A.R. McCurdy

Bio: A.R. McCurdy is an academic researcher from University of Saskatchewan. The author has contributed to research in topics: Interesterified fat & Erucic acid. The author has an hindex of 14, co-authored 28 publications receiving 835 citations.

Functionality of Flours, Protein Fractions and Isolates from Field Peas and Faba Bean

Abstract: Field pca and faba bean proteins are rich sources of lysine, and air classification of the pin milled flours essentially doubled the protein contents in the protein fractions. The proteins in these flours and protein fractions were highly soluble at acid pH and exhibited only a narrow range of insolubility at pH 4–5. Water holding and oil absorption capacities increased in proportion to protein contents of the flour, protein fraction, and isolate of each legume, including soybean flour and isolate, but oil emulsification properties were uniformly high among all products. The protein fractions exhibited excellent whipp-ability and foam stability compared to soybean controls, and their promising functional properties suggested potential applications in meat emulsions, beverages and bakery products.

Detachment of "Pseudomonas fluorescens" from biofilms on glass surfaces in response to nutrient stress

Abstract: The effects of glucose and nitrogen depletion on the colonization of glass Petri plates byPseudomonas fluorescens were studied in batch culture. Colonization of the surfaces was initiated before colonization of the bulk phase, and biofilm formation was observed. This resulted in an apparent lag in the batch growth curve for the cell suspension. The lag phase was an artifact caused by the partitioning of cells between the bulk and solid phase of the culture and was not due to a reduction in the growth rate of unattached cells. The specific growth rate of the unattached cells (0.331 hour−1) was almost twice that determined for the total population (0.171 hour−1). Consequently the growth rate of biofilm-forming bacteria cannot be determined in batch culture unless the growth of both attached and unattached cells is monitored, and batch growth curves may contain artifacts due to the formation and dispersion of biofilms. The depletion of either glucose or nitrogen led to the active detachment of cells from the biofilm. An increase in the hydrophobicity of unattached cells was noted on depletion of carbon. This increase was the result of emigration of cells from the surface into the bulk phase.

Enzymatic pretreatment of deodorizer distillate for concentration of sterols and tocopherols

Abstract: Separation of sterols and tocopherols from fatty acids in deodorizer distillate was facilitated through lipase-catalyzed modification of fatty acids in canola, mixed and soya deodorizer distillates. The fatty acid esterification with methanol catalyzed by SP-382 (an immobilized nonspecific lipase) proceeded rapidly, with conversion of fatty acid to methyl ester in 5 h being 96.5, 83.5 and 89.4%, respectively. A model mixture of pure oleic acid and dl-α-tocopherol was used to study any potential side reactions that may lower the tocopherol content during the esterification reaction. Under the conditions employed, the loss of tocopherol was less than 5%. Simple vacuum distillation (1–2 mm Hg) was employed to remove the volatile fraction (methyl esters of fatty acids, some fatty acids and other volatiles) of the esterified deodorizer distillate, leaving behind sterols, sterol esters and tocopherols. Sterols and tocopherols were almost completely retained in the residue fraction with recoveries in the range of 95%. Overall recoveries of sterols and tocopherols after esterification and distillation were over 90% for all the deodorizer distillate samples.

Stereospecific analyses of seed triacylglycerols from high-erucic acid brassicaceae: Detection of erucic acid at thesn-2 position inBrassica oleracea L. Genotypes

Abstract: Stereospecific analyses of triacylglycerols from selected high-erucic acid breeding lines or cultivars ofBrassica napus L. andB. oleracea L. have been performed. Initial lipase screening revealed that while allB. napus lines contained little or no erucic acid at thesn-2 position, several of theB. oleracea lines had significant proportions of erucic acid at this position. Detailed stereospecific analyses were performed on the triacylglycerols from these lines by using a Grignard-based deacylation, conversion of thesn-1,sn-2 andsn-3 monoacylglycerols to their di-dinitrophenyl urethane (DNPU) derivatives, resolution of the di-DNPU-monoacylglycerols (MAGs) by high-performance liquid chromatography on a chiral column, transmethylation of eachsn-di-DNPU MAG fraction and analysis of the resulting fatty acid methyl esters by gas chromatography. The findings unequivocally demonstrate for the first time that, within the Brassicaceae, there existsB. oleracea germplasm containing seed oils with substantial erucic acid (30–35 mol%) at thesn-2 position. This has important implications for biotechnology and breeding efforts designed to increase the levels of erucic acid in rapeseed beyond 66 mol% to supply strategic industrial feedstocks. In the first instance, the germplasm will be of direct use in retrieving a gene encoding aBrassica lyso-phosphatidic acid acyltransferase with an affinity for erucoyl-CoA. In a breeding program, the germplasm offers promise for the introduction of this trait intoB. napus by interspecific hybridization and embryo rescue.

Detection of olive oil adulteration with canola oil from triacylglycerol analysis by reversed-phase high-performance liquid chromatography

Abstract: The objective of this study was to explore the use of reversed-phase high-performance liquid chromatography (RP-HPLC) as a means to detect adulteration of olive oil with less expensive canola oil. Previously this method has been shown to be useful in the detection of some other added seed oils; however, the detection of adulteration with canola oil might be more difficult due to similarities in fatty acid composition between canola oil and olive oil. Various mixtures of canola oil with olive oils were prepared, and RP-HPLC profiles were obtained. Adulteration of olive oil samples with less than 7.5% (w/w) canola oil could not be detected.

Should we stay or should we go: mechanisms and ecological consequences for biofilm dispersal.

Abstract: In most environments, bacteria reside primarily in biofilms, which are social consortia of cells that are embedded in an extracellular matrix and undergo developmental programmes resulting in a predictable biofilm 'life cycle'. Recent research on many different bacterial species has now shown that the final stage in this life cycle includes the production and release of differentiated dispersal cells. The formation of these cells and their eventual dispersal is initiated through diverse and remarkably sophisticated mechanisms, suggesting that there are strong evolutionary pressures for dispersal from an otherwise largely sessile biofilm. The evolutionary aspect of biofilm dispersal is now being explored through the integration of molecular microbiology with eukaryotic ecological and evolutionary theory, which provides a broad conceptual framework for the diversity of specific mechanisms underlying biofilm dispersal. Here, we review recent progress in this emerging field and suggest that the merging of detailed molecular mechanisms with ecological theory will significantly advance our understanding of biofilm biology and ecology.

Biofilm Dispersal: Mechanisms, Clinical Implications, and Potential Therapeutic Uses

Abstract: Like all sessile organisms, surface-attached communities of bacteria known as biofilms must release and disperse cells into the environment to colonize new sites. For many pathogenic bacteria, biofilm dispersal plays an important role in the transmission of bacteria from environmental reservoirs to human hosts, in horizontal and vertical cross-host transmission, and in the exacerbation and spread of infection within a host. The molecular mechanisms of bacterial biofilm dispersal are only beginning to be elucidated. Biofilm dispersal is a promising area of research that may lead to the development of novel agents that inhibit biofilm formation or promote biofilm cell detachment. Such agents may be useful for the prevention and treatment of biofilms in a variety of industrial and clinical settings. This review describes the current status of research on biofilm dispersal, with an emphasis on studies aimed to characterize dispersal mechanisms, and to identify environmental cues and inter- and intracellular signals that regulate the dispersal process. The clinical implications of biofilm dispersal and the potential therapeutic applications of some of the most recent findings will also be discussed.

One Biocatalyst–Many Applications: The Use of Candida Antarctica B-Lipase in Organic Synthesis

Abstract: The application of the B-component lipase from the yeast Candida antarctica in organic synthesis is reviewed. This enzyme has been found to be a particularly efficient and robust lipase catalyzing a surprising diversity of reactions including many different regio- and enantio-selec-tive syntheses. Furthermore, the C. antarctica B-lipase is an example of an enzyme for which its specificity has been predicted based on the crystal structure and modeling of the active site region. This prediction is compared to experimental observations and a very close correlation is found.