Molecular specific photoacoustic imaging using plasmonic gold nanoparticles

Mallidi, Srivalleesha

04 October 2012

Cancer has become one of the leading causes of death today. The early detection of cancer may lead to desired therapeutic management of cancer and to decrease the mortality rate through effective therapeutic strategies. Advances in materials science have enabled the use of nanoparticles for added contrast in various imaging techniques. More recently there has been much interest in the use of gold nanoparticles as optical contrast agents because of their strong absorption and scattering properties at visible and near-infrared wavelengths. Highly proliferative cancer cells overexpress molecular markers such as epidermal growth factor receptor (EGFR). When specifically targeted gold nanoparticles bind to EGFR they tend to cluster thus leading to an optical red-shift of the plasmon resonances and an increase in absorption in the red region. These changes in optical properties provide the foundation for photoacoustic imaging technique to differentiate cancer cells from surrounding benign cells. In photoacoustic imaging, contrast mechanism is based on the optical absorption properties of the tissue constituents. Studies were performed on tissue phantoms, ex-vivo and in-vivo tumor models to evaluate molecular specific photoacoustic imaging technique. The results indicate that highly sensitive and selective detection of cancer cells can be achieved by utilizing the plasmon resonance coupling effect of EGFR targeted gold nanoparticles and photoacoustic imaging. In conclusion, the combined ultrasound and photoacoustic imaging technique has the ability to image molecular signature of cancer using bioconjugated gold nanoparticles. / text

Gold nanoparticles

Optical contrast agents

Cancer cells

Epidermal growth factor receptor

Plasmon resonances

Photoacoustic imaging

Contrast and sensitivity enhanced molecular imaging using photoacoustic nanoamplifiers

Chen, Yun-Sheng, active 2012

12 November 2013

Molecular imaging is an emerging imaging principle which can visually represent the biological processes both spatially and temporally down to the sub-cellular level in vivo. The outcome of this research is expected to have a profound impact on facilitating the early diagnosis of diseases, accelerating the development of new drugs, and improving the efficacy of therapy. In general, molecular imaging highly relies on probes to sense the occurrence of molecular biological events, and to generate signals which could be picked up by diagnostic imaging modalities. The advances in the design of molecular probes not only have equipped traditional anatomical medical imaging with new capabilities but also, in some cases, stimulated developments of new imaging modalities and renaissance of existing medical imaging modalities. One of these is photoacoustic imaging, which as an emerging medical imaging modality, unites the merits from both optical imaging and ultrasound imaging. It shares with optical imaging, that it uses non-ionizing radiation and provides higher contrast and higher sensitivity than ultrasound imaging. Unlike optical imaging, which requires ballistic photons for imaging, photoacoustic imaging requires only diffusive photons to excite the ultrasound signal from the imaging target; therefore, it is capable of imaging much deeper into the tissue. In combination with molecular probes, photoacoustic molecular imaging has been demonstrated by several research groups using various photoacoustic molecular probes. However, the molecular probes used for most of these studies were contrast agents simply adopted from other optical imaging modalities. Our research on photoacoustic contrast agents indicated that the mechanism of photoacoustic signal generation from nanometer-sized contrast agents is distinct from that of optically homogeneous materials, such as tissue. We have discovered that, the amplitude of the photoacoustic signal generated from nano-contrast agents depends not only on the optical absorption of the particles, but more importantly, on the dynamic process of the heat conduction from the nanoparticles to the ambient, and the thermal properties of the surrounding materials. Based on our finding, we explored and further improved the photoacoustic response of the nanoparticles by exploiting the heat conduction process between the nanoparticle and its surrounding materials and by manipulating the excitations. This research allows to create optimized molecular specific contrast enhanced photothermal stable probes which can aid photoacoustic imaging and image guided photothermal cancer therapy. / text

Photoacoustic imaging

Photothermal cancer therapy

Molecular probes

Contrast agents

Bioconjugation

Nanoparticles

Interactions of composite gold nanoparticles with cells and tissue : implications in clinical translation for cancer imaging and therapy

Tam, Justina Oichi

04 March 2014

Current methods to diagnose and treat cancer often involve expensive, time-consuming equipment and materials that may lead to unwanted side effects and may not even increase a patient’s chance of survival. Thus, for a while now, a large part of the research community has focused on developing improved methods to detect, diagnose, and treat cancer on the molecular scale. One of the most recently discovered methods of cancer therapy is targeted therapy. These targeted therapies have potential to provide a patient with a form of personalized medicine because these therapies are biological molecules that specifically target other molecules involved with a cancer’s growth. Past trials using these therapeutic molecules, however, have led to controversial results, where certain patients responded better than others to the therapy for unknown reasons. Elucidating the reason behind these mixed results can be accomplished using metal nanoparticle technologies which could provide a bright signal to monitor the path that these therapeutic molecules take in vivo as well as enhance the molecule’s efficacy. Literature has shown that presenting targeting molecules in a dense manner to their target will increase these molecules’ binding affinity. This concept has been explored here to increase binding affinity of therapeutic molecules by attaching these molecules in a dense manner on the surface of gold nanoparticles, and correlating this increased affinity with therapeutic efficacy. Additionally, gold nanoparticles provide an easy surface for molecules to be functionalized on and have shown to be effective imaging, x-ray, and photothermal therapy agents. A major roadblock to using these gold nanoparticles clinically is their non-degradability and thus potential to cause long-term negative side effects in vivo. A platform for developing biodegradable gold nanoparticles is also explored here to take advantage of the gold nanoparticles’ excellent imaging and drug delivery capabilities while still allowing them to be used safely in the long term. / text

Gold nanoparticles

Iron oxide nanoparticles

Nanosensors

EGFR

Cetuximab

Clone 225

Monitoring autophagy

Delivery

Clearance

Photoacoustic imaging

Functional and molecular photoacoustic imaging for the detection of lymph node metastasis

Luke, Geoffrey Patrick

02 March 2015

Accurate detection of the spread of cancer is critical for planning the best treatment strategy for a patient. Currently, an invasive sentinel lymph node biopsy is commonly used to detect metastases after a primary tumor is detected. This procedure results in patient morbidity, requires weeks of waiting, and is prone to sampling error. This dissertation presents new developments in an emerging biomedical imaging modality – photoacoustic imaging – and their application to improving the detection of metastases in the lymphatic system in a metastatic mouse model of squamous cell carcinoma of the oral cavity. Label-free spectroscopic photoacoustic imaging is demonstrated to detect hypoxia that results from the development of sub-millimeter cancer foci in the lymph node. In order to improve the sensitivity to micrometastases, molecularly-activated plasmonic nanosensers which are targeted to the epidermal growth factor receptor are introduced. The nanosensors are demonstrated to detect metastases consisting of only a few tens of cells. Improvements to spectroscopic photoacoustic imaging are then demonstrated by selecting imaging wavelengths based on the spectral properties of the optical absorbers. Finally, a new contrast agent – silica-coated gold nanoplates – are used to map the sentinel lymph node with high contrast. The final result is a set of tools that can be used to noninvasively detect micrometastases and improve molecular photoacoustic imaging. / text

Photoacoustic imaging

Molecular imaging

Sentinel lymph node

Ultrasound imaging

Nanoparticles

Image processing

Spectroscopy

Near-IR plasmonic contrast agents for molecular imaging, cell tracking and clinical translation

Joshi, Pratixa Paritosh

11 August 2015

Gold nanoparticles attain an intense focus in biomedical imaging applications due to their unique optical properties, facile conjugation with biomolecules, and biocompatibility. Although a considerable amount of work towards the development of gold nanoparticles has been completed, these promising contrast agents have not yet reached the clinic due to several challenges including efficient accumulation at the diseased site, sensitivity of detection in vivo, potential adverse effects, and clearance from the body. High signal-to-background ratio is required to enhance sensitivity of detection. Because near infrared (near-IR) light has the best tissue penetration, contrast agents designed to work in this range can significantly increase imaging sensitivity. Moreover, efficient targeting of the molecular biomarkers on diseased cells can decrease the required dosage, increase the site-specific accumulation, and enhance the imaging sensitivity. Molecular-specific contrast agents developed in this project use directional attachment of antibody molecules to the nanoparticle surface, enhancing the targeting efficacy. Additionally, cell-based delivery of diagnostic and therapeutic agents is gaining much interest due to the immune cells’ special access to the avascular, diseased regions. The contrast agents developed in this project enable detection of just a few cells per unit of imaging volume, enable multiplex imaging, and open up a possibility for tracking different cell populations with noninvasive photoacoustic and ultrasound imaging. Finally, the clearance of nanoparticles from the body dictates their clinical translation. The in vivo pharmacokinetics study along with the proposed in vitro model explored in this project will enable fast, reliable, and cost-efficient screening of promising agents and facilitate quick optimization of nanoparticles for their potential use in the clinic. / text

Gold nanoparticles

Biodegradable nanoparticles

Molecular imaging

Cell tracking

Biodistribution and clearance

Photoacoustic imaging

In vivo imaging

Intravascular photoacoustics as a theranostic platform for atherosclerosis

Yeager, Douglas Edward

10 September 2015

The persistence of high global mortality rates directly attributable to cardiovascular disease drives ongoing research into novel approaches for improved diagnosis and treatment of its primary underlying cause, atherosclerosis. Combined intravascular ultrasound and photoacoustic (IVUS/IVPA) imaging is one such modality, actively being developed as a tool for improved characterization of high-risk atherosclerotic plaques. The pathophysiology associated with progression and destabilization of atherosclerotic plaques leads to characteristic changes in arterial morphology and composition. IVUS/IVPA imaging seeks to expand upon the ability of clinically utilized intravascular ultrasound (IVUS) imaging to assess vessel anatomy by adding improved sensitivity to image the underlying cellular and molecular composition through intravascular photoacoustic (IVPA) imaging of either endogenous chromophores (e.g. lipid) or exogenously delivered contrast agents. This dissertation focuses on the expansion of IVUS/IVPA imaging using exogenous contrast agents to enable the detection and subsequent optically-triggered therapy of atherosclerotic plaques. The passive extravasation and aggregation of systemically injected plasmonic gold nanorods absorbing within the near infrared tissue optical window within plaques of atherosclerotic rabbit models is first demonstrated, along with the ability to localize the contrast agents using ex vivo IVUS/IVPA imaging. The motivation for nanoparticle labeling of atherosclerosis is then expanded from that of purely image contrast agents to vehicles for image-guided, dual-modality phototherapy. The integrated IVUS/IVPA imaging catheter is utilized for photothermal delivery with simultaneous IVPA temperature monitoring using the high optical absorption of gold nanorod contrast agents to enable localized heating. Subsequently, the potential role for IVUS/IVPA-guided phototherapy is further expanded through the characterization and in vitro assessment of novel multifunctional theranostic nanoparticles comprised of a gold nanorod core with a degradable, photosensitizer-doped silica shell. Together, the results presented within this dissertation provide a framework for ongoing research into the expansion of IVUS/IVPA imaging as a platform for complimentary diagnosis and local treatment of atherosclerotic plaques using multifunctional theranostic nanoparticle contrast agents. / text

Intravascular imaging

Atherosclerosis

Ultrasound

Photoacoustic

Gold nanorod

Photothermal therapy

Photodynamic therapy

Theranostic

Characterization of atherosclerotic plaques using ultrasound guided intravascular photoacoustic imaging

Wang, Bo, 1981-

01 June 2011

Rupture of atherosclerotic plaque is closely related to plaque composition. Currently, plaque composition cannot be clinically characterized by any imaging modality. The objective of this dissertation is to use a recently developed imaging modality – ultrasound-guided intravascular photoacoustic (IVPA) imaging – to detect the distribution of two critical components in atherosclerotic plaques: lipid and phagocytically active macrophages. Under the guidance of intravascular ultrasound imaging, spectroscopic IVPA imaging is capable of detecting the spatially resolving optical absorption property inside a vessel wall. In this study, contrast in spectroscopic IVPA imaging was provided by either the endogenous optical property of lipid or optically absorbing contrast agent such as gold nanoparticles (Au NPs). Using a rabbit model of atherosclerosis, this dissertation demonstrated that ultrasound guided spectroscopic IVPA imaging could simultaneously image lipid deposits as well as macrophages labeled in vivo with Au NPs. Information of macrophage activity around lipid rich plaques may help to identify rupture-prone or vulnerable plaques. The results show that ultrasound guided IVPA imaging is promising for detecting plaque composition in vivo. Clinical use of ultrasound guided IVPA imaging may significantly improve the accuracy of diagnosis and lead to more effective treatments of atherosclerosis. / text

Intravascular photoacoustic imaging

Atherosclerosis

Tissue characterization

Intravascular ultrasound

Molecular imaging

Gold nanoparticles

Lipid

Macrophages

Propriedades ópticas do Fe3+ tetraédrico em matriz cerâmica / Optical properties of tetrahedal Fe3+ in ceramic sample

Sandra da Silva Pedro

19 November 2007

Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro / O objetivo deste trabalho foi a produção e a investigação de amostras cerâmicas dopadas com Fe3+. Os métodos experimentais usados foram a difração de raios X, e as espectroscopias de fotoluminescência e fotoacústica. As fases formadas foram identificadas a partir dos resultados da difração de raios X. Utilizando os dados ópticos, os níveis de energia excitados e o fundamental, os parâmetros de energia e de campo cristalino e de Racah, os tempos de vida radiativos e não-radiativos e a simetria do sítio do Fe3+ foram determinados. / The aim of this work was the production and investigation of a Fe3+- doped sample. The experimental methods were X-ray diffraction, photoluminescence and photoacoustic spectroscopies. From X-ray results, the formed phases in the sample were identified. By using optical data, the excited and fundamental energy levels, the energy crystal field and Racah parameters, the radiative and non-radiative lifetimes and the Fe3+ site symmetry were determinated.

Amostras cerâmicas

Fotoluminescência

Fotoacústica

Espectroscopia

Análise espectral

Spectroscopy

Photoacoustic

Photoluminescence

Ceramic samples

FISICA DA MATERIA CONDENSADA

Determinação da difusividade térmica de cristais de BaLiFsub(3) puro e dopado

SAWADA, LIDIA

09 October 2014

Made available in DSpace on 2014-10-09T12:25:47Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:03:34Z (GMT). No. of bitstreams: 1 11311.pdf: 4096901 bytes, checksum: db8eab8599a76e1dd1addc784a437a1a (MD5) / Dissertacao (Mestrado) / IPEN/D / Intituto de Pesquisas Energeticas e Nucleares, IPEN/CNEN-SP

BARIUM FLUORIDES

LITHIUM FLUORIDES

CRYSTAL DOPING

THERMAL DIFFUSIVITY

LASERS; CRYSTAL GROWTH

PHOTOACOUSTIC EFFECT

Propriedades ópticas do Fe3+ tetraédrico em matriz cerâmica / Optical properties of tetrahedal Fe3+ in ceramic sample

Sandra da Silva Pedro

19 November 2007

Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro / O objetivo deste trabalho foi a produção e a investigação de amostras cerâmicas dopadas com Fe3+. Os métodos experimentais usados foram a difração de raios X, e as espectroscopias de fotoluminescência e fotoacústica. As fases formadas foram identificadas a partir dos resultados da difração de raios X. Utilizando os dados ópticos, os níveis de energia excitados e o fundamental, os parâmetros de energia e de campo cristalino e de Racah, os tempos de vida radiativos e não-radiativos e a simetria do sítio do Fe3+ foram determinados. / The aim of this work was the production and investigation of a Fe3+- doped sample. The experimental methods were X-ray diffraction, photoluminescence and photoacoustic spectroscopies. From X-ray results, the formed phases in the sample were identified. By using optical data, the excited and fundamental energy levels, the energy crystal field and Racah parameters, the radiative and non-radiative lifetimes and the Fe3+ site symmetry were determinated.

Amostras cerâmicas

Fotoluminescência

Fotoacústica

Espectroscopia

Análise espectral

Spectroscopy

Photoacoustic

Photoluminescence

Ceramic samples

FISICA DA MATERIA CONDENSADA