Design and Control of Nanoconfinement to Achieve Magnetic Resonance Contrast Agents with High Relaxivity.

The enhanced relaxation of hydrogen atoms of surrounding water from suitable contrast agent promotes magnetic resonance imaging as one of the most important medical diagnosis technique. The key challenge for the preparation of performant contrast agents for magnetic resonance imaging with high relaxivity is to ensure a high local concentration of contrast agent while allowing a contact between water and the contrast agent. Both requirements are answered by tailoring a semipermeable confinement for a gadolinium complex used as contrast agent. A locally high concentration is achieved by successfully encapsulating the complex in polymer nanocontainers that serves to protect and retain the complex inside a limited space. The access of water to the complex is achieved by carefully controlling the chemistry of the shell and the core of the nanocontainers. The confinement of the nanocontainers enables an increased relaxivity compared to an aqueous solution of the contrast agent. The nanocontainers are successfully applied in vivo to yield enhanced contrast in magnetic resonance imaging.

Certain types of iron oxide nanoparticles are not suited to passively target inflammatory cells that infiltrate the brain in response to stroke.

Intravenous administration of iron oxide nanoparticles during the acute stage of experimental stroke can produce signal intensity changes in the ischemic region. This has been attributed, albeit controversially, to the infiltration of iron-laden blood-borne macrophages. The properties of nanoparticles that render them most suitable for phagocytosis is a matter of debate, as is the most relevant timepoint for administration. Both of these questions are examined in the present study. Imaging experiments were performed in mice with 30 minutes of middle cerebral artery occlusion (MCAO). Iron oxide nanoparticles with different charges and sizes were used, and mice received 300 µmol Fe/kg intravenously: either superparamagnetic iron oxide nanoparticles (SPIOs), ultrasmall SPIOs, or very small SPIOs. The particles were administered 7 days before MCAO, at the time of reperfusion, or 72 hours after MCAO. Interestingly, there was no observable signal change in the ischemic brains that could be attributed to iron. Furthermore, no Prussian blue-positive cells were found in the brains or blood leukocytes, despite intense staining in the livers and spleens. This implies that the nanoparticles selected for this study are not phagocytosed by blood-borne leukocytes and do not enter the ischemic mouse brain.

Studying the effect of particle size and coating type on the blood kinetics of superparamagnetic iron oxide nanoparticles.

PURPOSE: Magnetic resonance imaging (MRI), one of the most powerful imaging techniques available, usually requires the use of an on-demand designed contrast agent to fully exploit its potential. The blood kinetics of the contrast agent represent an important factor that needs to be considered depending on the objective of the medical examination. For particulate contrast agents, such as superparamagnetic iron oxide nanoparticles (SPIOs), the key parameters are particle size and characteristics of the coating material. In this study we analyzed the effect of these two properties independently and systematically on the magnetic behavior and blood half-life of SPIOs. METHODS: Eleven different SPIOs were synthesized for this study. In the first set (a), seven carboxydextran (CDX)-coated SPIOs of different sizes (19-86 nm) were obtained by fractionating a broadly size-distributed CDX-SPIO. The second set (b) contained three SPIOs of identical size (50 nm) that were stabilized with different coating materials, polyacrylic acid (PAA), poly-ethylene glycol, and starch. Furthermore, small PAA-SPIOs (20 nm) were synthesized to gain a global insight into the effects of particle size vs coating characteristics. Saturation magnetization and proton relaxivity were determined to represent the magnetic and imaging properties. The blood half-life was analyzed in rats using MRI, time-domain nuclear magnetic resonance, and inductively coupled plasma optical emission spectrometry. RESULTS: By changing the particle size without modifying any other parameters, the relaxivity r(2) increased with increasing mean particle diameter. However, the blood half-life was shorter for larger particles. The effect of the coating material on magnetic properties was less pronounced, but it had a strong influence on blood kinetics depending on the ionic character of the coating material. CONCLUSION: In this report we systematically demonstrated that both particle size and coating material influence blood kinetics and magnetic properties of SPIO independently. These data provide key information for the selection of a contrast agent for a defined application and are additionally valuable for other nano areas, such as hyperthermia, drug delivery, and nanotoxicology.

Current limitations of molecular magnetic resonance imaging for tumors as evaluated with high-relaxivity CD105-specific iron oxide nanoparticles.

OBJECTIVE: Tumor imaging via molecular magnetic resonance imaging (MRI) that uses specific superparamagnetic iron oxide particles (SPIOs) has been addressed in the literature several times in the last 20 years. To our knowledge, none of the reported approaches is currently used for routine clinical diagnostic evaluation, nor are any in clinical development. This raises questions as to whether SPIO-enhanced molecular MRI is sensitive and specific enough for use in clinical practice. The aim of our preclinical study was to investigate the minimum requirements for obtaining sensitive molecular MRI for use in tumor evaluations under optimal conditions. The well-vascularized F9 teratocarcinoma tumor model, which exhibits high levels of the highly accessible target CD105 (endoglin), was used to compare the accumulation and visualization of target-specific SPIOs by MRI. MATERIAL AND METHODS: Superparamagnetic iron oxide particles were optimized in the following ways: (a) proton relaxivity was increased for higher imaging sensitivity, (b) a coating material was used for optimal loading density of the αCD105 antibody, and (c) binding activity to the target CD105 was increased. Binding activity and specificity were confirmed in vitro using enzyme-linked immunosorbent assay and in vivo using pharmacokinetic and biodistribution studies of 11 F9 teratoma-bearing mice together with micro-autoradiography. CD105 target expression was determined using immunohistochemistry and quantitative enzyme-linked immunosorbent assay. The transverse relaxation rate R2* was quantified by 3.0-T MRI in the tumors, kidneys, and muscles before and up to 60 minutes after injection in 11 mice. The use of [Fe]-labeled SPIOs for all in vivo experiments allowed for the direct correlation of the imaging results with SPIO accumulation. RESULTS: High-relaxivity αCD105-polyacrylic acid-SPIOs (r2 up to 440 L mmol Fe s) with strong binding activity accumulated specifically in tumors (1.4% injected dose/g) and kidneys (4.1% injected dose/g) in a manner dependent on the target concentration. The accumulation occurred within the first 3 minutes after injection. Visualization of specific SPIOs was accomplished with MRI. In contrast to the successful use of MRI in all examined kidneys (mean ± SEM ΔR2*, 61 ± 11 s), only 6 of 11 tumors (mean ± SEM ΔR2*, 15 ± 7 s) showed a clear signal when compared with the control even though optimal conditions were used. CONCLUSION: The accumulation of CD105-specific SPIOs in F9 mouse teratomas was robust. However, visualization of the specifically accumulated SPIOs by MRI was not reliable because of its limited signal detection sensitivity. We postulate that it will be challenging to improve the imaging properties of targeted SPIOs further. Therefore, molecular MRI by targeted SPIOs is currently not suitable for clinical tumor imaging using routinely applicable sequences and field strength.

Thermo-responsive columns for HPLC: The effect of chromatographic support and polymer molecular weight on the performance of the columns.

Recently a novel technique has been developed in chromatography, namely thermo-responsive chromatography. This employs the use of thermo-responsive polymers grafted onto pre-formed stationary phases for the separation of hydrophobic analytes. The resultant thermo-responsive silica exhibits temperature-controlled hydrophilic-hydrophobic properties. In this study, the themo-responsive polymers were grafted in situ into the pre-packed aminated silica columns. It was found that the molecular weight of the grafted thermo-responsive polymers should be optimized in order to obtain an efficient thermo-responsive column. Furthermore, within this study it was observed that the type of stationary phase (monolithic or packed beads) and the presence of mesoporosity in the system are important parameters influencing the final performance of the thermo-responsive column.

Thermo-responsive monolithic materials.

One of the recent major improvements of HPLC was the introduction of monolithic silica columns, which have the advantage of faster separation and lower back pressure as compared to common silica beads. Here, we present an interesting alternative to such reversed-phase monolithic columns by a convenient coupling route of a thermo-responsive polymer to hydrophilic silica monoliths. Poly(N-isopropylacrylamide) (PNIPAM) was polymerized in solution via a reversible addition fragmentation chain transfer (RAFT) polymerization technique and coupled then in situ onto an amino-modified silica monolithic column. These columns were compared with RP-18 monolithic columns in the separation of steroids under isocratic condition in aqueous mobile phase. Separation is optimized just by changing the temperature, instead of changing the mobile phase composition.