Identification and characterization of some psychrotrophic heat resistant/sporeforming bacteria in the Grade A raw milk supply of Oregon

Meer, Ralph R.

07 August 1987

Heat resistant sporeforming psychrotrophic bacteria were isolated from raw milk samples from 59 Grade A farms in Oregon. Forty-nine of the 59 (83%) raw milk samples in this survey contained sporeforming psychrotrophic bacteria; isolates from twenty-four (40%) of the samples exhibited proteolytic properties. Populations of sporeforming psychrotrophic bacteria ranged from <10 to >10,000 CFU/mL for all samples. One hundred-two isolates were identified as Bacillus species. Twelve different Bacillus species were identified with B. licheniformis being the most predominate (18% of the samples) and B. laterosporus the least frequently isolated species, (2%). Fifty-eight percent of the bacilli isolates produced a bitter off-flavor and putrid odor, while 42% produced a fruity and/or rancid off-flavor when inoculated into sterile whole milk. Based on biochemical activity tests, 83% of the thermoduric isolates hydrolysed casein while 56% were proteolytic (in litmus milk), 57% demonstrated lipolytic activity and 31% produced acid in litmus milk. Forty-eight isolates that tested positive for proteolysis were evaluated quantitatively for activity, which ranged from 0.93 to 1.93 units (expressed as mM of alanine). Isolates of Bacillus cereus var. mycoides demonstrated significantly higher (p>0.05) proteolytic activity than other Bacillus species isolated. / Graduation date: 1988

Milk -- Microbiology

Milk -- Flavor and odor

Sporeforming bacteria

Bacillus (Bacteria)

Flavor chemistry of irradiated milk fat

Khatri, Lakho Lilaram

25 October 1965

Increasing interest has been shown in the irradiation sterilization and irradiation pasteurization of foods, but problems of off-flavors and odors are still unsolved, especially in the case of dairy products. From the flavor chemistry point of view, milk lipids are very highly susceptible to irradiation effects. Therefore, this investigation was designed to study some irradiation induced reactions involving flavor changes in the milk fat and to identify the volatile components produced in the milk fat upon irradiation. Milk fat, prepared from raw sweet cream and washed free of phospholipids, was first irradiated in the presence of air and under vacuum in glass vials at 4.5 Mrad with gamma rays from cobalt-60. The irradiation resulted in increase in TBA number, peroxide value, total monocarbonyls, bleaching of color, slightly rancid and typical candle-like off-flavors. Free fatty acids were also produced upon irradiation. The changes were more drastic in air along with production of a slight oxidized flavor. The monocarbonyls identified by column and paper chromatographic methods in irradiated milk fat include: C₁ through C₁₂, C₁₄ , and C₁₆ n-alkanals; C₃ through C₉, C₁₁, C₁₃ and C₁₅ alk-2-ones with only traces of C₆ and C₈ alk-2- ones; and C₅, C₆, C₉, and C₁₂ alk-2-enals. Irradiation of milk fat that had been dried over calcium hydride also caused free fatty acid production, especially short chain fatty acids. Methyl octanoate treated with calcium hydride and irradiated at 1.5, 3.0, 4.5, and 6.0 Mrad yielded small quantities of free octanoic acid, confirming that irradiation caused fission of the ester linkage even when traces of water were removed. The quantities of octanoic acid formed increased with increasing dose of irradiation. For identification of volatile components, the milk fat was irradiated in 307x409 'C' enameled cans under vacuum. The headspace analysis showed some air still left in the cans. Irradiation resulted in consumption of oxygen and production of hydrogen, carbon monoxide, carbon dioxide, and methane as identified in the headspace gases. The volatiles were isolated from the irradiated and control milk fats by low temperature, vacuum steam distillation at 40°C and 1-2 mm Hg. The volatile components were then extracted from the aqueous distillate with ethyl ether. The ethyl ether extract exhibited the typical candle-like defect. The ethyl ether concentrate was analyzed by combination of GLC and fast-scan mass spectrometric techniques. Identification of various components was achieved on the basis of mass spectral data and coincidence of gas chromatographic retention times. In the case of the components for which only GLC t[subscript r]/t[subscript r] evidence was available or the mass spectra obtained were not satisfactory, the identity assigned was only tentative. The volatile compounds that were positively identified to be present in irradiated milk fat are given below: n-Alkanes C₅ through C₁₇ 1-Alkenes C₅, C₇ through C₁₇ Fatty acids C₄, C₆, C₈ and C₁₀ n-Alkanals C₅ through C₁₁ Others γ-decalactone, δ-decalactone, 2-heptanone, benzene, ethyl acetate, chloroform, and dichlorobenzene. The tentative identification was obtained for the following compounds: γ-lactones C₆ and C₈ δ-lactones C₆, C₈, C₁₁, and C₁₂ 1, ?-alkadienes C₁₀, C₁₁, C₁₂, C₁₆ and C₁₇ iso-alkanes C₁₀, C₁₁, C₁₂, and C₁₃ Others methyl hexanoate, 2-hexanone, 4-heptanone and n-dodecanal. The compounds present in unirradiated control milk fat included: short chain fatty acids (C₄, C₆, C₈, and C₁₀), C₈, C₁₀, and C₁₂ δ-lactones, 2-heptanone, chloroform, dichlorobenzene, benzene, toluene, and ethyl-benzene. Only tentative identity was established for most of these components in control milk fat. Possible reaction mechanisms are presented for the formation of the compounds in irradiated milk fat. / Graduation date: 1966

Flavor

Dairy products -- Analysis

Dried milk

Milk -- Pasteurization

Milk -- Flavor and odor

Modifying Fatty Acid Composition of Bovine Milk by Abomasal Infusion or Dietary Supplementation of Seed Oils or Fish Oil

Bandara, Aloka B.

26 January 1998

The potential for enhancing oleic acid (cis-18:1) and linoleic acid (18:2) content and lowering medium chain fatty acid (MCFA) content of bovine milk was investigated by abomasal infusion or dietary supplementation of oils. In experiment 1, olive oil, sesame oil, sunflower oil, or fish oil was abomasally infused (155 to 219 g/d) into Jersey cows during the last 6 d of each of four 14-d periods. In experiment 2, canola oil, olive oil, high-oleic sunflower oil, or distilled water (control) was abomasally infused (342 to 371 g/d) into three Holsteins and three Jerseys during the last 5 d of each of four 10-d periods. The intestinal digestibility and concentration of cis-18:1 and 18:2 in milk were proportional to flow of these fatty acids to the duodenum. Also, greater concentration of cis-18:1 in milk was associated with lowered yield of MCFA. During olive oil or sesame oil infusion in experiment 1, for each 100 g of cis-18:1 infused into the abomasum, milk cis-18:1 yield was increased by an average of 47 g, and MCFA yield was reduced by 42 g. The yield of 18:2 in milk was increased by approximately 46 g for each 100 g of infused 18:2 during olive oil or sesame oil infusion. Milk produced during sesame oil infusion, however, had an off-flavor when evaluated by a taste panel. In experiment 2, each 100 g of cis-18:1 infused daily increased milk cis-18:1 yield in Holsteins and Jerseys by 41 and 39 g/d, respectively, whereas recovery of infused 18:2 was 34 g/d for Jerseys and 42 g/d for Holsteins. In experiment 3, 22 Jersey cows were fed a basal diet, or the basal diet supplemented with 3.5% high-oleic canola oil, 3.5% soybean oil, or 1.75% high-oleic canola oil plus 1.75% soybean oil for 5 wk. Dietary canola oil supplementation increased conjugated linoleic acid (CLA) percentage in milk to a moderate level without raising trans-18:1 percentage, whereas feeding either supplement containing soybean oil raised both CLA and trans-18:1 percentages. Concentrations of trans-18:1 and CLA in milk apparently reflected the extent of unsaturated fatty acid biohydrogenation in the rumen. Dietary supplementation with canola oil increased yield of cis-18:1 in milk by 21 g for each 100 g of supplemental cis-18:1 intake. Yield of 18:2 in milk was raised by 3 g for each 100 g of supplemental 18:2 intake by cows fed soybean oil. Using abomasal infusion as an indicator of the maximum potential for apparent recovery of cis-18:1 in milk (39 to 49%), cis-18:1 recovery in response to supplemental cis-18:1 in the diet was approximately half of the potential response due to partial biohydrogenation in the rumen. The apparent recovery of dietary 18:2 in milk was reduced to only one-tenth of the potential yield (31 to 47%) indicated by abomasal infusion of seed oils. Results indicated that the fatty acid profile of bovine milk was altered in a manner that would be beneficial to human health when cows were fed supplemental oleic acid, but further research should focus on safe and economical methods to protect dietary unsaturated fatty acids from biohydrogenation. / Ph. D.

oleic acid

linoleic acid

medium chain fatty acids

abomasal infusion

milk flavor

Ultra-high-temperature processed and conventionally processed milk in the preparation of instant pudding

Pearson, Joanne Miller

January 1985

Instant puddings were prepared using ultra-high-temperature (UHT) processed and conventionally (HTST) processed milk at 6°C and 23°C in six replicates of a 2X2 factorial design to determine the effect of milk type and temperature on apparent viscosity and gel strength of pudding. Apparent viscosity was estimated from linespread readings on separate 25 ml samples of pudding measured at 0, 5, 10, 15, and 30 minutes after preparation. Gel strength was determined from penetrometer readings on separate warm and refrigerated 100 ml samples of pudding measured at 15, 30, 60, and 90 minutes after preparation. Consumer evaluations of flavor and texture of the puddings were obtained as well as word descriptors of UHT milk by those consumers who had tried the product. A five-point hedonic scale of 1=dislike extremely to 5=like extremely was used by 200 consumers to register their perceptions of flavor and texture of the puddings. Apparent viscosity was greater with HTST milk, warm milk, and longer elapsed time. The combination of cold milk and shorter time was least viscous. Gel strength of refrigerated pudding was greater for HTST milk, cold HTST, and longer time. Nonrefrigerated pudding was firmer for HTST milk and cold milk. Shortest time resulted in softest gel strength, with no difference between other time periods. Although values from objective measures differed between puddings made with UHT and with HTST milk, consumer responses to the texture and the flavor of the puddings were similar for the four milk type by temperature variations. / M.S.

LD5655.V855 1985.P427

Consumers' preferences

Milk -- Flavor and odor -- Rating of

Milk -- Preservation

Puddings -- Rating of

Flavor comparison of ultra high temperature processed milk heated by Ohmic heating and conventional methods

He, Juan

20 March 2012

Ultra high temperature (UHT) processing can extend shelf life of milk to several months without refrigeration, which is more convenient and energy saving than pasteurized milk. However, the poor acceptance caused by "cooked" flavors limits its marketing growth, especially in United States. Ohmic heating, which has a more uniform and rapid heating than conventional UHT process, may minimized the flavor change during the thermal treatment. Flavor composition between Ohmic heated UHT milk and other traditionally processed UHT milk (direct steam injection and indirect plate heating) during 36 weeks storage were investigated in this study. A total of 20 volatile compounds were analyzed based on their importance to UHT milk as well as their representation to different chemical classes including sulfur-containing compounds, ketones, lactones, aldehydes and others. Dimethyl sulfide (DMS) and methyl ketones were significant different among three types of UHT heated milk. δ-lactones showed higher amount in Ohmic heating after stored for four weeks, which might generate creamy, fruity intermediate aroma. Other compounds showed no significant difference among three heating processes. Aroma recombination test revealed that the overall aroma of the ultra pasteurized (UP) milk could be mimicked by recombining 15 important reference odorants in the same concentrations as they occurred in the UHT milk using commercial pasteurized milk as the matrix. / Graduation date: 2012

Ohmic heating

direct steam injection

indirect plate heating

flavor

UHT milk

Milk -- Heat treatment

Milk -- Flavor and odor