Using Hemolysis as a Novel Method for Assessment of Cytotoxicity and Blood Compatibility of Decellularized Heart Tissues.

Developing patient-specific transplantable organs is a promising response to the increasing need of more effective therapies for patients with organ failure. Advances in tissue engineering strategies have demonstrated favorable results, including the use of decellularized hearts as scaffolds for cardiac engineering; however, there is a need to establish methods to characterize the cytotoxicity and blood compatibility of cardiac extracellular matrix (cECM) scaffolds created by decellularization. In this study, porcine hearts were decellularized in an automated perfusion apparatus utilizing sodium dodecyl sulfate (SDS) detergent. Residual SDS was measured by a colorimetric assay. Phosphate-buffered saline, distilled water (DW), and Triton X-100 washes were used to remove SDS. The efficiency of detergent removal was measured as a function of time. It was observed that using Triton-X 100 can nearly double the rate of SDS removal. An assay based on human blood hemolysis was developed to measure the remaining cytotoxicity of the cECM. The results from the hemolysis cytotoxicity assay were consistent with a standard live/dead assay using MS1 endothelial cells incubated with the cECM. This study demonstrated an effective, reliable, and relatively inexpensive method for determining the cytotoxicity and blood compatibility of decellularized cECM scaffolds.

A new approach for trace analysis of guanidine compounds in surface water with resorcinarene-based ion chromatography columns.

Trace levels of pharmaceuticals have been detected in surface water and may pose a health risk to humans and other organisms. New chromatographic materials will help identify and quantify these contaminants. We introduce a new ion chromatographic (IC) material designed to separate cationic pharmaceuticals and report its ability to separate a group of guanidine compounds. Guanidine moieties are strongly basic and protonated under acid conditions, and therefore can potentially be separated on the newly designed stationary phase and detected by ion exchange chromatography. The new column packing material is based on glutamic acids bonded to resorcinarene moieties that in turn are bound to divinylbenzene macroporous resin. Detection limits in the range of 5-30 µg L(-1) were achieved using integrated pulsed amperometric detection (IPAD) for guanidine (G), methylguanidine (MG), 1,1-dimethylbiguanide (DMG), agmatine (AGM), guanidinobenzoic acid (GBA) and cimetidine (CIM). Suppressed conductivity (CD) and UV-vis detection resulted in limits of detection similar to IPAD, in the range of 2-66 µg L(-1), but were not able to detect all of the analytes. Three water sources, river, lake, and marsh, were analyzed and despite matrix effects, sensitivity for guanidine compounds was in the 100 µg L(-1) range and apparent recoveries were 80-96%. The peak area precision was 0.01-2.89% for IPAD, CD and UV-vis detection.

Separation of uremic toxins from urine with resorcinarene-based ion chromatography columns.

People with chronic kidney disease suffer from uremic toxins which accumulate in their bodies. Detection and quantification of uremic toxins help diagnose kidney problems and start patient care. The aim of this research was to seek a new method to assist this diagnosis by trace level detection and separation of guanidine containing uremic toxins in water and urine. To detect and quantify the uremic toxins, new stationary phases for ion chromatography (IC) columns based on glutamic acid functionalized resorcinarenes bound to divinylbenzene macroporous resin were prepared. The new column packing material afforded separation of the five compounds: guanidinoacetic acid, guanidine, methylguanidine, creatinine, and guanidinobenzoic acid in 30min. Peak resolutions ranged from 7.6 to 1.3. Gradient elutions at ambient temperature with methanesulfonic acid (MSA) solution as eluent resulted in detection levels in water from 10 to 47ppb and in synthetic urine from 28 to 180ppb. Limits of quantification for the analytes using pulsed amperometric detection were 30-160ppb in water and 93-590ppb in urine. Trace levels of creatinine (1ppm) were detected in the urine of a healthy individual using the columns.