Imaging Atoms and Molecules with Strong Laser Fields

Smeenk, Christopher

January 2013

We study multi-photon ionization of rare gas atoms and small molecules by infrared femtosecond laser pulses. We demonstrate that ionization is accurately described by a tunnelling model when many infrared photons are absorbed. By measuring photo-electron and photo-ion spectra, we show how the sub-Ångstrom spatial resolution of tunnelling gives information about electron densities in the valence shell of atoms and molecules. The photo-electron and photo-ion momentum distributions are recorded with a velocity map imaging (VMI) spectrometer. We describe a tomographic method for imaging a 3-D momentum distribution of arbitrary symmetry using a 2-D VMI detector. We apply the method to measure the 3-D photo-electron distribution in elliptically polarized light. Using circularly polarized light, we show how the photo-electron momentum distribution can be used to measure the focused laser intensity with high precision. We demonstrate that the gradient of intensities present in a focused femtosecond pulse can be replaced by a single average intensity for a highly nonlinear process like multi-photon ionization. By studying photo-electron angular distributions over a range of laser parameters, we determine experimentally how the photon linear momentum is shared between the photo-electron, photo-ion and light field. We find the photo-electron carries only a portion of the total linear momentum absorbed. In addition we consider how angular momentum is shared in multi-photon ionization, and find the photo-electron receives all of the angular momentum absorbed. Our results demonstrate how optical and material properties influence the photo-electron spectrum in multi-photon ionization. These will have implications for molecular imaging using femtosecond laser pulses, and controlling the initial conditions of laser generated plasmas.

tunneling

ultrafast

laser

optics

multiphoton

photo-electron spectroscopy

molecular imaging

physical chemistry

A Tale of Two Projects: Basis for Centrosome Amplification after DNA Damage and Practical Assessment of Photodamage in Live-Cell Imaging: A Dissertation

Douthwright, Stephen

02 April 2015

This thesis comprises two separate studies that focus on the consequences of cellular damage. The first investigates the effects of DNA damage on centriole behavior and the second characterizes phototoxicity during live-cell imaging. Cancer treatments such as ionizing radiation and/or chemotherapeutic DNA damaging agents are intended to kill tumor cells, but they also damage normal proliferating cells. Although centrosome amplification after DNA damage is a well-established phenomenon for transformed cells, it is not fully understood in untransformed cells. The presence of extra centrosomes in normal cell populations raises the chances of genomic instability, thus posing additional threats to patients undergoing these therapies. I characterized centriole behavior after DNA damage in synchronized untransformed (RPE1) human cells. Treatment with the radiomimetic drug, Doxorubicin, prolongs G2 phase by at least 72hrs, where 52% of cells display disengaged centrioles and 10% contain extra centrioles. This disengagement is mediated by Plk and APC/C activities both singly and in combination. Disengaged centrioles are associated with maturation markers suggesting they are capable of organizing spindle poles. Despite the high incidence of centriole disengagement, only a small percentage of centrioles reduplicate due to p53/p21 dependent inhibition of Cdk2 activity. Although all cells become prolonged in G2 phase, 14% eventually go through mitosis, of which 26% contain disengaged or extra centrioles. In addition to cancer treatments, cellular damage can be acquired from various external conditions. Short wavelengths of light are known to be toxic to living cells, but are commonly used during live-cell microscopy to excite fluorescent proteins. I characterized the phototoxic effects of blue (488nm) and green (546nm) light on cell cycle progression in RPE1. For unlabeled cells, I found that exposure to green light is far less toxic than blue light, but is not benign. However, the presence of fluorescent proteins led to increased sensitivity to both blue and green light. For 488nm irradiations, spreading the total irradiation durations out into a series of 10s pulses or conducting single longer, but lower intensity, exposures made no significant changes in phototoxicity. However, reducing oxidative stress by culturing cells at physiological (~3%) oxygen, or treatment with a water-soluble antioxidant, Trolox, greatly improved the cells tolerance to blue light. Collectively, my work offers an explanation for centrosome amplification after DNA damage and demonstrates the importance of proper centriole regulation in untransformed human cells. Further, it provides a practical assessment of photodamage during live-cell imaging.

DNA Damage

Centrioles

Centrosome

Molecular Imaging

Dissertations, UMMS

Cell Biology

Cellular and Molecular Physiology

Reconstruction Methods for Optical Molecular Tomography

Cong, Alexander Xiao

25 January 2013

Molecular imaging plays an important role for development of systems biomedicine, which non-invasively extracts pictorial information on physiological and pathological activities at the cellular and molecular levels. Optical molecular tomography is an emerging area of molecular imaging. It locates and quantifies a 3D molecular probe distribution in vivo from data measured on the external surface of a small animal around the visible and infrared range. This approach can facilitate or enable preclinical applications such as cancer studies, involving angiogenesis, tumor growth, cell motility, metastasis, and interaction with a micro-environment. The reconstruction of diffuse light sources is the central task of optical molecular tomography, and generally ill-posed and rather complex. The key element of optical molecular tomography includes the geometrical model, tissue properties, photon characteristics, transport model, and reconstruction algorithm. This dissertation focuses mainly on the development optical molecular tomography methods based on bioluminescence/fluorescence probes to solve some well-known challenges in this field. Our main results are as follows. We developed a new algorithm for estimation of optical parameters based on the phase-approximation model.  Our iterative algorithm takes advantage of both the global search ability of the differential evolution algorithm and the efficiency of the conjugate gradient method. We published the first paper on multispectral bioluminescence tomography (BLT). The multispectral BLT approach improves the accuracy and stability of the BLT reconstruction even if data are highly noisy. We established a well-posed inverse source model for optical molecular tomography. Based on this model, we proposed a differential evolution-based reconstruction algorithm to determine the source locations and strengths accurately and reliably. Furthermore, to enhance the spatial resolution of fluorescence molecular tomography, we proposed fluorescence micro-tomography to image cells in a tissue scaffold based on Monte Carlo simulation on a massive parallel processing architecture. Each of these methods shows better performance in numerical simulation, phantom experiments, and mouse studies than the conventional methods. / Ph. D.

Optical molecular imaging

photon propagation model

Finite element method

inverse source

reconstruction

BIS-MPA DENDRIMERS AS A PLATFORM FOR MOLECULAR IMAGING APPLICATIONS

Sadowski, Lukas

January 2016

The objective of this research was to develop and validate new macromolecular imaging agents to detect and characterize malignant tumours. Using well-defined, highly branched macromolecules called dendrimers as the structural scaffold, efficient functionalization of the periphery was demonstrated using “click” chemistry in order to prepare multivalent imaging probes. Furthermore, a transmetalation was demonstrated to displace chelated copper with technetium, enabling “click” reactions to be performed in the presence of the dipicolylamine (DPA), a ligand known to chelate many metals. The dendritic scaffold was functionalized with either hydrophobic or hydrophilic targeting vectors. The hydrophobic ligand, an acyloxymethyl ketone targeting the overexpression of cathepsin B exhibited poor in vitro affinity when coupled to either G1 or G2 dendrimers, despite the use of various linkers. A glu-urea-lys dipeptide, representing a hydrophilic prostate specific membrane antigen targeting vector, demonstrated excellent affinity in vitro. The lead compound, a G2 dendrimer bearing four PSMA targeting vectors attached via an alkyl spacer was further investigated in vitro and in vivo. Unfortunately, poor tumor uptake was observed and the compound was hypothesized to hydrolyze readily (<15min), based on the in vitro plasma stability data. To rectify the aforementioned problem, non neo-pentyl esters were replaced with either carbamate or ether linkages. In vitro plasma stability analysis of the analogous compounds demonstrated increased stability. In particular, the ether analogue was found to be most stable, with minimal degradation observed after 4 hours. / Thesis / Doctor of Philosophy (PhD)

CD133-Targeted Radionuclide Therapy and Molecular Imaging

Wyszatko, Kevin

January 2024

To address the unmet clinical need to eradicate treatment-resistant CD133+ cancer stems within tumors, a CSC-targeted radionuclide therapy (TRT) and companion diagnostic imaging probes were developed utilizing CD133-targeting antibodies and antibody fragments. In Chapter 1, background research providing context for the work in this Thesis is presented. In Chapter 2, a CD133-targeting antibody, RW03IgG, underwent radiolabeling with lutetium-177 to synthesize [177Lu]Lu-DOTA-RW03IgG for CD133-TRT. The CD133-TRT was evaluated for pharmacokinetics and treatment of a CD133 expressing human colorectal tumor bearing mouse model. Biodistribution studies on [177Lu]Lu-DOTA-RW03IgG demonstrated notable uptake in the colorectal tumors and off-target organ uptake consistent with previously reported antibody-based TRTs. Confirmation that tumor uptake was mediated by antibody-antigen binding was verified through co-injection with an excess dose of unlabeled RW03IgG. A dose-escalation therapy trial using [177Lu]Lu-DOTA-RW03IgG for treatment of the colorectal cancer mouse model revealed a dose-dependent reduction in tumor growth rate at well-tolerated doses. The decrease in tumor growth rate observed due to [177Lu]Lu-DOTA-RW03IgG treatment, along with an improvement in overall mouse survival, demonstrate the therapeutic efficacy of CD133-TRT. Additionally, histopathological and immunohistochemical (IHC) analyses indicated low off-target organ toxicity and significant anti-tumor effects. These findings suggested the potential for enhanced overall survival benefits through multiple doses. However, results on multiple-dosed CD133-TRT on the tumor growth rate and overall mouse survival were inconclusive. In Chapter 3, an orthotopic patient-derived glioblastoma (GBM) mouse model was developed that replicates anatomical pharmacokinetic challenges and CSC populations observed in patient tumors. Stereotactic engraftment of the patient GBM cells was optimized to reproducibly deliver tumor cells to the thalamus and growth was monitored using bioluminescence imaging. Ex vivo analysis confirmed various key characteristics of patient GBM, including CD133 expression, hypercellularity, and invasiveness. Biodistribution studies on [177Lu]Lu-DOTA-RW03IgG using the PDX GBM mouse model indicate antibody-antigen driven tumor uptake, determined through co-injection an excess dose of unlabeled RW03IgG. Ex vivo autoradiography supported the biodistribution results and showed elevated uptake of [177Lu]Lu-DOTA-RW03IgG in tumor relative to non-tumor bearing brain tissue. Chapters 4 and 5 centered on the development and evaluation of companion diagnostic CD133-targeted immunoPET probes. Chapter 4 specifically explored probes derived from the full antibody, RW03IgG. The probes were synthesized by conjugating RW03IgG with DFO-NCS to produce DFO-RW03IgG at different chelator-to-antibody ratios. The various DFO-RW03IgG conjugates were then radiolabeled with zirconium-89 to obtain [89Zr]-DFO-RW03IgG. Biodistribution studies and PET imaging revealed promising tumor uptake of [89Zr]-DFO-RW03IgG, and it was observed that higher chelator-to-antibody ratios led to increased accumulation in off-target organs. Chapter 5 investigated a probe derived from an scFv-Fc fragment of RW03, [89Zr]-DFO-RW03scFv-Fc. Biodistribution studies and PET images of colorectal tumor-bearing mice administered [89Zr]-DFO-RW03scFv-Fc showed favorable tumor uptake and low off-target organ accumulation. In Chapter 6, a probe for CD133-Photoacoustic Imaging (PAI) was synthesized through conjugation of RW03IgG with IR-783, an organic dye recognized for its favorable photoacoustic properties. Challenges were encountered in isolating the product, (IR-783)-RW03IgG, at high degrees of labeling (DOL) due to product aggregation. In vitro binding assays indicated that (IR-783)-RW03IgG (DOL = 1) maintained a comparable binding affinity to native RW03IgG. In vivo, colorectal tumors in mice administered (IR-783)-RW03IgG (DOL = 1) did not exhibit significant contrast from the background tissue, and the tumor PA signal did not differ significantly compared to tumors in mice administered an IR-783 labeled isotype IgG. The results suggest that a higher concentration of dye is needed within colorectal tumors for effective tumor visualization than what was provided by IR-783-RW03IgG. Chapter 7 investigated the use of Imaging Mass Cytometry (IMC) to simultaneously visualize [177Lu]Lu-DOTA-RW03IgG and multiple tumor biomarkers in tissue specimens collected from colorectal tumor xenograft mice treated with CD133-TRT. IMC showed undetectable concentrations of hafnium-177 (the decay product of lutetium-177) in tumors treated with CD133-TRT. However, lutetium-176 and lutetium-175, sourced from the carrier-added [177Lu]LuCl3 used in the synthesis of [177Lu]Lu-DOTA-RW03IgG, were present at levels sufficient for IMC visualization. The distribution of lutetium-176, representing [177Lu]Lu-DOTA-RW03IgG, within tumors, was imaged concomitantly with CD133, DNA damage markers, and several additional biomarkers that describe elements of the tumor microenvironment. These collective results endorse IMC as a useful tool to assess the distribution of TRT within tumors and uncover changes to the microenvironment in response to treatment. / Thesis / Doctor of Philosophy (PhD) / Targeted radionuclide therapy (TRT) and molecular imaging strategies were developed to aid in the elimination of the rare and particularly resilient Cancer Stem Cell (CSC) population in tumors. A fully human monoclonal antibody and antibody fragments targeting CD133, a molecular biomarker for CSCs, provided the means to deliver radioactive isotopes for therapy and imaging to CD133+ cells in tumors. The therapeutic efficacy of CD133-TRT for treatment of a colorectal cell line-derived xenograft mouse model was promising, and the treatment showed uptake in orthotopic patient derived glioblastoma tumors engrafted in mice. ImmunoPET probes targeting CD133 were optimized and successfully delineated CD133 expressing tumors from background tissue, warranting further evaluation using patient-representative cancer models. A non-invasive CD133-targeting Photoacoustic Imaging (PAI) probe was synthesized through conjugation of the CD133-targeting antibody to an organic dye, IR-783, although further probe optimization is required to provide tumor contrast. Tumor specimens from mice treated with CD133-TRT were assessed by Imaging Mass Cytometry (IMC), which revealed detectable concentrations of carrier isotopes from the therapy in the tumors, implicating the discovery of a powerful new tool for multiplexed single-cell level resolution imaging for cellular-scale analysis of targeted radionuclide therapy. The CSC-therapy and select molecular imaging probes generated in this Thesis warrant further evaluation using patient-representative mouse models of cancer.

Cancer Stem Cells

Targeted Radionuclide Therapy

Molecular Imaging

PET Imaging

CD133

Antibodies and Fragments

Quantification of Pharmacokinetics in Small Animals with Molecular Imaging and Compartment Modeling Analysis

Fang, Yu-Hua

02 April 2009

No description available.

Biomedical Research

Engineering

Kinetic modeling

compartment modeling

molecular imaging

PET

MRI

quantification

THE SYNTHESIS AND EVALUATION OF NEW RADIOPHARMACEUTICALS AND MULTIMODAL IMAGING PROBES / THE SYNTHESIS, EVALUATION AND MECHANISTIC STUDY OF NEW 99mTc(I)-TETRAZINES FOR THE DEVELOPMENT OF NEW RADIOPHARMACEUTICALS AND MULTIMODAL IMAGING PROBES

Bilton, Holly A

January 2019

Technetium-99m (99mTc) radiopharmaceuticals are widely used for diagnostic imaging of heart, kidney, and liver disease, and cancer. Evolution from perfusion type tracers to targeted agents however has proven difficult. 99mTc labeled antibodies for imaging specific disease biomarkers would be of great interest, however the disparity between the isotopes half-life (6 hours) and the long circulation time of most antibodies (multiple days) has been a significant barrier. Furthermore, the conjugation of bifunctional 99mTc-chelate complexes to small molecules often has a detrimental impact on targeting. The use of bioorthogonal chemistry derived from tetrazines and trans-cyclooctene derivatives, along with pretargeting has the potential to overcome these issues and create a new generation of targeted 99mTc radiopharmaceuticals. Initially, the synthesis of three generations of imidazole based tridentate chelates linked to a tetrazine was completed. These new ligands were labeled with 99mTc under mild conditions (60 °C, 20 min, pH 3.5) with modest to good radiochemical yields ranging from 31 to 83%. Biodistribution studies revealed that compound 14, which contains a polyethylene glycol 5 (PEG5) linker had the best clearance from non-target tissues. Compound 14 was also used successfully in a pretargeting strategy along with a transcyclooctene (TCO) derivative of the bone targeting bisphosphonate, alendronate (ALN). One hour following the administration of TCO-ALN to BALB/c mice, compound 14 was injected intravenously where uptake at sites of high calcium turn over (i.e. the joints) was observed. At 6 hours post injection, for example, uptake reached as high as 20.1 ± 4.91 and 16.1 ± 4.84 %ID/g in the knee and shoulder, respectively. Pretargeted imaging studies were performed subsequently with a TCO-functionalized huA33 antibody in mice bearing SW122 xenografts. The TCO-huA33 antibody was injected 24 hours before the administration of two radiolabeled tetrazines at high and low specific activities. At 6 hours post injection tumour uptake was minimal, with tumour: blood ratios <1 in all cases. Blood clearance studies determined that the tetrazines were being cleared rapidly, with a blood residence half-life of 1.3-2.1 minutes. The hypothesis is that the low concentration of the antibody (owing to its high molecular weight), combined with the rapid clearance of the tetrazine and significant off-target uptake resulted in unfavorable kinetics and low tumor binding. Studies of the clearance pathway of 14 were investigated with clinically approved hepatobiliary transport inhibitors to help understand the mechanism of clearance, which could in turn be used to optimize the pharmacokinetics of the tetrazine ligands. A range of different inhibitors of key clearance pathways were evaluated with limited success. However, co-administration of 14 with ALN resulted in a 75% decrease in gall bladder uptake of 14 (216 ± 75.9 to 33.6 ± 3.93 %ID/g). Pretargeting studies of 14 with TCO-ALN in the presence of excess ALN revealed that ALN did not hinder the uptake of TCO-ALN in the bone, with all organs and tissues having the same uptake with TCO-ALN or TCO-ALN + ALN (knee: 20.1 ± 4.91 and 14.9 ± 2.43 %ID/g, respectively). There was also a concomitant decrease in gall bladder uptake (91.5 ± 17.1 to 28.8 ± 2.63 %ID/g). Further work on improving the distribution of the tetrazine ligands involved investigating the effect of the chelate. The core chelate found in 14 without the tetrazine moiety (compound 11a) was labeled with 99mTc to produce 11b in a 31% radiochemical yield. Biodistribution studies of 11b and 14 at 6 hours post injection demonstrated that the imidazole-based 99mTc-chelate was a major factor in the rapid and significant uptake and retention in the liver and gallbladder. A new triazole based chelate with optimal clearance from Kluba and coworkers was synthesized in 45% yield and successfully labeled with 99mTc (compound 23a). Biodistribution studies were performed where at 6 hours post injection, 23a had five times lower uptake in all non-target organs compared to 11b. The synthesis of a tetrazine derivative of 23a (compound 32) unfortunately demonstrated high hepatobiliary uptake compared to the original triazole chelate (gall bladder: 228 ± 251 and 8.77 ± 0.73 %ID/g, large intestine: 85.5 ± 83.5 and 6.88 ± 0.30 %ID/g, respectively). This particular derivative had a lipophilic linker as a result of the synthetic challenges faced during the preparation of a more hydrophilic triazole-tetrazine derivative. In addition to pretargeting applications, the 99mTc-tetrazine was used as a reagent to create multimodal imaging agents. Nanoscale gas vesicle (GV) ultrasound contrast agents were functionalized with TCO via an amide coupling to lysine residues. TCO-GVs were then radiolabeled by adding compound 6 where the desired product, a new multimodal probe, was obtained in 59% radiochemical yield. SPECT imaging and biodistribution studies in mice were completed where the labeled GV’s showed uptake in the gall bladder (120 ± 29.1 %ID/g), liver (16.8 ± 7.50 %ID/g), lungs (3.26 ± 1.53 %ID/g), small intestines (14.5 ± 5.30 %ID/g), and spleen (5.47 ± 2.71 %ID/g) at 120 min post injection. In addition to radiolabelling, the TCO-GVs were also functionalized with a near IR-tetrazine dye to produce a multimodal ultrasound/photoacoustic (US/PA) imaging agent in a 68% yield. / Thesis / Doctor of Philosophy (PhD)

Radiopharmaceuticals

Chemistry

Chemical Biology

Technetium-99m

Bioorthogonal Chemistry

Multimodal Imaging

Molecular Imaging

Pretargeted Imaging

Material-Specific Computed Tomography for Molecular X-Imaging in Biomedical Research

Dong, Xu

08 April 2019

X-ray Computed Tomography (CT) imaging has been playing a central role in clinical practice since it was invented in 1972. However, the traditional x-ray CT technique fails to distinguish different materials with similar density, especially for biological tissues. The lack of a quantitative imaging representation has constrained the application of CT technique from a broadening application such as personal or precision medicine. Therefore, my major thesis statement is to develop novel material-specific CT imaging techniques for molecular imaging in biological bodies. To achieve the goal, comprehensive studies were conducted to investigate three different techniques: x-ray fluorescence molecular imaging, material identification (specification) from photon counting CT, and photon counting CT data distortion correction approach based on deep learning. X-ray fluorescence molecular imaging (XFMI) has shown great promise as a low-cost molecular imaging modality for clinical and pre-clinical applications with high sensitivity. In this study, the effects of excitation beam spectrum on the molecular sensitivity of XFMI were experimentally investigated, by quantitatively deriving minimum detectable concentration (MDC) under a fixed surface entrance dose of 200 mR at three different excitation beam spectra. The result shows that the MDC can be readily increased by a factor of 5.26 via excitation spectrum optimization. Furthermore, a numerical model was developed and validated by the experimental data (≥0.976). The numerical model can be used to optimize XFMI system configurations to further improve the molecular sensitivity. Findings from this investigation could find applications for in vivo pre-clinical small-animal XFMI in the future. PCCT is an emerging technique that has the ability to distinguish photon energy and generate much richer image data that contains x-ray spectral information compared to conventional CT. In this study, a physics model was developed based on x-ray matter interaction physics to calculate the effective atomic number () and effective electron density () from PCCT image data for material identification. As the validation of the physics model, the and were calculated under various energy conditions for many materials. The relative standard deviations are mostly less than 1% (161 out of 168) shows that the developed model obtains good accuracy and robustness to energy conditions. To study the feasibility of applying the model with PCCT image data for material identification, both PCCT system numerical simulation and physical experiment were conducted. The result shows different materials can be clearly identified in the − map (with relative error ≤8.8%). The model has the value to serve as a material identification scheme for PCCT system for practical use in the future. As PCCT appears to be a significant breakthrough in CT imaging field, there exists severe data distortion problem in PCCT, which greatly limits the application of PCCT in practice. Lately, deep learning (DL) neural network has demonstrated tremendous success in medical imaging field. In this study, a deep learning neural network based PCCT data distortion correction method was proposed. When applying the algorithm to process the test dataset data, the accuracy of the PCCT data can be greatly improved (RMSE improved 73.7%). Compared with traditional data correction approaches such as maximum likelihood, the deep learning approach demonstrate superiority in terms of RMSE, SSIM, PSNR, and most importantly, runtime (4053.21 sec vs. 1.98 sec). The proposed method has the potential to facilitate the PCCT studies and applications in practice. / Doctor of Philosophy / X-ray Computed Tomography (CT) has played a central role in clinical imaging since it was invented in 1972. It has distinguishing characteristics of being able to generate three dimensional images with comprehensive inner structural information in fast speed (less than one second). However, traditional CT imaging lacks of material-specific capability due to the mechanism of image formation, which makes it cannot be used for molecular imaging. Molecular imaging plays a central role in present and future biomedical research and clinical diagnosis and treatment. For example, imaging of biological processes and molecular markers can provide unprecedented rich information, which has huge potentials for individualized therapies, novel drug design, earlier diagnosis, and personalized medicine. Therefore there exists a pressing need to enable the traditional CT imaging technique with material-specific capability for molecular imaging purpose. This dissertation conducted comprehensive study to separately investigate three different techniques: x-ray fluorescence molecular imaging, material identification (specification) from photon counting CT, and photon counting CT data distortion correction approach based on deep learning. X-ray fluorescence molecular imaging utilizes fluorescence signal to achieve molecular imaging in CT; Material identification can be achieved based on the rich image data from PCCT; The deep learning based correction method is an efficient approach for PCCT data distortion correction, and furthermore can boost its performance on material identification. With those techniques, the material-specific capability of CT can be greatly enhanced and the molecular imaging can be approached in biological bodies.

Computed Tomography

Molecular Imaging

X-ray Fluorescence

Photon Counting CT

Deep learning (Machine learning)

Imaging brain aromatase by using PET : A way to study anabolic steroid abuse

Takahashi, Kayo

January 2008

<p>Aromatase is an enzyme that facilitates the conversion of androgens to estrogens and may play a role in mood and mental status. The main theme of this thesis is the imaging of brain aromatase by use of the PET technique. The PET tracer for aromatase, ¹¹C-labeled vorozole (VOZ) was developed and evaluated by with <i>in vitro</i> and <i>in vivo</i> methods. <i>In vitro</i> experiments using rat brain showed that VOZ was distributed in the medial amygdala, bed nucleus of the stria terminalis and medial preoptic area, regions of the brain known to be rich in aromatase and the K_D value was determined to be 0.60 nM. The <i>in vivo</i> PET study in rhesus monkey brain revealed that VOZ penetrated the blood-brain barrier and accumulated in the amygdala and hypothalamus. Taken together, VOZ is a good PET tracer for <i>in vivo</i> aromatase imaging with high affinity and high sensitivity.</p><p>This technique was applied to an investigation of brain aromatase under the physiological conditions simulating anabolic-androgenic steroid abuse. A significant increase in VOZ binding by anabolic-androgenic steroids was observed in the bed nucleus of stria terminalis and medial preoptic area in the rat brain. In contrast, no significant change in binding was observed in the medial amygdala. These results indicate that the manner of regulation of aromatase expression might be different in the bed nucleus of stria terminalis and medial preoptic area compared with that in the medial amygdala. The aromatase expression was suggested to be regulated through androgen receptors, as indicated in a study with flutamide treatment. The increased aromatase expression was seen in neurons. The PET study with anabolic steroid-treated rhesus monkeys also showed increased VOZ binding in the hypothalamus but not in the amygdala. The alteration of density of aromatase binding in the hypothalamic area could explain some psychological features of anabolic-androgenic steroid abusers.</p><p>Novel PET tracers for aromatase were developed and examined. The two newly synthesized ¹⁸F-labeled vorozole analogs, [¹⁸F]FVOZ and [¹⁸F]FVOO, displayed different characteristics. Both tracers showed similar binding pattern as VOZ; however, [¹⁸F]FVOO was metabolized very quickly, meaning that this tracer is not suitable as a PET tracer. On the other hand, [¹⁸F]FVOZ can be an appropriate PET tracer.</p><p>The role of aromatase in the human brain has not been clarified yet. To approach this problem by<i> in vivo</i> methods, we have just started PET studies to explore aromatase expression in humans.</p>

aromatase

brain

molecular imaging

PET

[11C]Vorozole

amygdala

hypothalamus

anabolic-androgenic steroids

abuse

[18F]Vorozole analogs

Neuroscience

Neurovetenskap

Homodyne High-harmonic Spectroscopy: Coherent Imaging of a Unimolecular Chemical Reaction

Beaudoin Bertrand, Julien

21 August 2012

At the heart of high harmonic generation lies a combination of optical and collision physics entwined by a strong laser field. An electron, initially tunnel-ionized by the field, driven away then back in the continuum, finally recombines back to rest in its initial ground state via a radiative transition. The emitted attosecond (atto=10^-18) XUV light pulse carries all the information (polarization, amplitude and phase) about the photorecombination continuum-to-ground transition dipolar field. Photorecombination is related to the time-reversed photoionization process. In this perspective, high-harmonic spectroscopy extends well-established photoelectron spectroscopy, based on charged particle detection, to a fully coherent one, based on light characterization. The main achievement presented in this thesis is to use high harmonic generation to probe femtosecond (femto=10^-15) chemical dynamics for the first time. Thanks to the coherence imposed by the strong driving laser field, homodyne detection of attosecond pulses from excited molecules undergoing dynamics is achieved, the signal from unexcited molecules acting as the reference local oscillator. First, applying time-resolved high-harmonic spectroscopy to the photodissociation of a diatomic molecule, Br2 to Br + Br, allows us to follow the break of a chemical bond occurring in a few hundreds of femtoseconds. Second, extending it to a triatomic (NO2) lets us observe both the previously unseen (but predicted) early femtosecond conical intersection dynamics followed by the late picosecond statistical photodissociation taking place in the reaction NO2 to NO + O. Another important realization of this thesis is the development of a complementary technique to time-resolved high-harmonic spectroscopy called LAPIN, for Linked Attosecond Phase INterferometry. When combined together, time-resolved high-harmonic spectroscopy and LAPIN give access to the complex photorecombination dipole of aligned excited molecules. These achievements lay the basis for electron recollision tomographic imaging of a chemical reaction with unprecedented angstrom (1 angstrom= 0.1 nanometer) spatial resolution. Other contributions dedicated to the development of attosecond science and the generalization of high-harmonic spectroscopy as a novel, fully coherent molecular spectroscopy will also be presented in this thesis.

Chemical Dynamics Imaging

Attosecond Science

High Harmonic Generation

Coherent Detection

Molecular Photonics

Ultrafast Lasers

Ultrafast Molecular Imaging

Molecular Photodissociation