Heat Modulation of Intrinsic MR Contrasts for Tumor Characterization

(1) Background: The longitudinal relaxation time (T1), transverse relaxation time (T2), water proton chemical shift (CS), and apparent diffusion coefficient (ADC) are MR quantities that change with temperature. In this work, we investigate heat-induced intrinsic MR contrast types to add salient information to conventional MR imaging to improve tumor characterization. (2) Methods: Imaging tests were performed in vivo using different rat tumor models. The rats were cooled/heated to steady-state temperatures from 26–36 °C and quantitative measurements of T1, T2, and ADC were obtained. Temperature maps were measured using the proton resonance frequency shift (PRFS) method during the heating and cooling cycles. (3) Results: All tissue samples show repeatable relaxation parameter measurement over a range of 26–36 °C. Most notably, we observed a more than 3.3% change in T1/°C in breast adenocarcinoma tumors compared to a 1% change in benign breast fibroadenoma lesions. In addition, we note distinct values of T2/°C change for rat prostate carcinoma cells compared to benign tissue. (4) Conclusion: These findings suggest the possibility of improving MR imaging visualization and characterization of tissue with heat-induced contrast types. Specifically, these results suggest that the temporal thermal responses of heat-sensitive MR imaging contrast mechanisms in different tissue types contain information for improved (i) characterization of tumor/tissue boundaries for diagnostic and therapy purposes, and (ii) characterization of salient behavior of tissues, e.g., malignant versus benign tumors.

Temporal Exposure of Dermal Fibroblasts to Silver Diamine Fluoride and Fluorine NMR Quantitation

Objective: Silver diamine fluoride has been advocated as a caries arresting material for Early Childhood Caries (ECC) and has received considerable public attention as the “silver bullet”. However, cytotoxicity tests on the current concentrations of Silver Diamine Fluoride (SDF) to soft tissue have not been thoroughly assessed and analyzed at selected time intervals. The level of fluoride that is present within human cells has yet to be quantified. Preliminary SDF toxicity studies in our lab determined exposures of Dermal Fibroblasts to 0.03% SDF for 18 hours resulted in 100% cytotoxicity and complete monolayer loss. Endpoint titration of SDF determined that morphologic cytotoxic effects were ameliorated at input SDF levels lower than 0.002%. Because of the small culture sample volumes, we were unable to effectively assay fluoride concentrations using commercially available assays. In this study we attempted to assess fluoride levels in culture supernatants in a temporal fashion using quantitative Nuclear Magnetic Resonance (NMR). Study design: Dermal Fibroblast (DF) cells were grown in 24 well cluster plates fitted with 0.4 micron TranswellTM inserts to confluency in 0.9mL of DF culture media. Then the DF cells were challenged with 0.1 mL of SDF in sterile water in the Transwell chamber to achieve a final concentration of 0.03% SDF. Cultures were reincubated for 30 minutes, 1, 2, 4 and 8 hours. At the selected time points Transwell inserts were removed. SDF culture media was removed and replaced with fresh media and allowed to re-incubate up to 8 hours. Harvested SDF culture media was centrifuged at 15,000 x g to remove any resulting SDF precipitates and supernatants were harvested and stored at −70°C for fluoride assay. After 8 hours, media was aspirated from all wells and DF cells were fixed and then stained with methylene blue and assessed for cytotoxicity. Harvested supernatants were assessed for fluoride content. While SDF is soluble in pure water, it precipitates instantly in the presence of other media constituents and 0.85% saline. Transwells inserts capture the precipitate but allow soluble SDF and constituents pass through to the cell monolayer. NMR was used to assess SDF (fluoride) prepared in water, in DF media or in normal saline at the same concentrations used in the DF cell studies. The 19F NMR spectra were acquired at 25 °C on an Agilent DD2 500 MHz spectrometer equipped with a 5mm HFX z gradient probe operating at 470.3 MHz for fluorine. For quantitative measurements, all spectra were collected with 64 scans and a delay of 5 seconds. The spectrum width is 220 ppm with offset at resonance of −110 ppm. The processing and analyzing were done by MNOVA. The dataset consists 45371 complex points and is zero-filled to the size of 128k points after applying 5Hz exponential line broadening. The 19F chemical shift was referenced indirectly based on proton chemical shift, which was referenced with respect to the water proton signal of 4.75 ppm at 25°C. Results: Visible DF cell morphology changes begin to appear as early as 1 hour exposure to 0.03% SDF in Transwells and continue with degradation of cell morphology through 8 hours exposure at which point 100% of the cell monolayer is lost. The 8 hour image shows complete cell loss which is consistent with earlier studies using 24 hour exposures at 0.03% concentration. Note that the actual concentration of SDF affecting cell viability is shown in this study to be far lower than the 0.03% input because of the aggregate precipitation captured with the Transwell inserts. In this study, our NMR fluoride assessments showed that only 6–12 % of the input SDF fluoride reaches the lower cell chamber. Conclusions: Considering that the SDF reagent is applied orally at ~40%, these results warrant more refined testing to identify true lower limit of toxicity end points of SDF. SDF should be utilized only by trained professionals and never contact soft tissue. NMR may be utilized to determine relative amounts of fluoride both in cell culture media and within fluoride exposed cells.

Preparation, Performance and Challenges of Catalyst Layer for Proton Exchange Membrane Fuel Cell

In this paper, the composition, function and structure of the catalyst layer (CL) of a proton exchange membrane fuel cell (PEMFC) are summarized. The hydrogen reduction reaction (HOR) and oxygen reduction reaction (ORR) processes and their mechanisms and the main interfaces of CL (PEM|CL and CL|MPL) are described briefly. The process of mass transfer (hydrogen, oxygen and water), proton and electron transfer in MEA are described in detail, including their influencing factors. The failure mechanism of CL (Pt particles, CL crack, CL flooding, etc.) and the degradation mechanism of the main components in CL are studied. On the basis of the existing problems, a structure optimization strategy for a high-performance CL is proposed. The commonly used preparation processes of CL are introduced. Based on the classical drying theory, the drying process of a wet CL is explained. Finally, the research direction and future challenges of CL are pointed out, hoping to provide a new perspective for the design and selection of CL materials and preparation equipment.

Polyaspartic Acid-Coated Paramagnetic Gadolinium Oxide Nanoparticles as a Dual-Modal T1 and T2 Magnetic Resonance Imaging Contrast Agent

Surface-coating polymers contribute to nanoparticle-based magnetic resonance imaging (MRI) contrast agents because they can affect the relaxometric properties of the nanoparticles. In this study, polyaspartic acid (PASA)-coated ultrasmall Gd2O3 nanoparticles with an average particle diameter of 2.0 nm were synthesized using the one-pot polyol method. The synthesized nanoparticles exhibited r1 and r2 of 19.1 and = 53.7 s−1mM−1, respectively, (r1 and r2 are longitudinal and transverse water–proton spin relaxivities, respectively) at 3.0 T MR field, approximately 5 and 10 times higher than those of commercial Gd-chelate contrast agents, respectively. The T1 and T2 MR images could be obtained due to an appreciable r2/r1 ratio of 2.80, indicating their potential as a dual-modal T1 and T2 MRI contrast agent.

Chitosan Oligosaccharide Lactate-Coated Ultrasmall Gadolinium Oxide Nanoparticles: Synthesis, In Vitro Cytotoxicity, and Relaxometric Properties

In this study, hydrophilic and biocompatible chitosan oligosaccharide lactate (COL)-coated ultra-small gadolinium oxide nanoparticles (NPs) were synthesized through a one-pot polyol method and characterized by various experimental techniques. The In Vitro cellular cytotoxicity assay indicated that the COL-coated gadolinium oxide NPs were non-toxic up to 500 μM Gd. In addition, their water proton spin relaxivities (i.e., r1 and r2) were estimated to be 13.0 and 27.0 s−1mM−1, respectively, which are higher than those of commercial magnetic resonance imaging (MRI) contrast agents. The application potential of the solution sample as a T1 MRI contrast agent was demonstrated In Vitro by measuring map images in which dose-dependent contrast enhancements were observed.

Inspecting Insulin Products Using Water Proton NMR. I. Noninvasive vs Invasive Inspection

Background: There is a clear need to transition from batch-level to vial/syringe/pen-level quality control of biologic drugs, such as insulin. This could be achieved only by noninvasive and quantitative inspection technologies that maintain the integrity of the drug product. Methods: Four insulin products for patient self-injection presented as prefilled pens have been noninvasively and quantitatively inspected using the water proton NMR technology. The inspection output is the water proton relaxation rate R2(1H2O), a continuous numerical variable rather than binary pass/fail. Results: Ten pens of each product were inspected. R2(1H2O) displays insignificant variation among the 10 pens of each product, suggesting good insulin content uniformity in the inspected pens. It is also shown that transferring the insulin solution out of and then back into the insulin pen caused significant change in R2(1H2O), presumably due to exposure to O2 in air. Conclusions: Water proton NMR can noninvasively and quantitatively inspect insulin pens. wNMR can confirm product content uniformity, but not absolute content. Its sensitivity to sample transferring provides a way to detect drug product tampering. This opens the possibility of inspecting every pen/vial/syringe by manufacturers and end-users.

Survey of water proton longitudinal relaxation in liver in vivo

Objective To determine the variability, and preferred values, for normal liver longitudinal water proton relaxation rate R1 in the published literature. Methods Values of mean R1 and between-subject variance were obtained from literature searching. Weighted means were fitted to a heuristic and to a model. Results After exclusions, 116 publications (143 studies) remained, representing apparently normal liver in 3392 humans, 99 mice and 249 rats. Seventeen field strengths were included between 0.04 T and 9.4 T. Older studies tended to report higher between-subject coefficients of variation (CoV), but for studies published since 1992, the median between-subject CoV was 7.4%, and in half of those studies, measured R1 deviated from model by 8.0% or less. Discussion The within-study between-subject CoV incorporates repeatability error and true between-subject variation. Between-study variation also incorporates between-population variation, together with bias from interactions between methodology and physiology. While quantitative relaxometry ultimately requires validation with phantoms and analysis of propagation of errors, this survey allows investigators to compare their own R1 and variability values with the range of existing literature.

An in-situ MRI method for quantifying temperature change of hydrate growth in a porous medium

The intricacy of the thermo-hydro-chemically coupled process of hydrate phase transition requires real-time in-situ observations, therefore, thermometry maps are of particular value to reveal the heat transfer process during crystal growth and dissociation. By using the temperature dependence of water proton chemical shift, the temporally- and spatially-resolved thermometry of tetrahydrofuran hydrate growths is presented in this study. Images of temperature changes were synchronously obtained by a 9.4 T 1H Magnetic Resonance Imaging (MRI) system, in order to predict the saturation of aqueous solution, solid hydrate phases, and the positive temperature anomaly of exothermic reaction. Variations of MRI signal decrease and histories of temperature rise differ significantly in space and time, which have a great use for analyzing the physical micro-mechanism and the heat transfer process of hydrate growth. The extension of these predicted results could have important implications for optimizing the phase transition process of gas hydrates.

Revisiting paramagnetic relaxation enhancements in slowly rotating systems: how long is the long range?

Cross-relaxation terms in paramagnetic systems that reorient rigidly with slow tumbling times can increase the effective longitudinal relaxation rates of protons of more than 1 order of magnitude. This is evaluated by simulating the time evolution of the nuclear magnetization using a complete relaxation rate-matrix approach. The calculations show that the Solomon dependence of the paramagnetic relaxation rates on the metal–proton distance (as r−6) can be incorrect for protons farther than 15 Å from the metal and thus can cause sizable errors in R1-derived distance restraints used, for instance, for protein structure determination. Furthermore, the chemical exchange of these protons with bulk water protons can enhance the relaxation rate of the solvent protons by far more than expected from the paramagnetic Solomon equation. Therefore, it may contribute significantly to the water proton relaxation rates measured at magnetic resonance imaging (MRI) magnetic fields in the presence of slow-rotating nanoparticles containing paramagnetic ions and a large number of exchangeable surface protons.