Christopher P. Reinhardt

Cell Tracking Using Nanoparticles

Tracking cells in regenerative medicine is becoming increasingly important for basic cell therapy science, for cell delivery optimization and for accurate biodistribution studies. This report describes nanoparticles that utilize stable-isotope metal labels for multiple detection technologies in preclinical studies. Cells labeled with nanoparticles can be imaged by electron microscopy, fluorescence, and magnetic resonance. The nanoparticle-labeled cells can be quantified by neutron activation, thereby allowing, with the use of standard curves, the determination of the number of labeled cells in tissue samples from in vivo sources. This report describes the characteristics of these nanoparticles and methods for using these nanoparticles to label and track cells.

Estimation of glomerular filtration rate in dogs by plasma clearance of gadolinium diethylenetriamine pentaacetic acid as measured by use of an ELISA.

OBJECTIVE-To evaluate use of gadolinium diethylenetriamine pentaacetic acid (Gd-DTPA) to estimate glomerular filtration rate (GFR) by plasma clearance and use of an ELISA as the method of Gd-DTPA quantification. ANIMALS-16 dogs of various sexes and breeds (12 dogs were clinically normal, and 4 dogs were polyuric and polydipsic with no other clinical or biochemical abnormalities). PROCEDURES-GFR was estimated by measuring the plasma clearance of Gd-DTPA and iohexol by use of an ELISA and high-performance liquid chromatography (HPLC), respectively. The GFR was determined by use of a 1-compartment model for both methods. The GFRs obtained by Gd-DTPA plasma clearance were compared with those obtained by iohexol plasma clearance by use of correlation analysis, paired t tests, and limits of agreement analysis. A paired t test was used to evaluate differences between the 2 plasma clearance methods. RESULTS-A strong linear correlation (r(2) = 0.90) was found between GFRs derived from the plasma clearance of Gd-DTPA and those derived from the plasma clearance of iohexol. By use of limits of agreement analysis, almost all (13/14) dogs had Gd-DTPA GFRs that were within 12% of iohexol GFRs. The remaining dog had a Gd-DTPA GFR that was 45% higher than the iohexol GFR. There was no significant difference between Gd-DTPA GFRs and those obtained with iohexol. CONCLUSIONS AND CLINICAL RELEVANCE-This study revealed that plasma clearance of Gd-DTPA measured by use of an ELISA is an effective method to estimate GFR in dogs because it compared favorably with results for the iohexol-HPLC method.

Functional immunoassay technology (FIT), a new approach for measuring physiological functions: application of FIT to measure glomerular filtration rate (GFR)

This is the first description of functional immunoassay technology (FIT), which as a diagnostic tool has broad application across the whole spectrum of physiological measurements. In this paper, FIT is used to measure the renal clearance of an ultra low-dose administration of a clinically available contrast reagent for the purpose of obtaining an accurate glomerular filtration rate (GFR) measurement. Biomarker-based GFR estimates offer convenience, but are not accurate and are often misleading. FIT overcomes previous analytic barriers associated with obtaining an accurate GFR measurement. We present the performance characteristics of this diagnostic test and demonstrate the method by directly comparing GFR values obtained by FIT to those obtained by an FDA approved nuclear test in 20 adults. Two subjects were healthy volunteers and the remaining 18 subjects had diagnosed chronic kidney disease, with 12 being kidney transplant recipients. Measured GFR values were calculated by the classic UV/P method and by the blood clearance method. GFR obtained by FIT and the nuclear test correlated closely over a wide range of GFR values (10.9-102.1 ml.min(-1).1.73 m(-2)). The study demonstrates that FIT-GFR provides an accurate and reproducible measurement. This nonradioactive, immunoassay-based approach offers many advantages, chiefly that most laboratories already have the equipment and trained personnel necessary to run an ELISA, and therefore this important diagnostic measurement can more readily be obtained. The FIT-GFR test can be used throughout the pharmaceutical development pipeline: preclinical and clinical trials.

Polycationic Nanoparticles: (1) Synthesis of a Polylysine-MION Conjugate and its Application in Labeling Fibroblasts

Nanoparticles are increasingly used to label cells to track them by imaging or to quantify them in vivo. However, normal cellular uptake mechanisms are inadequate to load cells with tracking label. We propose a simple method to coat nanoparticles, such as monocrystalline iron oxide nanoparticle (MION), with the transfection agent polylysine in order to facilitate rapid, uniform, and heavy labeling of fibroblasts. The method is based on commercially available reagents, requires no more than 1xa0h of laboratory contact time, and can be accomplished safely without a chemical hood. A suspension of MION was treated by addition of solid sodium periodate to oxidize glucose residues of dextran and introduced aldehyde groups to the dextran coat surrounding MION’s crystalline magnetite core. After a 30-min incubation to effect oxidation, unreacted periodate was quenched with glycerol. The preparation was dialyzed to remove reactants and diluted to a final concentration of 2xa0mg Fe/ml. Poly-L-lysine was added to the oxidized MION (MION-A) to form reversible covalent Schiff base linkages. The resulting conjugate, a polylysine iron oxide nano-particle is abbreviated PLION. NIH3T3 fibroblasts labeled with either MION, MION-A, or MION plus polylysine showed minimal uptake of iron while cells labeled with PLION acquired a brown hue demonstrating strong labeling with iron. Microscopic assessment of iron labeling was confirmed using Prussian blue staining. In some cells, the concentration of iron was sufficiently high and localized to suggest association with cytoplasmic vacuoles. The nucleus of the cell was not labeled. Cell labeling increased when the ratio of polylysine to MION increased and with increasing amount of PLION.