We investigated the antimicrobial effect of constituents of the American cranberry (Vaccinium macrocarpon); sugar plus organic acids, phenolics, and anthocyanins, against Escherichia coli O157:H7. Each fractional component was assayed over a 24-h period with 5-log initial inocula to determine the minimal inhibitory concentration (MIC), minimal bactericidal concentration (MBC), and log CFU/ml reductions, at their native pH and neutral pH. Each fraction produced significant reductions (P0.05) at the native pH: MICs for sugars plus organic, phenolics, and anthocyanins were 5.6/2.6 Brix/acid (citric acid equivalents) 2.70g/L (gallic acid equivalent), and 14.80mg/L (cyanidin-3-glucoside equivalent), respectively. Sugars plus organic acids at native pH (3) produced a reduction below detectable limits (1 log CFU/ml) compared to the control at 24h for 11.3/5.2 and 5.6/2.6 Brix/acid. Phenolics at native pH (4) produced reductions below detectable limits compared to the control at 24h and initial inocula for treatments of 5.40 and 2.70g/L. Anthocyanins at native pH (2) produced reductions below detectable limits for treatments of 29.15 and 14.80mg/L cyanidin-3-glucoside equivalents. Neutralized phenolics and anthocyanins had the same MIC and MBC as those at their native pH. Neutralized sugars plus organic acids did not inhibit bacterial growth compared to the control. Neutralized phenolics reduced bacteria below detectable limits in treatments of 5.40g/L and 2.70g/L compared to the control. Neutralized anthocyanins reduced bacterial growth below detectable limits at the concentration of 29.15mg/L, but at 14.80mg/L there was no significant reduction. Stationary-phase cells of E. coli O157:H7 were treated with 5% of each fraction in 0.8% NaCl for 20min and viewed under transmission electron microscopy. All fractions caused significant damage compared the control. Sugars plus organic acids caused visible osmotic stress, while phenolics and anthocyanins caused disintegration of the outer membrane.

This cross-sectional study determined the phenolic composition of an over-the-counter cranberry juice (CBJ) with high-performance liquid chromatography and examined the effects of low- and normal-calorie CBJ formulations on the postprandial glycemic response in healthy humans. The CBJ used in this study contained seven phenolic acids, with 3- and 5-caffeoylquinic acid being the primary components, and 15 flavonol glycosides, with myricetin-3-galactoside and quercetin-3-galactoside being the most prevalent. CBJ proanthocyanidins consisted of three different tetramers and a heptamer, which were confirmed with matrix-assisted laser desorption ionization-time of flight-mass spectrometry analysis. Participants received one of the following six treatments: nothing (no water/beverage), water (480 mL), unsweetened low-calorie CBJ (38 Cal/480 mL), normal-calorie CBJ (280 Cal/480 mL), isocaloric normal calorie (high fructose corn syrup [HFCS]), or isocaloric low-calorie beverages. No significant differences in postprandial blood glucose or insulin were observed in the groups receiving nothing, water, or low-calorie treatments. In contrast, the ingestion of normal-calorie CBJ and normal-calorie control beverage resulted in significantly higher blood glucose concentrations 30 minutes postprandially, although the differences were no longer significant after 180 minutes. Plasma insulin of normal-calorie CBJ and control (HFCS) recipients was significantly higher 60 minutes postprandially, but not significantly different 120 minutes postprandially. CBJ ingestion did not affect heart rate or blood pressure. This study suggests that the consumption of a low-calorie CBJ rich in previously uncharacterized trimer and heptamer proanthocyanidins is associated with a favorable glycemic response and may be beneficial for persons with impaired glucose tolerance.

Research about biodegradable antimicrobial films continues to receive a lot of attention due to the plastic pollution crisis and the need for environment-friendly and safe food products. In this study, we developed chitosan-based antimicrobial films using a combination of encapsulated lemon essential oil (LEO) by ionic gelation and cranberry juice and evaluated the performance of the films. Our results indicated that the incor-poration of LEO microspheres and cranberry juice into the chitosan films improved the UV barrier and thermal properties as well as antioxidant activity of the films. The increase in antioxidants was consistent with the chemical components in LEO and cranberry juice as determined by GC-MS; some of which possess antioxidant properties. Furthermore, following antimicrobial activity test, considerable inhibition halo of 11 and 20 mm were observed respectively against fungi Candida albicans and Penicillium roqueforti, particularly in presence of the film containing both LEO microspheres and cranberry juice.