Plasmonic laser nanosurgery

Eversole, Daniel Steven

18 November 2013

Plasmonic Laser Nanosurgery (PLN) is a novel photodisruption technique that exploits the large enhancement of ultrafast laser pulses in the near-field of gold nanoparticles for the nanoscale manipulation of biological structures. Excitation of surface plasmons on spherical nanoparticles by pulsed irradiation provides a platform for the confinement of photoactivated processes, while functionalized nanoparticle targeting methods provide the highest level of therapeutic selectivity. In this dissertation, we demonstrate and characterize the in vitro plasmonic optoporation of MDA-MB-468 human epithelial breast cancer cells labeled with plasmonic gold nanoparticles using NIR, femtosecond laser pulses. Using a 10 kDa FITC-Dextran probe dye, we find that the PLN can optoporate nanoparticle-labeled cellular membranes at fluences down to just a few mJ/cm², providing a 50-fold reduction in pulse energy necessary to induce membrane dysfunction as compared with unlabeled cells. Limited membrane dysfunction was found to lead to transient optoporation of cells as a possible transfection method, while more extensive, non-recoverable membrane dysfunction lead to cellular death as a possible plasmonic treatment of malicious cells. In the first regime, we found a maximum optoporation efficiency of approximately 31% ± 5.4% with 2 to 2.5 mW laser light having 80 MHz repetition rate. In the second regime, we were able to necrotically kill greater than 90% of irradiated cells with as little as 5 mW average power. We found that particle aggregation along the cellular surface is crucial for the success of PLN. High particle loadings were required, suggesting that particle aggregates provide large enhancements, leading to reduced PLN threshold energies. We provide experimental evidence suggesting photodisruption with ultra-low energy pulses is directly dependent upon the emission of electrons from the particle surface, which seed the formation of free radicals in the surrounding water. These free radicals mediate membrane dysfunction by polyunsaturated lipid and protein peroxidation. / text

Ultrafast lasers

Plasmonics

Noble-metals

Cancer

Transfections

Novel applications of a modified gene gun : implications for new research in neuroscience

O'Brien, John Anthony

January 2012

The original Bio-Rad gene gun was unable to transfect acute or organotypic brain slices, as the amount of helium gas used, the distance for the gold-coated microcarriers to travel to target area were not optimised for fragile tissues, such as the brain. Typically, tissues were severely damaged by a helium shock wave and only a few cells were transfected. It was essential to improve gene gun accuracy by restricting the gold particles from being propelled superficially over a wide area. It was also necessary to increase the amount of DNA or dye delivery into intact tissues. Furthermore, for the gene gun to perform successfully on brain slices the helium gas pressure had to be lowered thereby reducing the degree of cell damage incurred during a biolistic delivery. Without knowing it at the time, the modified gene gun had worked particularly well on a variety of other fragile tissues, and not just the brain. However, the modified gun was not optimised for cultured cells as other transfection methods were available. A particularly notable point of this work was the successful labelling of individual Purkinje dendritic spines from live nerve cells in the cerebellum region of the brain. Biolistic images of Purkinje cells show that the distribution of dendritic spines are not random (O’Brien and Unwin, 2006). Spines were shown to grow in elaborate regular linear arrays, that trace short-pitch helical paths around the dendrites. It was apparent that the spines are arranged to maximize the probability that the dendritic arbour would interact with any afferent axon. This was an important discovery as there has been much debate as to how spines develop on a dendritic shaft. There are three general views to this question, each proposing a theory describing a model for spinogenesis. Classification of the three models in relation to our findings is described in chapter six of this thesis. The Investigation of spine morphology by biolistics was further optimized; gold particles were reduced from a micrometre to forty nanometres (O’Brien and Lummis, 2011), demonstrating that it is possible to use gold-coated DNA nanoparticles of this size to transfect tissue revealing exquisite structural detail. It was possible to observe boutons making synaptic contacts with the pyramidal nerve spines in the hippocampal region of the brain. The findings so far have shown spines from the pyramidal shaft are similar to the spines in the cerebellum, forming regular linear arrays. Recent studies had linked defects in the function of presynaptic boutons to the etiology of several neurodevelopment and neurodegenerative diseases, including autism and Alzheimer’s disease. Our discovery could help to understand why there are abnormalities in dendritic spines which are associated with pathological conditions characterized by cognitive decline, such as mental retardation, Alzheimer’s, stroke and schizophrenia (Yuste and Bonhoeffer, 2001). This thesis provides a synthesis of knowledge about biolistic technology. It is presented as a narrative from improving the gene gun transfection efficiency in brain slices to the development of nano-biolistics. The delivery of DNA and fluorescent dyes into living cells by biolistic delivery should enable a detailed map of the anatomical connections between individual cells and groups of cells to be constructed, providing a “wiring diagram” of connections. The implications of this are discussed in Chapter twelve. The original Bio-Rad gene gun was unable to transfect acute or organotypic brain slices, as the amount of helium gas used, the distance for the gold-coated microcarriers to travel to target area were not optimised for fragile tissues, such as the brain. Typically, tissues were severely damaged by a helium shock wave and only a few cells were transfected. It was essential to improve gene gun accuracy by restricting the gold particles from being propelled superficially over a wide area. It was also necessary to increase the amount of DNA or dye delivery into intact tissues. Furthermore, for the gene gun to perform successfully on brain slices the helium gas pressure had to be lowered thereby reducing the degree of cell damage incurred during a biolistic delivery. Without knowing it at the time, the modified gene gun had worked particularly well on a variety of other fragile tissues, and not just the brain. However, the modified gun was not optimised for cultured cells as other transfection methods were available. A particularly notable point of this work was the successful labelling of individual Purkinje dendritic spines from live nerve cells in the cerebellum region of the brain. Biolistic images of Purkinje cells show that the distribution of dendritic spines are not random (O’Brien and Unwin, 2006). Spines were shown to grow in elaborate regular linear arrays, that trace short-pitch helical paths around the dendrites. It was apparent that the spines are arranged to maximize the probability that the dendritic arbour would interact with any afferent axon. This was an important discovery as there has been much debate as to how spines develop on a dendritic shaft. There are three general views to this question, each proposing a theory describing a model for spinogenesis. Classification of the three models in relation to our findings is described in chapter six of this thesis. The Investigation of spine morphology by biolistics was further optimized; gold particles were reduced from a micrometre to forty nanometres (O’Brien and Lummis, 2011), demonstrating that it is possible to use gold-coated DNA nanoparticles of this size to transfect tissue revealing exquisite structural detail. It was possible to observe boutons making synaptic contacts with the pyramidal nerve spines in the hippocampal region of the brain. The findings so far have shown spines from the pyramidal shaft are similar to the spines in the cerebellum, forming regular linear arrays. Recent studies had linked defects in the function of presynaptic boutons to the etiology of several neurodevelopment and neurodegenerative diseases, including autism and Alzheimer’s disease. Our discovery could help to understand why there are abnormalities in dendritic spines which are associated with pathological conditions characterized by cognitive decline, such as mental retardation, Alzheimer’s, stroke and schizophrenia (Yuste and Bonhoeffer, 2001). This thesis provides a synthesis of knowledge about biolistic technology. It is presented as a narrative from improving the gene gun transfection efficiency in brain slices to the development of nano-biolistics. The delivery of DNA and fluorescent dyes into living cells by biolistic delivery should enable a detailed map of the anatomical connections between individual cells and groups of cells to be constructed, providing a “wiring diagram” of connections. The implications of this are discussed in Chapter twelve.

612.8233

CHARACTERIZATION OF THE REGULATORY REGION OF THE DISPERSED HOMEOBOX GENE <i>gsh-1</i>

MCFARLAND, KEVIN LEE

11 June 2002

No description available.

gsh-i

homeobox

promoter

transient transfections

reporter genes

Étude de l'effet de la mutation naturelle G577R dans le domaine de liaison de l'ADN du récepteur des androgènes sur l'affinité et la spécificité de la liaison à l'ADN

Nguyen, Denis

January 2002

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.

Domaine de liaison à l'ADN

Boîte P

Éléments de réponse

Interaction récepteur-ADN

Sélectivité de liaison à l'ADN

Retard sur gel

Transfections transitoires

Modélisation moléculaire