Control of felinine-derived malodor in cat litter.

OBJECTIVES: Malodors stemming from soiled cat litter are a major frustration for cat owners, despite the widespread use of absorbent litters with claims of odor control. Technologies for effective litter odor control have not been rigorously evaluated. Here, we report on the effectiveness of a novel litter formulation of 1-monochlorodimethylhydantoin (MCDMH)-modified clinoptilolite zeolite (MCDMH-Z) to control the odors of 3-mercapto-3-methylbutanol (3M3MB) and ammonia, the principal products generated by the enzymatic breakdown of felinine and urea, respectively. METHODS: The efficacy of MCDMH-Z for the odor control of 3M3MB was determined by solid-phase microextraction and gas chromatography mass spectrometry analysis, colorimetric analysis and a sensory panel. Enzyme inhibition was monitored by a colorimetric coupled assay for ammonia. The antimicrobial properties were measured by a reduction in colony-forming units (CFUs). RESULTS: 3M3MB proved highly susceptible to modification by MCDMH-Z granules. Headspace above litter exposed to MCDMH-Z showed no detectable 3M3MB; levels >59 ng were detected in commercially available products. Urease activity decreased by >97% after incubation with MCDMH-Z to 0.14 mg/ml. Cat litter F showed comparable inhibition (0.13 mg/ml); others showed less inhibition, producing up to 4.8 mg/ml of ammonia. MCDMH-Z reduced the CFUs of Proteus vulgaris by six log reduction values in 30 mins; in the same amount of time, no reduction was seen with commercial products tested. The odor control capability of the MCDMH-Z granules was further supported by a sensory panel scoring 3M3MB-spiked litters. CONCLUSIONS AND RELEVANCE: Samples of commercially available litter products showed an effect on malodor, or inhibition of urease, or contained antimicrobial activity; no samples were capable of accomplishing these concurrently. In contrast, MCDMH-Z granules were effective in all three test categories. Control of felinine-derived odors, in particular, has the potential to improve cat owner satisfaction, and may beneficially affect cat behaviors provoked by pheromonally active sulfurous metabolites deposited in the litter.

Role of cholesterol crystals in atherosclerosis is unmasked by altering tissue preparation methods.

Standard tissue preparation for light and scanning electron microscopy (SEM) uses ethanol as a dehydrating agent but that can also dissolve cholesterol crystals (CC) leaving behind empty tissue imprints or "clefts". Cholesterol crystals may contribute to plaque rupture by their sharp tips that can tear membranes and trigger inflammation. Therefore, use of ethanol in tissue processing can mask the pathological role of CC. Here we evaluated the amount of cholesterol dissolved from CC with single and complete series of standard graded ethanol concentrations (25-100%) used in tissue preparation. Also, solubility of CC in ethanol at physiological levels was measured. Furthermore, we compared the effect of ethanol on CC in fresh human atherosclerotic plaques to matched segments dehydrated using vacuum (-1 atm, 12h). Tissue crystal density ranging from 0 to +3 was measured semi-quantitatively by SEM. For CC exposed to 25% and 100% ethanol for 10 min each, 0.38% and 95% of CC were dissolved respectively. Also, increase in CC solubility was significant at physiological levels of ethanol (0.16%) compared to water (43.4 ± 18.0 ng/mL vs. 30.9 ± 13.9 ng/mL; p < 0.05). We speculate that this could represent a potential mechanism of cardio-protective effects of alcohol consumption. In atherosclerotic plaques, CC density was lower in ethanol vs. saline treatment (+1.2 vs. +2.8; P < 0.01) with visible dissolving noted by SEM. Ethanol has been used for centuries in tissue preparation for microscopy. Here we demonstrate how current tissue preparation methods greatly alter histological findings with SEM by masking the potential mechanism of plaque rupture.