar simultâneamente eventos biomecânicos e bioquímicos disparados por outros meios, entre outros, eletricamente. Uma das grandes vantagens das ferramentas fotônicas é a sua facilidade de integração. Nós desenvolvemos uma ferramenta integrada incorporando pinça óptica simples com Microscopia Confocal "Single-photon" e Multifóton. O sistema consegue realizar microscopias de fluorescência excitada pela absorção de dois fótons e geração de segundo harmônico em conjunto com manipulações ópticas. Medidas de força, elasticidade e viscosidade de membranes esticadas podem ser monitoradas em tempo real pelas microscopias confocais, bem como protozoários capturados opticamente, como, por exemplo, Trypanosoma cruzi. Nós mostraremos vários exemplos do uso de tal ferramenta integrada e seu potencial para observar processos mecânicos e bioquímicos a nível celular / Abstract: The research in biomedical photonics is clearly evolving in the direction of the understanding of biological processes at the cell level. The spatial resolution to accomplish this task practically requires photonics tools. However, an integration of different photonic tools and a multimodal and functional approach will be necessary to access the mechanical and biochemical cell processes. This way we can observe mechanicaly triggered biochemical events or biochemicaly triggered mechanical events, or even observe simultaneously mechanical and biochemical events triggered by other means, e.g. electricaly. One great advantage of the photonic tools is its easiness for integration. Therefore, we developed such integrated tool by incorporating single Optical Tweezers with Confocal Single and Multiphoton Microscopies. This system can perform 2-photon excited fluorescence and Second Harmonic Generation microscopies together with optical manipulations. Force, elasticity and viscosity measurements of stretched membranes can be followed by real time confocal microscopies. Also opticaly trapped living protozoas, such as Trypanosoma cruzi. Integration with CARS microscopy is under way. We will show several examples of the use of such integrated instrument and its potential to observe mechanical and biochemical processes at cell level / Mestrado / Física / Mestre em Física

Microscopia confocal

Microscopia confocal multifóton

Pinças óticas

Imagens óticas

Confocal microscopy

Multiphoton confocal microscopy

Second harmonic generation microscopy

Optical tweezers

Optical images

Imaging of Targeted Lipid Microbubbles using Third Harmonic Generation Microscopy

Harpel, Kaitlin Gillett

January 2016

The use of receptor-targeted lipid microbubbles imaged by ultrasound is an innovative method of detecting and localizing disease. However, since ultrasound requires a medium between the transducer and the object being imaged, it is impractical to apply to an exposed surface in a surgical setting where sterile fields need be maintained. Additionally, the application of an ultrasound gel to the imaging surface may cause the bubbles to collapse. Multiphoton microscopy (MPM) is an emerging tool for accurate imaging of tissues and cells with high resolution and contrast. We have recently developed a novel method for detecting targeted microbubble adherence to the upregulated plectin-receptor on pancreatic tumor cells using MPM. Specifically, the third-harmonic generation response can be used to detect bound microbubbles to various cell types presenting MPM as an alternative and useful imaging method. This is an interesting technique that can potentially be translated as a diagnostic tool for the early detection of cancer and inflammatory disorders.

microbubbles

multiphoton microscopy

pancreatic cancer

plectin1 receptor

third harmonic generation

Biomedical Engineering

confocal microscopy

Phase-Change Contrast Agents for Targeting and Delivery

Hadinger, Kyle

January 2016

Phase-change contrast agents (PCCAs) are an innovative form of imaging agent with practical applications in both the research and clinical settings. PCCAs are derived from gaseous microbubbles, which are able to act as targeted-contrast agents through conjugation of a ligand that is selective for an overexpressed receptor or biomarker in a given disease. Gaseous microbubbles can be condensed to liquid phase nanodroplets, which should be sufficiently small to extravasate into cells and/or tissues given their size and stability. Once liquid nanodroplets have internalized within a given tissue, they can be "activated" back into gaseous microbubbles with ultrasound at clinically used frequencies and energy outputs. This is purposeful as microbubbles provide much greater ultrasound reflectivity than nanodroplets. In this study, PCCAs and/or microbubbles act as a targeting agent in multiple scenarios. The projects in this study include- examination of binding and internalization of targeted PCCAs with different gaseous cores within MDA-MB-231 breast cancer cells, vaporization of liquid phase nanodroplets through application of acoustic energy via focused ultrasound (FUS), and targeting vulnerable plaque in the heart with different types of targeted microbubbles under varying shear-stresses.

Confocal Microscopy

Microbubbles

Phase-Change Contrast Agents

Ultrasound

Vulnerable Plaque

Biomedical Engineering

Breast Cancer

Microelectromechanical handheld laser-scanning confocal microscope: application to breast cancer imaging

Kumar, Karthik

15 February 2010

Demographic data indicate that 60% of 6.7 million annual global cancer mortalities and 54% of 10.8 million new patients are in developing nations, unable or unwilling to avail of invasive screening tests that are the current norm. For most cancers, survival rate is strongly dependent on early detection, highlighting the need for improved screening methods. Studies have shown that cancers can be identified based on distinct sub-cellular morphological features and expression levels of specific molecular markers. Since 85% of cancers are known to originate in the epithelium, portable in vivo imaging techniques providing sub-cellular detail in tissue up to depths of 250 μm could help improve access to biopsy-free examination in low-infrastructure environments. The resultant early detection could dramatically improve patient prognosis, while reducing screening costs, treatment delay, and occurrences of unnecessary and potentially harmful medication. This dissertation investigates handheld instrumentation for laser-scanning confocal microscopy (LSCM) and its applicability to breast cancer detection and subsequent image-guided management. LSCM allows high-resolution mapping of spatial variations in refractive index or tumor marker expression within a single cell layer situated few hundred micrometers beneath the tissue surface. The main challenge facing miniaturization lies in the mechanism of beam deflection across the sample. The first part of the dissertation presents a fast, large-angle, high-reflectivity two-axis vertical comb driven silicon micromirror fabricated by a novel method compatible with complementary metal-oxide-semiconductor processing employed in the semiconductor industry. The process enables integration of rotation sensors on the chip to adaptively correct for aberrations in beam scanning while significantly reducing fabrication costs and barriers to market acceptance. The second part of the dissertation explores the integration of this micromirror with other optical and electronic components into a handheld laser-scanning confocal microscope. Applicability of the probe to epithelial breast cancer screening via reflectance and fluorescence imaging is investigated. Finally, enhanced imaging modalities based on the micromirror are presented. 3D cellular-level in vivo imaging via rapid swept-source optical coherence tomography is demonstrated. A method for “objective-less” microendoscopy, potentially resulting in substantially reduced probe dimensions, employing reflective binary-phase Fresnel zone plates monolithically integrated on the surface of the micromirror is presented. / text

Breast cancer

Cancer screening

Breast cancer imaging

Early detection

Laser-scanning confocal microscopy

Micromirrors

Microendoscopy

Integrated Multi-Spectral Fluorescence Confocal Microendoscope and Spectral-Domain Optical Coherence Tomography Imaging System for Tissue Screening

Makhlouf, Houssine

January 2011

A multi-modality imaging system intended for clinical utilization has been developed. It is constructed around an existing fiber-bundle-based fluorescence confocal microendoscope. Additional imaging modalities have been implemented to expand the capabilities of the system and improve the accuracy of disease diagnosis. A multi-spectral mode of operation is one such modality. It acquires fluorescence images of a biological sample across a spectral range of sensitivity and explores the collected image data at any specified wavelength within that spectral range. Cellular structures can be differentiated according to their spectral properties. The relative distribution and concentration of the different cellular structures can potentially provide useful pathologic information about the imaged tissue. A spectral-domain optical coherence tomography (SDOCT) modality is another imaging technique integrated into the system. It provides a cross-sectional imaging perspective that is comparable to microscopic images obtained from histology slides and complementary to the en face view obtained from the confocal imaging modality. The imaging system uses a parallelized architecture (fiber-optic bundle, line of illumination) to increase the data acquisition speed. A one-dimensional scan is needed to capture 2D images in the confocal modality or a 3D data cube (two spatial dimensions and one spectral dimension) in the multi-spectral mode of operation. No scanning is required to capture a 2D OCT image. The fiber-bundle design is particularly critical for the SDOCT modality as it paves the way to novel fast endoscopic OCT imaging that has a high potential for translation into the clinic. The integrated multi-modality imaging system can readily switch between different imaging modalities, which will make it a powerful diagnostic tool in a clinical environment. It can provide valuable information about the morphology, the spectral and biochemical features, and the macroscopic architecture of tissue. It is believed that fast and accurate disease diagnosis can potentially be made based on all these characteristics.

fiber-bundle

fluorescence

optical coherence tomography

spectrometer

Optical Sciences

confocal microscopy

endoscope

Nuclear and Cytoskeletal Prestress Govern the Anisotropic Mechanical Properties of the Nucleus

Macadangdang, Joan Karla

24 September 2012

Physical forces in the cellular microenvironment play an important role in governing cell function. Forces transmitted through the cell cause distinct deformation of the nucleus, and possibly play a role in force-mediated gene expression. The work presented in this thesis drew upon innovative strategies employing simultaneous atomic force and laser-scanning confocal microscopy, as well as parallel optical stretching experiments, to gain unique insights into the response of eukaryotic cell nuclei to external force. Non-destructive approaches confirmed the existence of a clear anisotropy in nuclear mechanical properties, and showed that the nucleus' mechanical response to extracellular forces is differentially governed by both nuclear and cytoskeletal prestress: nuclear prestress regulates shape and anisotropic deformation, whereas cytoskeletal prestress modulates the magnitude and degree of deformation. Importantly, the anisotropic mechanical response was conserved among diverse differentiated cell types from multiple species, suggesting that nuclear mechanical anisotropy plays an important role in cell function.

nucleus

eukaryotic cell

atomic force microscopy

confocal microscopy

optical stretcher

cytoskeleton

force transduction

anisotropy

Real-Time Live Confocal Fluorescence Microscopy as a New Tool for Assessing Platelet Vitality

Hermann, Martin, Nussbaumer, Oliver, Knöfler, Ralf, Hengster, Paul, Nussbaumer, Walter, Streif, Werner

05 March 2014

Background: Assessment of platelet vitality is important for patients presenting with inherited or acquired disorders of platelet function and for quality assessment of platelet concentrates. Methods: Herein we combined live stains with intra-vital confocal fluorescence microscopy in order to obtain an imaging method that allows fast and accurate assessment of platelet vitality. Three fluorescent dyes, FITC-coupled wheat germ agglutinin (WGA), tetramethylrhodamine methyl ester perchlorate (TMRM) and acetoxymethylester (Rhod-2), were used to assess platelet morphology, mitochondrial activity and intra-platelet calcium levels. Microscopy was performed with a microlens-enhanced Nipkow spinning disk-based system allowing live confocal imaging. Results: Comparison of ten samples of donor platelets collected before apheresis and platelets collected on days 5 and 7 of storage showed an increase in the percentage of Rhod-2positive platelets from 3.6 to 47 and finally to 71%. Mitochondrial potential was demonstrated in 95.4% of donor platelets and in 92.5% of platelets stored for 7 days. Conclusion: Such fast and accurate visualization of known key parameters of platelet function could be of relevance for studies addressing the quality of platelets after storage and additional manipulation, such as pathogen inactivation, as well as for the analysis of inherited platelet function disorders. / Hintergrund: Die Vitalitätsbestimmung von Blutplättchen ist sowohl für die Analyse angeborener Plättchendefekte als auch für die Qualitätsbestimmung von Plättchenkonzentraten von zentraler Bedeutung. Methoden: In der vorliegenden Arbeit stellen wir eine Methode vor, die mittels einer Kombination von Vitalfarbstoffen und konfokaler «Real time»-Mikroskopie neue Einblicke in die Vitalitätsbestimmung lebender Plättchen ermöglicht. Mittels der Zugabe von FITC-gekoppeltem Weizenkeimlektin (WGA), Tetramethylrhodamin-Methylesterperchlorat (TMRM) und Acetoxymethylester (Rhod-2) wurde bei lebenden Blutplättchen deren Morphologie, mitochondriale Aktivität und Veränderungen im Calcium-Haushalt im Rahmen der Lagerung analysiert. Für die Mikroskopie wurde ein Nipkow-System gewählt, das eine konfokale Mikroskopie lebender Zellen ermöglicht. Ergebnisse: Der Vergleich von 10 humanen Blutplättchenproben zu Beginn bzw. nach 5 und 7 Tagen Lagerung zeigte einen Anstieg der Rhod-2-positiven Plättchen von 3,6 über 47 auf 71%. Die Anzahl der Blutplättchen mit TMRM-positiven Mitochondrien hingegen lag vor der Lagerung bei 95,4% und nach den 7 Tagen Lagerung bei 92,5%. Schlussfolgerung: Die hier vorgestellte Methodik der Bildgebung zur Bestimmung vitaler Parameter von Blutplättchen eignet sich als ergänzende Analysemodalität für eine bessere Bestimmung der Blutplättchenqualität. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Konfokale Mikroskopie

Mitochondrienfunktionstests

Blutplättchen

Confocal microscopy

Mitochondria function tests

Blood platelets

ddc:610

rvk:XA 10000

Aberration free extended depth of field microscopy

Botcherby, Edward J.

January 2007

In recent years, the confocal and two photon microscopes have become ubiquitous tools in life science laboratories. The reason for this is that both these systems can acquire three dimensional image data from biological specimens. Specifically, this is done by acquiring a series of two-dimensional images from a set of equally spaced planes within the specimen. The resulting image stack can be manipulated and displayed on a computer to reveal a wealth of information. These systems can also be used in time lapse studies to monitor the dynamical behaviour of specimens by recording a number of image stacks at a sequence of time points. The time resolution in this situation is, however, limited by the maximum speed at which each constituent image stack can be acquired. Various techniques have emerged to speed up image acquisition and in most practical implementations a single, in-focus, image can be acquired very quickly. However, the real bottleneck in three dimensional imaging is the process of refocusing the system to image different planes. This is commonly done by physically changing the distance between the specimen and imaging lens, which is a relatively slow process. It is clear with the ever-increasing need to image biologically relevant specimens quickly that the speed limitation imposed by the refocusing process must be overcome. This thesis concerns the acquisition of data from a range of specimen depths without requiring the specimen to be moved. A new technique is demonstrated for two photon microscopy that enables data from a whole range of specimen depths to be acquired simultaneously so that a single two dimensional scan records extended depth of field image data directly. This circumvents the need to acquire a full three dimensional image stack and hence leads to a significant improvement in the temporal resolution for acquiring such data by more than an order of magnitude. In the remainder of this thesis, a new microscope architecture is presented that enables scanning to be carried out in three dimensions at high speed without moving the objective lens or specimen. Aberrations introduced by the objective lens are compensated by the introduction of an equal and opposite aberration with a second lens within the system enabling diffraction limited performance over a large range of specimen depths. Focusing is achieved by moving a very small mirror, allowing axial scan rates of several kHz; an improvement of some two orders of magnitude. This approach is extremely general and can be applied to any form of optical microscope with the very great advantage that the specimen is not disturbed. This technique is developed theoretically and experimental results are shown that demonstrate its potential application to a broad range of sectioning methods in microscopy.

502.82

Organisation du phloème et analyse fonctionnelle des protéines PP2 / Phloem organization and functional analysis of PP2 proteins

Cayla, Thibaud

21 December 2012

Le phloème est un tissu complexe composé de plusieurs types cellulaires, dont les cellules compagnes et les tubes criblés. Il permet le transport et l’allocation à longue distance de nombreux métabolites et de macromolécules. Il existe dans les tubes criblés des structures très spécifiques dont la fonction est inconnue. Par exemple le rôle des protéines phloémiennes PP2 (Phloem Protein 2) qui ont été de longue date décrite dans les tubes criblés, reste à définir. Les protéines PP2 présentent une activité de lectine et d’interaction avec des protéines de sève phloémienne, suggérant un rôle dans le transport de macromolécules dans le phloème.Nous avons étudié la fonction de deux membres de la famille, PP2-A1 et PP2-A2, chez l’espèce modèle Arabidopsis thaliana. Plusieurs approches ont été mises en œuvre pour étudier ces protéines ; une approche cytologique, la recherche de partenaire protéiques et la création de lignées dérégulées pour l’expression des gènes PP2. L’étude de la localisation de PP2-A1 avec des étiquettes fluorescentes dérivées de la GFP a été réalisée par microscopie confocale, dans les cellules compagnes et dans les tubes criblés ; elle a montré que cette protéine présente une localisation nucléo- cytoplasmique dans les cellules compagnes tandis qu’elle forme des agrégats fixés dans les tubes criblés. Ceci suggère que PP2-A1 est ancrée dans les tubes criblés, à la membrane plasmique ou à certains organites. Des résultats similaires ont été obtenus pour PP2-A2. Sur la base de cette première étude, nous permettant d’identifier in vivo avec précision les cellules compagnes et les tubes criblés, et en utilisant plusieurs marqueurs subcellulaires fluorescents de référence, nous avons réalisé une cartographie subcellulaire fine des cellules compagnes et des tubes criblés in vivo. Cette approche a permis de décrire in vivo l’organisation subcellulaire de ces cellules. Elle a révélé la présence de nombreux organites présents à la périphérie des tubes criblés et de nature énigmatique, suggérant une activité importante dans ces cellules, en accord avec des données récentes de protéome des tubes criblés. L’étude de lignées surexprimant des versions étiquetées de PP2-A1 et PP2-A2 nous a permis de mettre en évidence un phénotype altéré avec des plantes qui présentent un retard de floraison et une biomasse plus importante. Ces observations suggèrent que PP2-A1 et PP2-A2 pourraient avoir un rôle dans la signalisation à longue distance. Ces travaux, qui illustrent la complexité des cellules du phloème, apportent ainsi des éléments nouveaux sur les voies de signalisation à longue distance utilisées par les végétaux pour coordonner leur croissance et leur développement. / The phloem is a complex tissue, made of several cell types, including companion cells and sieve elements. It plays an important role in long-distance transport and allocation of a number of metabolites and macromolecules. The sieve elements display specific structures yet uncharacterized and of unknown function. For instance the function of the phloem specific PP2 proteins (Phloem Protein 2) that have been described for long in the sieve elements is still unclear. PP2 proteins present lectin activity and bind to phloem sap proteins, suggesting a role in the transport of macromolecules in the phloem. We have investigated the function of two members of this family, PP2-A1 and PP2-A2 in the model species Arabidopsis thaliana. Different approaches have been undertaken to study these proteins: a cytological approach, the research of partners, and the study of downregulated and upregulated lines for the PP2-A1 and PP2-A2 genes. Localization studies of PP2-A1 fused to GFP-derived fluorescent tags have been realized by confocal laser scanning microscopy in the companion cells and the sieve elements; they showed that PP2-A1 presents a nucleocytoplasmic localization in the companion cells, whereas it forms fixed aggregates in the sieve elements. It suggested that PP2-A1 is anchored to the plasma membrane or to organelles inside the sieve elements. Similar results were obtained for PP2-A2. Making use of this study to accurately identify companion cells and sieve elements in vivo, and using additional subcellular fluorescent markers, we realized a fine mapping of companion cells and sieve elements in vivo. This study revealed the presence of numerous organelles of unknown identity at the periphery of the sieve elements, suggesting an important activity in those cells consistent with recent proteomics analysis of the sieve tubes. The study of plants overexpressing tagged versions of PP2-A1 and PP2-A2 enabled to observe an altered phenotype with delayed flowering and increased biomass, suggesting that PP2-A1 and PP2-A2 may play a role in long distance signalling. This work illustrates the complexity of phloem cell organization and functions, bringing new elements on long distance signalling pathway used by the plants to coordinate their growth and development.

Phloème

Cellule compagne

Microscopie confocale

PP2

Tube criblé

Phloem

Companion cell

Confocal microscopy

PP2

Sieve element

Granzyme B-td TOMATO, un nouvel outil fluorescent pour le suivi de la cytolyse chez la souris

Mouchacca, Pierre

16 March 2012

La fonction de cytolyse est un mécanisme majeur des effecteurs du système immunitaire pour éliminer les cellules infectées ou tumorales. Cette fonction associe l'activité de la perforine, qui forme des pores dans la membrane d'une cellule cible, à la sécrétion de protéases: les granzymes. Ces dernières sont des molécules pro-apoptotiques qui induisent la mort de la cellule cible. Les granzymes et en particulier granzyme B ciblent plusieurs voies intracellulaires complémentaires pour assurer l'efficacité de la cytolyse. Or il est difficile d'observer directement la fonction de cytolyse au cours de réponse immunitaire in vivo dans des conditions physiologiques. Dans les travaux présentés dans cette thèse, nous avons développé un nouveau modèle qui permet de suivre la fonction de cytolyse en temps réel par l'expression d'une protéine de fusion fluorescente GZMB-tdTomato. Les résultats obtenus par expression rétrovirale ont montré que la protéine de fusion est correctement exprimée dans les vésicules cytolytiques qui deviennent fluorescentes. Dans un second temps, nous avons réalisé un nouveau modèle murin qui exprime GZMB-tdTomato de manière substituée au GZMB natif par recombinaison homologue (Knock In). Nous avons mis en évidence que la protéine de fusion conserve l'activité catalytique de la protéine native et ses caractéristiques (conditions d'expression, de maturation, de sécrétion et demeure active après le passage dans la cellule cible lors de la cytolyse). En utilisant un modèle murin exprimant un TCR transgénique nous avons pu suivre le déroulement de la fonction de cytolyse de lymphocytes cytotoxiques en temps réel par video microscopies. / Cytolysis is a major function used by the immune system's effectors to kill infected or tumor cells. Cytolysis depends on the pore forming protein perforin and the secretion of proteases of the granzyme family. Granzymes, including granzyme B (GZMB) have pro-apoptotic features and induce target cell death. Several complementary pathways are triggered by granzymes to ensure efficient cytolysis. It remains difficult to directly observe cytolysis during in vivo immune responses under physiological conditions. In this PhD we developed a new model to visualize cytolytic function in real time by expression of a fusion protein: GZMB-tdTomato. Results obtained from retroviral transduction showed that the fusion protein is correctly expressed in cytolytic vesicles, which became fluorescent. We then constructed a new mouse model by homologous recombination (Knock In) that express GZMB-tdTomato substituted for the native GZMB. The fusion protein conserves the catalytic activity of GZMB and its features (expression, maturation, secretion conditions) and remains active after its passage into target cells. Using TCR transgenic OTI cells, we followed the sequence of events of cytolysis from lymphocytes in real time by videomicroscopy. We also observed the cytolytic vesicles relocalization towards the cell contact zone and the death of target cell by cytolysis. Finally, we studied in vivo differentiation of naïve lymphocyte to cytolytic effector cells (the acquisition of cytolysis) and target cell death after bacterial infection.

Cytolyse

Granzyme B

Souris

Knock In

Microscopie confocale

Ctl

Cytolysis

Ctl