@article{liu_cadwallader_drake_2023, title={Identification of predominant aroma components of dried pea protein concentrates and isolates}, volume={406}, ISSN={["1873-7072"]}, DOI={10.1016/j.foodchem.2022.134998}, abstractNote={Pea protein is a growing plant-based protein ingredient. Pea proteins have characteristic undesirable flavors, leading to challenges in ingredient applications. The objective of this study was to characterize the flavor of pea proteins using descriptive sensory analysis and instrumental volatile compound analyses. Seven sensory attributes were identified in most pea proteins at variable intensities: cereal/grain, cardboard, green pea, beany/yellow pea, bitter, umami, and astringent. Other attributes, cheesy, doughy, sulfur, pyrazine, fecal, sweet aromatic and salty taste, were distinguishing flavors of some pea proteins (p < 0.05). The key aroma-active compounds in pea proteins were hexanal, heptanal, benzaldehyde, methional, 2-hexanone, 2-heptanone, 1-octen-3-one, 2-nonanone, 1-nonen-3-one, 1-pentanol, 2-pentyl furan, 2-isopropyl-3-methoxypyrazine, 2,5-dimethyl-3-(3-methylbutyl)-pyrazine and 2-methyl-isoborneol (present in all representative samples). Volatile compounds responsible for the majority of sample variation included 2-methyl butanal, (Z)-3-hexanal, (E,E)-2,4-decadienal, 1-octen-3-one, 2-decanone, 1-pentanol, 1-octen-3-ol, geosmin and 2,3-diethyl-5-methyl pyrazine (p < 0.05). This study can facilitate product development and flavor masking of various pea protein applications.}, journal={FOOD CHEMISTRY}, author={Liu, Yaozheng and Cadwallader, Dylan C. and Drake, MaryAnne}, year={2023}, month={Apr} }
 @article{cadwallader_gerard_drake_2023, title={The role of packaging on the flavor of fluid milk}, volume={106}, ISSN={["1525-3198"]}, DOI={10.3168/jds.2022-22060}, abstractNote={Few studies have addressed the effects of package material in the absence of light on contributions to fluid milk flavor. The objective of this study was to compare the sensory and chemical properties of fluid milk packaged in paperboard cartons, low-density polyethylene, high-density polyethylene (HDPE), polyethylene terephthalate (PET), linear low-density polyethylene (LLDPE), and glass. Pasteurized (high temperature short time, 77°C for 25 s) skim and whole milk were filled (280 mL ± 10 mL) into paperboard cartons, low-density polyethylene, HDPE, PET, LLDPE, and glass (control). Milks were stored at 4°C in the dark and sampled at d 0, 5, 10, and 15. Descriptive analysis was applied to document sensory profiles at each time point, and volatile compounds were extracted and identified by solid-phase microextraction with gas chromatography mass spectrometry and gas chromatography-olfactometry. Tetrad tests with consumers were conducted at d 10. Both skim and whole milks packaged in cartons had noticeable paperboard flavor by d 5 and higher levels of hexanal than skim and whole milks in other package types at d 5. Skim milks packaged in paperboard cartons and LLDPE had distinct refrigerator/stale flavor compared with milks in the other package types, concurrent with increased levels of refrigerator/package-related compounds including styrene, acetophenone and 2-ethyl-1-hexanol. Milks packaged in glass, PET and HDPE were not distinguished by consumers at d 10 post-processing. Package type influences fluid milk flavor, and these effects are greater in skim milk compared with whole milk. Paperboard cartons do not preserve milk freshness, as well as PET, HDPE, or glass, due to flavor migration and scalping. Glass remains an ideal barrier to preserve fluid milk flavor, but in the absence of light, HDPE and PET provide additional benefits while also maintaining fluid milk flavor.}, number={1}, journal={JOURNAL OF DAIRY SCIENCE}, author={Cadwallader, D. C. and Gerard, P. D. and Drake, M. A.}, year={2023}, month={Jan}, pages={151–167} }
 @article{rizzo_del toro-gipson_cadwallader_drake_2022, title={Identification of aroma-active compounds in Cheddar cheese imparted by wood smoke}, volume={105}, ISSN={["1525-3198"]}, DOI={10.3168/jds.2021-21697}, abstractNote={Cheddar cheese is the most popular cheese in the United States, and the demand for specialty categories of cheese, such as smoked cheese, are rising. The objective of this study was to characterize the flavor differences among Cheddar cheeses smoked with hickory, cherry, or apple woods, and to identify important aroma-active compounds contributing to these differences. First, the aroma-active compound profiles of hickory, cherry, and apple wood smokes were analyzed by solid-phase microextraction (SPME) gas chromatography-olfactometry (GCO) and gas chromatography-mass spectrometry (GC-MS). Subsequently, commercial Cheddar cheeses smoked with hickory, cherry, or apple woods, as well as an unsmoked control, were evaluated by a trained sensory panel and by SPME GCO and GC-MS to identify aroma-active compounds. Selected compounds were quantified with external standard curves. Seventy-eight aroma-active compounds were identified in wood smokes. Compounds included phenolics, carbonyls, and furans. The trained panel identified distinct sensory attributes and intensities among the 3 cheeses exposed to different wood smokes (P < 0.05). Hickory smoked cheeses had the highest intensities of flavors associated with characteristic "smokiness" including smoke aroma, overall smoke flavor intensity, and meaty, smoky flavor. Cherry wood smoked cheeses were distinguished by the presence of a fruity flavor. Apple wood smoked cheeses were characterized by the presence of a waxy, green flavor. Ninety-nine aroma-active compounds were identified in smoked cheeses. Phenol, guaiacol, 4-methylguaiacol, and syringol were identified as the most important compounds contributing to characteristic "smokiness." Benzyl alcohol contributed to the fruity flavor in cherry wood smoked cheeses, and 2-methyl-2-butenal and 2-ethylfuran were responsible for the waxy, green flavor identified in apple wood smoked cheeses. These smoke flavor compounds, in addition to diacetyl and acetoin, were deemed important to the flavor of cheeses in this study. Results from this study identified volatile aroma-active compounds contributing to differences in sensory perception among Cheddar cheeses smoked with different wood sources.}, number={7}, journal={JOURNAL OF DAIRY SCIENCE}, author={Rizzo, P. V. and Del Toro-Gipson, R. S. and Cadwallader, D. C. and Drake, M. A.}, year={2022}, month={Jul}, pages={5622–5640} }
 @article{sipple_schiano_cadwallader_drake_2021, title={Child preferences and perceptions of fluid milk in school meal programs}, volume={104}, ISSN={["1525-3198"]}, DOI={10.3168/jds.2020-19546}, abstractNote={School meal programs in the United States feed approximately 30 million children each day and account for the majority of child milk intake. Dairy consumption during childhood and adolescence has lasting effects on lifelong health status, so it is important for schools to ensure adequate consumption in this life stage by offering an appealing product. This study identified the intrinsic and extrinsic attributes that influence children's perceptions, attitudes, and consumption of fluid milk at school, especially as they relate to fluid milk packaging. An online choice-based conjoint survey (n = 211) and four 1-h focus groups (n = 31) were conducted with child milk consumers ages 8 to 13 yr to evaluate extrinsic attributes. The survey evaluated milk package attributes including packaging type, front-of-package graphics, package color, and labeled milk fat content. Focus group topics included preferences, usability, health, taste of fluid milk, and milk consumption habits. To evaluate intrinsic properties related to packaging, 3 varieties of milk (unflavored fat-free, unflavored low-fat, and chocolate-flavored fat-free) were produced and packaged in polyethylene-coated paperboard cartons, polyethylene terephthalate (PET) bottles, and high-density polyethylene (HDPE) bottles (all 250 mL). After 10 to 13 d of storage at 4°C under dark conditions, milks were evaluated by descriptive analysis and child acceptance testing (ages 8-13 yr; n = 126, 122, and 126 for each variety, respectively). Extrinsically, package type was the most important attribute to children, but graphics, nutritional labeling, branding, package size, and overall familiarity also drove preferences. The ideal milk packaging build from the conjoint survey was an HDPE bottle with blue-colored packaging and a cow graphic, labeled as low-fat milk. Intrinsically, all varieties of milks packaged in paperboard cartons developed package-specific flavors, including refrigerator/stale and paperboard, after 10 d of storage. These off-flavors were not detected in HDPE- or PET-packaged milks. For unflavored milks, child consumers preferred the flavor of PET or HDPE packaged milks over cartons, regardless of milk fat content, but preferences were not distinct for chocolate-flavored milk. The results of this study demonstrate that children's liking and preference for milk are driven by both intrinsic and extrinsic factors and suggest that improvements are needed to increase acceptance of milk currently served in school meal programs.}, number={5}, journal={JOURNAL OF DAIRY SCIENCE}, author={Sipple, L. R. and Schiano, A. N. and Cadwallader, D. C. and Drake, M. A.}, year={2021}, month={May}, pages={5303–5318} }
 @article{harwood_carter_cadwallader_drake_2020, title={The role of heat treatment in light oxidation of fluid milk}, volume={103}, ISSN={["1525-3198"]}, DOI={10.3168/jds.2020-18933}, abstractNote={Light-oxidized flavor (LOF) resulting from photooxidation of riboflavin following light exposure is one of the most common off-flavors in fluid milk. The sensory perception of LOF has been studied extensively in high temperature, short time pasteurized (HTST) milk, but few studies have evaluated ultrapasteurized (UP) milk. The objective of this study was to evaluate the role of heat treatment in the development of LOF in UP fluid skim milk. Skim milk was processed by HTST or by direct steam injection (DSI-UP) and subsequently exposed to 2,000-lx light-emitting diode light for various times. Sensory properties were monitored by descriptive analysis and threshold tests, and volatile compounds were evaluated by solid phase microextraction with gas chromatography-mass spectrometry. Dissolved oxygen and riboflavin were determined at each time point using an oxygen meter and ultra-performance liquid chromatography with a fluorescence detector, respectively. The entire experiment was performed in triplicate. Typical cardboard and mushroom flavors (LOF) were detected by trained panelists in HTST milk after 3.5 h of light exposure. In contrast, LOF was not detected by trained panelists in UP milk until 36 h of light exposure. Similarly, the best estimate threshold for LOF from untrained consumers (n = 101) was higher for DSI-UP milk (61.0 h) than for HTST milk (15.2 h). Milks with LOF were characterized by higher relative abundance of the lipid oxidation compounds hexanal and heptanal. Dissolved oxygen (DO) and riboflavin concentrations decreased with increased light exposure time, and the decrease was slower in UP milk compared with HTST milk. Initial DO concentration was investigated as a possible influence in LOF development because DSI-UP milks had lower initial DO concentrations than HTST milks. However, follow-up evaluations of deaerated HTST milks suggested that DO was not a significant factor in LOF development. These results demonstrate that UP milk is less sensitive to LOF than HTST milk, possibly due to sensory masking effects or antioxidant effects of volatile sulfur compounds. An enhanced understanding of light and storage effects on milks will assist with best practices when transporting and displaying fluid milk products for sale.}, number={12}, journal={JOURNAL OF DAIRY SCIENCE}, author={Harwood, W. S. and Carter, B. G. and Cadwallader, D. C. and Drake, M. A.}, year={2020}, month={Dec}, pages={11244–11256} }