Modification and Single-Laboratory Validation of AOAC Official Method 977.13 for Histamine in Seafood to Improve Sample Throughput.

Histamine is the main causative agent in scombrotoxin fish poisoning, the most frequently reported illness related to fish consumption. The AOAC official method for histamine determination in fish is the fluorometric method AOAC 977.13, which is sensitive and reproducible but somewhat labor intensive and time consuming. We investigated multiple modifications to this method in an attempt to reduce assay time and increase sample throughput while maintaining the performance of the original method. Some of the attempted modifications negatively affected the performance characteristics of the method. However, omitting the heating step during extraction and replacing the cuvette style fluorometer with a microplate reader retained method performance while increasing sample throughput. Therefore, we adopted these modifications and conducted a single-laboratory validation. The recovery, precision (RSD), and LOD of the modified method assessed by the single-laboratory validation ranged from 92 to 105%, 1 to 3%, and 0.2 to 0.5 ppm, respectively, in tuna, mahi-mahi, and Spanish mackerel samples. We conclude that the AOAC 977.13 fluorometric method, modified as described, will improve assay time and sample throughput efficiency cumulatively, as the number of sample units analyzed increases. We anticipate that this modified method could be used by regulatory agencies and other laboratories following successful multilaboratory validation.

Screening for petrochemical contamination in seafood by headspace solid-phase microextraction gas chromatography-mass spectrometry.

A headspace solid-phase microextraction gas chromatography-mass spectrometry (SPME GC-MS) method is described, to screen seafood for volatile organic compounds (VOCs) associated with petrochemical taint. VOCs are extracted from the headspace of heated sample homogenates by adsorption onto a SPME fiber and desorbed for analysis by GC-MS. Targeted compounds are determined semi-quantitatively using representative calibration standards for the various classes (alkanes, alkylbenzenes, indanes/tetralins, and naphthalenes) of VOCs analyzed. Sample preparation is minimal, and the analyses are rapid and automated with a capacity of 50 samples per day. The method was optimized in terms of headspace temperature, sample heating time, extraction time, and desorption time using oyster samples fortified with target compounds. Calibrations for hydrocarbon components were linear in the range of 8.3-167 ng/g; the limit of detection ranged between 0.05 and 0.21 ng/g, and the limit of quantitation between 0.16 and 0.69 ng/g. Good precision (RSD < 10 % at 16.7 ng/g for individual VOCs) and accuracy (recovery range 89-118 % at 25 ng/g) were obtained in oyster, crab, shrimp, and finfish matrices. The trueness of the method was demonstrated by quantifying VOCs at 1-2-ppb levels in oyster fortified with certified reference material NIST SRM 1491a. Following single laboratory validation, the method was employed for the determination of VOCs in seafood exposed to oil contaminated seawater and for the determination of background VOC levels in seafood species from the Gulf of Mexico and local food stores. The method as described can be used to supplement human sensory testing for petrochemical taint in seafood.

Propylene glycol accumulation associated with continuous infusion of lorazepam in pediatric intensive care patients.

OBJECTIVE: To determine if propylene glycol accumulates in children receiving continuous lorazepam infusion and, if accumulation occurs, to determine if it is associated with significant laboratory abnormalities. DESIGN: Prospective study. SETTING: A tertiary care pediatric intensive care unit. PATIENTS: Eleven intubated pediatric intensive care patients receiving continuous lorazepam infusion for sedation. INTERVENTIONS: Propylene glycol accumulation was determined by comparing concentrations at baseline, after 48 hrs, and at end of therapy. Laboratory abnormalities were determined by comparing serum lactate and osmolar gap at baseline, after 48 hrs, and at end of therapy. Correlation between the cumulative dose of lorazepam received and the propylene glycol concentration measured at the end of therapy was determined. MEASUREMENTS AND MAIN RESULTS: Patients aged 1-15 months were studied. Lorazepam infusion rates ranged from 0.1 to 0.33 mg.kg.hr and lasted 3-14 days. Propylene glycol accumulated significantly in patients receiving continuous infusion of lorazepam. The propylene glycol concentration increased during the study from 86 +/- 93 microg/mL at baseline to 763 +/- 660 microg/mL at the end of the study ( p=.038). A statistically significant correlation between the cumulative dose of lorazepam received and propylene glycol concentration at the end of therapy was demonstrated ( r(2)=.65, p<.005). However, the propylene glycol accumulation was not associated with significant laboratory abnormalities. Neither serum lactate concentrations nor osmolar gap were significantly elevated over baseline. CONCLUSION: Propylene glycol accumulated significantly in pediatric intensive care patients receiving continuous lorazepam infusion, and propylene glycol concentration correlated with the cumulative lorazepam dose the patient received. However, significant laboratory abnormalities due to propylene glycol accumulation were not observed.

Preparation of irreversibly sickled cell beta-actin from normal red blood cell beta-actin.

We have previously demonstrated that an oxidative change, the formation of a disulfide bridge between two cysteine residues, in the membrane protein beta-actin is primarily responsible for locking the irreversibly sickled red blood cells (ISCs) of sickle cell anemic patients into the sickle shape. To support studies on biological and chemical characterization of the oxidized beta-actin and pharmacological research toward the reversal of the oxidation, we attempted to prepare oxidized beta-actin from normal red blood cell (RBC) beta-actin by a chemical reaction, expecting a product equivalent to that found in ISCs. 5,5'-Dithiobis(2-nitrobenzoic acid) (DTNB, or Ellman's reagent) was used for the oxidation. We proved the absence of accessible sulfhydryl groups in the oxidized product using liquid chromatography (LC) with both UV and fluorescence detection. Polymerization assays indicated that the chemically produced ISC actin demonstrated the same kinetics as ISC actin obtained from patients with sickle cell disease. The effect of the oxidation could be reversed by the use of the reducing agent tris(carboxyethyl)phosphine (TCEP).