Targeted Molecular MR Imaging of HER2 and EGFR Using De Novo Designed Protein Contrast Agents

Qiao, Jingjuan

08 December 2011

The application of magnetic resonance imaging (MRI) to non-invasively assess disease biomarkers has been hampered by lack of desired contrast agents with high relaxivity, targeting capability, and optimized pharmacokinetics. We developed a novel MRI probe which targets HER2, a biomarker for various cancers and a target for anti-cancer therapies. This multimodal HER2-targeted MRI probe integrates a rationally designed protein contrast agent with a high affinity HER2 affibody and near IR dye. Our probe can differentially monitor tumors with different HER2 levels in both cells and xenograft mice. In addition to its 10-fold higher dose efficiency compared to clinically-approved agent DTPA, our developed agent also exhibits advantages in crossing the endothelial boundary, tissue distribution, and tumor tissue retention as demonstrated by even distribution of the imaging probe across the entire tumor mass. Additionally, a second series of protein contrast agents that included affibody against EFGR developed with the capability to specifically target EGFR. These contrast agents have been utilized to monitor drug treatments and quantitatively analyze biomarker expression level. Furthermore, we anticipate these agents will provide powerful tools for quantitative assessment of molecular markers, and improved resolution for diagnosis, prognosis and drug discovery.

MRI

Contrast agent

Protein engineering

Gadolinium

Relaxivity

HER2

Synthesis of γ-Fe(2)O(3)-SiO(2) composite nanoparticles targeting magnetic resonance imaging and magnetic hyperthermia applications

Taboada Cabellos, Elena

23 October 2009

This PhD Thesis involves the development of a new synthetic protocol for iron oxide silica composite nanoparticles useful in MRI and magnetic hyperthermia. Our approximation combines the sol-gel chemistry and supercritical fluids to obtain biocompatible, spherical composite particles, with narrow particle size distribution. The composite particles showed very high values of relaxivity. We have also studied the dependence of the specific absorption rate with iron concentration. This manuscript is organized into seven chapters. Chapter 1 provides a general introduction to magnetic nanoparticles, their properties, synthesis, stabilization and applications, with special interest in the biomedical field. The aim of the chapter is to place the reader in the scientific context of the thesis. Chapter 2 describes the synthesis of nanoparticles by thermal decomposition of an iron complex, Fe(CO)5, and their characterization in solid and colloidal dispersion. Silica coating is a convenient approach to stabilize nanoparticles in a biocompatible way. In this thesis we have developed a new synthetic protocol to coat iron oxide nanoparticles with silica that combines the sol-gel chemistry and supercritical fluids. To understand and control the details of this procedure, we first synthesized nano- and microparticles of silica. They are described in Chapter 3. Chapter 4 includes the synthesis of the composite γ-Fe2O3@SiO2 nanoparticles. The core is composed of clustered iron oxide nanoparticles (described in Chapter 2) surrounded by a silica shell. Chapter 4 also describes the material characterization, with special emphasis on the magnetic properties, which will be exploited in the biomedical applications. We also succeeded in synthesizing composite ε-Fe2O3@SiO2 nanospheres from the previous γ-Fe2O3@SiO2 particles. The evaluation of the materials described in Chapters 2 and 4 as contrast agents for magnetic resonance imaging and as mediators for magnetic hyperthermia is included in Chapter 5. Chapter 6 lists the main conclusions derived from the present thesis. Finally, Chapter 7 gathers the annexes. It includes four publications arising from the main subject of this thesis, as well as five other publications and a patent on projects that I worked during the time that has lasted my doctoral thesis. The annexes also include a brief description of the experimental techniques used and protocols for sample preparation.

Nanoparticles

Supercritical fluids

Contrast Agent

Ciències Experimentals

621.3

Design of Novel Protein-based MRI Contrast Agernets with High Relaxivity and Stability for Biomedical Imaging

Xue, Shenghui

22 July 2013

Magnetic resonance imaging (MRI) is the leading imaging technique for disease diagnostics. MRI contrast agents facilitate MRI technique to obtain tissue-specific image with improved sensitivity and signal-to-noise ratio. However, the applications of current MRI contrast agents are hampered by their uncontrolled blood circulation time, low relaxivity, and low specificity. To address such need, I have developed a series of analitical methods to determine and evaluate the strong metal binding affinity and metal selectivity of developed protein-based contrast agents (ProCAs). In addition, we have successed designed contrast agents ProCA3 series based on key determinats for metal binding sites and relaxivity. We have dementrated that one of the ProCA3 variants, ProCA32, has a high Gd3+ affinity less than 10-21 M and high metal selectivity with relxivity of more than 30 mM-1s-1 per Gd and 60 mM-1s-1 per particle. Moreover, we have demonstrated that ProCA3 variants have proper blood circulation time, high relaxivity, high metal selectivity and low toxicity, which facilitate MR imaging of multiple organs, such as liver, kidney, and blood vessels, as well as tumors. ProCA32 is also able to image liver metastases a tumor size less than 0.25 mm, which is more than fourty times more sensitive than that of clinical diagnostics of liver metastases using MRI and our developed methodology. We have further created ProCA3 variants with targeting peptide moieties such as ProCA3.bomb or ProCA3.affi to against cancer biomarkers such as GRPR and HER2 with capability to imaging tumor biomarker expressions in vivo at molecular level. We have shown that ProCA3 has an excellent safety profile and pharmacokinetics for MRI in animals. With our additional effect in protein expression, modification, and scale up production of these developed protein contrast agents, ProCA3 is expected to be a promising MRI contrast for the diagnostics for disease, such as metastatic tumor and blood vessel abnormalities, and tumor biomarkers.

MRI contrast agent

Gadolinium

Melanoma

Tumor diagnostics

Liver metastasis

Relaxivities

MRI Contrast Enhancement using Gd2O3 Nanoparticles

Klasson, Anna

January 2008

There is an increasing interest for nanomaterials in biomedical applications and in this work, nanoparticles of gadolinium oxide (Gd2O3) have been investigated as a novel contrast agent for Magnetic Resonance Imaging (MRI). Relaxation properties have been studied in aqueous solutions as well as in cell culture medium and the nanoparticles have been explored as cell labeling agents. The fluorescent properties of the particles were used to visualize the internalization in cells and doped particles were also investigated as a multimodal agent that could work as a fluorescent marker for microscopy and as a contrast enhancer for MRI. Results show that in aqueous solutions, there is a twofold increase in relaxivity for Gd2O3 compared to commercial agent Gd-DTPA. In cell culture medium as well as in cells, there is a clear T1 effect and a distinct increase in signal intensity in T1-mapped images. Fluorescent studies show that the Gd2O3 nanoparticles doped with 5% terbium have interesting fluorescent properties and that these particles could work as a multimodal contrast agent. This study shows that Gd2O3 nanoparticles possess excellent relaxation properties that are retained in more biological environments. Gd2O3 particles are suitable as a T1 contrast agent, but seem also be adequate for T2 enhancement in for instance cell labeling experiments.

nanoparticles

gadolinium oxide

magnetic resonance imaging

contrast agent

Medicine

Medicin

MRI Contrast Enhancement using Gd₂O₃ Nanoparticles

Klasson, Anna

January 2008

<p>There is an increasing interest for nanomaterials in biomedical applications and in this work, nanoparticles of gadolinium oxide (Gd₂O₃) have been investigated as a novel contrast agent for Magnetic Resonance Imaging (MRI). Relaxation properties have been studied in aqueous solutions as well as in cell culture medium and the nanoparticles have been explored as cell labeling agents. The fluorescent properties of the particles were used to visualize the internalization in cells and doped particles were also investigated as a multimodal agent that could work as a fluorescent marker for microscopy and as a contrast enhancer for MRI.</p><p>Results show that in aqueous solutions, there is a twofold increase in relaxivity for Gd₂O₃ compared to commercial agent Gd-DTPA. In cell culture medium as well as in cells, there is a clear T₁ effect and a distinct increase in signal intensity in T₁-mapped images. Fluorescent studies show that the Gd₂O₃ nanoparticles doped with 5% terbium have interesting fluorescent properties and that these particles could work as a multimodal contrast agent.</p><p>This study shows that Gd₂O₃ nanoparticles possess excellent relaxation properties that are retained in more biological environments. Gd₂O₃ particles are suitable as a T₁ contrast agent, but seem also be adequate for T₂ enhancement in for instance cell labeling experiments.</p>

nanoparticles

gadolinium oxide

magnetic resonance imaging

contrast agent

Medicine

Medicin

Characterization and Applications for A Polymerized DiaCEST Contrast Agent

Bontrager, Jordan G.

January 2015

MRI can benefit from an increase in the sensitivity of contrast agents. The CEST MRI technique in particular suffers from very poor sensitivity when using diamagnetic contrast agents. Polymerized CEST MRI contrast agents could increase the sensitivity per macromolecule over monomer contrast agents. The increase in sensitivity is related to the increase in number of contrast agents per polymer. A contrast agent with increased sensitivity can be used to image on the molecular level in vivo, where the concentration of targets is very low. A polymerized diaCEST contrast agent was synthesized by coupling a salicylic acid analogue to a poly (acrylic acid) backbone. The CEST effect of the coupled analogue was compared to its uncoupled form for different concentrations and pH values. A RL-QUEST method was used to calculate the exchange rate of the analogue for different pH values before and after coupling. The polymerized diaCEST agent was attempted to be loaded into DOPC and bis-SorbPC liposomes, and was also attempted to be targeted to folate receptors in a KB cell culture. These studies establish the foundation for translation of polymerized diaCEST contrast agents to additional in vitro and in vivo investigations.

diaCEST

polymer

QUEST

salicylic acid

sensitivity

Biomedical Engineering

contrast agent

Next Generation Lanthanide-based Contrast Agents for Applications in MRI, Multimodal Imaging, and Anti-cancer Therapies

Chaudhary, Richa

30 July 2008

A new class of polymer stabilized gadolinium trifluoride nanoparticles (NPs) have been developed as contrast agents for magnetic resonance imaging (MRI) and computed tomography (CT), with potential long term goals in targeted imaging and anti-cancer therapy. The NPs are comprised of a 90/10 mixture of GdF3/EuF3 and are coated with linear polyacrylic acid (PAA) chains consisting of 25 repeating units. The resulting aggregates are stable in serum and possess unprecedented mass relaxivities [i.e. ~100-200 s-1(mg/mL)-1]. Electron microscopy images reveal various NP morphologies which depend on the exact synthesis protocol. These include highly cross-linked oblong clusters with 30-70 nm cross sections, extensively cross-linked aggregates with 100-300 nm cross sections, and distinct polymer stabilized nanocrystals with 50 nm diameters. Their application as contrast agents in T1-weighted MRI studies, CT imaging at various X-ray energies, and preliminary rat brain perfusion studies was also tested. NP contrast enhancement was compared to Gd-DPTA (Magnevist®) and iopramide (Ultravist 300®) to demonstrate their high contrasting properties and potential as multimodal contrast agents.

gadolinium

MRI

nanoparticle

imaging

contrast agent

relaxivity

0494

Development of Novel Protein-Based MRI Contrast Agents for the Molecular Imaging of Cancer Biomarkers

Pu, Fan

18 December 2014

Temporal and spatial molecular imaging of disease biomarkers using non-invasive MRI with high resolution is largely limited by lack of MRI contrast agents with high sensitivity, high specificity, optimized biodistribution and pharmacokinetics. In this dissertation, I report my Ph. D. work on the development of protein-based MRI contrast agents (ProCAs) specifically targeting different cancer biomarkers, such as grastrin-releasing peptide receptor (GRPR), prostate specific membrane antigen (PSMA), and vascular endothelial growth factor receptor-2 (VEGFR-2). Similar to non-targeted ProCAs, these biomarker-targeted ProCAs exhibit 5 - 10 times higher r1 and r2 relaxivites than that of clinical MRI contrast agents. In addition, these biomarker-targeted ProCAs have high Gd3+ binding affinities and metal selectivities. The highest binding affinity of the three GRPR-targeted contrast reagents obtained by grafting a GRPR ligand binding moiety into ProCA32 for GRPR is 2.7 x 10-9 M. We further demonstrate that GRPR-targeted ProCAs were able to semi-quantitatively evaluate GRPR expression levels in xenograft mice model by MRI. In addition, we have also created a PSMA-targeted ProCA which has a binding affinity to PSMA biomarker of 5.2 x 10-7 M. Further, we developed VEGFR-targeted contrast agent which is able to image VEGFR2 in mice models using T1-weighted and T2-weighted sequences. Moreover, the relaxivities and coordination water numbers of ProCAs can be tuned by protein design of ProCA4. Since disease biomarkers are expressed in various tumors and diseases, our results may have strong preclinical and clinical implications for the diagnosis and therapeutics of cancer and other type of diseases.

MRI contrast agent

GRPR

prostate cancer

PSMA

VEGFR-2

On the Permeabilisation and Disruption of Cell Membranes by Ultrasound and Microbubbles

Karshafian, Raffi

21 April 2010

Therapeutic efficacy of drugs depends on their ability to reach the treatment target. Drugs that exert their effect within cells are constrained by an inability to cross the cell membrane. Methods are being developed to overcome this barrier including biochemical and biophysical strategies. The application of ultrasound with microbubbles increases the permeability of cell membranes allowing molecules, which otherwise would be excluded, to enter the intracellular space of cells; a phenomenon known as sonoporation. This thesis describes studies aimed at improving our understanding of the mechanism underpinning sonoporation and of the exposure parameters affecting sonoporation efficiency. Cancer cells (KHT-C) in suspension were exposed to ultrasound and microbubbles – total of 97 exposure conditions. The effects on cells were assessed through uptake of cell-impermeable molecules (10 kDa to 2 MDa FITC-dextran), cell viability and microscopic observations of the plasma membrane using flow cytometry, colony assay and electron microscopy techniques. Sonoporation was a result of the interaction of ultrasound and microbubbles with the cell membrane. Disruptions (30-100 nm) were generated on the cell membrane allowing cell impermeable molecules to cross the membrane. Molecules up to 2 MDa in size were delivered at high efficiency (~70% permeabilisation). Sonoporation was short lived; cells re-established their barrier function within one minute, which allowed compounds to remain inside the cell. Following uptake, cells remained viable; ~50% of sonoporated cells proliferated. Sonoporation efficiency depended on ultrasound and microbubble exposure conditions. Microbubble disruption was a necessary but insufficient indicator of ultrasound-induced permeabilisation. The exposure conditions can be tailored to achieve a desired effect; cell permeability of ~70% with ~25% cell death versus permeability of ~35% with ~2% cell death. In addition, sonoporation depended on position in the cell cycle. Cells in later stages were more prone to being permeabilised and killed by ultrasound and microbubbles. This study indicated that sonoporation can be controlled through exposure parameters and that molecular size may not be a limiting factor. However, the transient nature may necessitate that the drug be in close vicinity to target cells in sonoporation-mediated therapies. Future work will extend the investigation into in vivo models.

Ultrasound Therapy

Sonoporation

Drug Delivery

Microbubble contrast agent

0760

Next Generation Lanthanide-based Contrast Agents for Applications in MRI, Multimodal Imaging, and Anti-cancer Therapies

Chaudhary, Richa

30 July 2008

A new class of polymer stabilized gadolinium trifluoride nanoparticles (NPs) have been developed as contrast agents for magnetic resonance imaging (MRI) and computed tomography (CT), with potential long term goals in targeted imaging and anti-cancer therapy. The NPs are comprised of a 90/10 mixture of GdF3/EuF3 and are coated with linear polyacrylic acid (PAA) chains consisting of 25 repeating units. The resulting aggregates are stable in serum and possess unprecedented mass relaxivities [i.e. ~100-200 s-1(mg/mL)-1]. Electron microscopy images reveal various NP morphologies which depend on the exact synthesis protocol. These include highly cross-linked oblong clusters with 30-70 nm cross sections, extensively cross-linked aggregates with 100-300 nm cross sections, and distinct polymer stabilized nanocrystals with 50 nm diameters. Their application as contrast agents in T1-weighted MRI studies, CT imaging at various X-ray energies, and preliminary rat brain perfusion studies was also tested. NP contrast enhancement was compared to Gd-DPTA (Magnevist®) and iopramide (Ultravist 300®) to demonstrate their high contrasting properties and potential as multimodal contrast agents.

gadolinium

MRI

nanoparticle

imaging

contrast agent

relaxivity

0494