Distribution of Acetic Acid Carbon in High Fatty Acids Synthesized from Acetic Acid by the Intact Mouse

Nutritional strategies can be employed to mitigate greenhouse emissions from ruminants. This article investigates the effects of polyphenols extracted from the involucres of Castanea mollissima Blume (PICB) on in vitro rumen fermentation. Three healthy Angus bulls (350 ± 50 kg), with permanent rumen fistula, were used as the donors of rumen fluids. A basic diet was supplemented with five doses of PICB (0%–0.5% dry matter (DM)), replicated thrice for each dose. Volatile fatty acids (VFAs), ammonia nitrogen concentration (NH3-N), and methane (CH4) yield were measured after 24 h of in vitro fermentation, and gas production was monitored for 96 h. The trial was carried out over three runs. The results showed that the addition of PICB significantly reduced NH3-N (p < 0.05) compared to control. The 0.1%–0.4% PICB significantly decreased acetic acid content (p < 0.05). Addition of 0.2% and 0.3% PICB significantly increased the propionic acid content (p < 0.05) and reduced the acetic acid/propionic acid ratio, CH4 content, and yield (p < 0.05). A highly significant quadratic response was shown, with increasing PICB levels for all the parameters abovementioned (p < 0.01). The increases in PICB concentration resulted in a highly significant linear and quadratic response by 96-h dynamic fermentation parameters (p < 0.01). Our results indicate that 0.2% PICB had the best effect on in-vitro rumen fermentation efficiency and reduced greenhouse gas production.

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Computer modeling of vapor-liquid equilibrium of high fatty acids

Proceedings of the International Conference on Computer Systems and Technologies and Workshop for PhD Students in Computing - CompSysTech '09 ◽

10.1145/1731740.1731815 ◽

2009 ◽

Author(s):

Dragomir Dobrudzhaliev ◽

Miluvka Stancheva

Keyword(s):

Fatty Acids ◽

Computer Modeling ◽

Liquid Equilibrium ◽

Vapor Liquid Equilibrium ◽

High Fatty Acids ◽

Vapor Liquid

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The Combined Effects of Magnesium Oxide and Inulin on Intestinal Microbiota and Cecal Short-Chain Fatty Acids

Nutrients ◽

10.3390/nu13010152 ◽

2021 ◽

Vol 13 (1) ◽

pp. 152

Author(s):

Kanako Omori ◽

Hiroki Miyakawa ◽

Aya Watanabe ◽

Yuki Nakayama ◽

Yijin Lyu ◽

...

Keyword(s):

Fatty Acids ◽

Acetic Acid ◽

Dietary Fiber ◽

Magnesium Oxide ◽

Acid Concentration ◽

Short Chain Fatty Acids ◽

Water Soluble ◽

Short Chain ◽

Acetic Acid Concentration ◽

Chain Fatty Acids

Constipation is a common condition that occurs in many people worldwide. While magnesium oxide (MgO) is often used as the first-line drug for chronic constipation in Japan, dietary fiber intake is also recommended. Dietary fiber is fermented by microbiota to produce short-chain fatty acids (SCFAs). SCFAs are involved in regulating systemic physiological functions and circadian rhythm. We examined the effect of combining MgO and the water-soluble dietary fiber, inulin, on cecal SCFA concentration and microbiota in mice. We also examined the MgO administration timing effect on cecal SCFAs. The cecal SCFA concentrations were measured by gas chromatography, and the microbiota was determined using next-generation sequencing. Inulin intake decreased cecal pH and increased cecal SCFA concentrations while combining MgO increased the cecal pH lowered by inulin and decreased the cecal SCFA concentrations elevated by inulin. When inulin and MgO were combined, significant changes in the microbiota composition were observed compared with inulin alone. The MgO effect on the cecal acetic acid concentration was less when administered at ZT12 than at ZT0. In conclusion, this study suggests that MgO affects cecal SCFA and microbiota during inulin feeding, and the effect on acetic acid concentration is time-dependent.

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The voluntary intake of acetate by dairy cows given ammonium salts of short-chain fatty acids in their drinking water

Animal Science ◽

10.1017/s0003356100026490 ◽

1968 ◽

Vol 10 (4) ◽

pp. 473-481 ◽

Cited By ~ 6

Author(s):

P. Jackson ◽

J. Hodgson ◽

J. A. F. Rook

Keyword(s):

Fatty Acids ◽

Drinking Water ◽

Acetic Acid ◽

Water Intake ◽

Daily Intake ◽

Short Chain Fatty Acids ◽

Sole Source ◽

Ammonium Salts ◽

Short Chain ◽

Chain Fatty Acids

A solution of ammonium salts of a mixture of short-chain fatty acids (mainly acetic acid) was added to the sole source of drinking water of 10 lactating Jersey cows. There was considerable variation in the concentration of salts tolerated without depression in water intake. Some animals refused solution offered at a concentration of 0·5% (w/w) whereas one animal accepted solution at a concentration of 8% (w/w) and had a mean daily intake of salts equivalent to 836 g acetic acid.2. Adjustment of the pH of the drinking solution to 6·5–7·5 increased the tolerance to the salts solution of animals which showed a low tolerance to the unadjusted solution. A mean daily intake equivalent to 480 g acetic acid was achieved without a significant depression of water intake. Replacement of 50 % of the ammonium ions by calcium increased the intake of salts by some cows but two out of eight refused the solution at a concentration of 0·5% (w/w).3. The addition of saccharine, vanilla or aniseed to a solution of the ammonium salts gave little or no improvement in acetate intake but sodium cyclamate, ethyl acetate or molasses reduced the variability between animals in their tolerance to the solution and increased the mean intake of salts. With an addition of molasses, which gave the most marked response, there was a mean daily intake of salts equivalent to 495±26 g acetic acid.

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The effect of the microbial flora on the flavour and free fatty acid composition of cheddar cheese

Journal of Dairy Research ◽

10.1017/s0022029900012437 ◽

1967 ◽

Vol 34 (3) ◽

pp. 257-272 ◽

Cited By ~ 89

Author(s):

B. Reiter ◽

T. F. Fryer ◽

A. Pickering ◽

Helen R. Chapman ◽

R. C. Lawrence ◽

...

Keyword(s):

Fatty Acids ◽

Acetic Acid ◽

Fatty Acid Composition ◽

Milk Fat ◽

Gluconic Acid ◽

Bacterial Flora ◽

Single Strain ◽

Acid Lactone ◽

Aseptic Conditions ◽

Higher Fatty Acids

SummaryComparisons were made of the flavour, free fatty acids and bacterial flora of commercial cheese made at different factories and experimental cheese made under aseptic conditions: (i) with δ-gluconic acid lactone instead of starter, (ii) with starter only, (iii) with starter and added floras derived from the curd of the commercial cheeses (reference flora cheeses).Comparison of the bacterial flora of commercial and reference flora cheeses showed that replication of organisms was better with some reference floras than with others. In all the cheeses the lactobacilli increased in numbers during maturation, whilst other groups of organisms died out.The amount of acetic acid present was influenced by the starter and by the lactobacilli. Single-strain starters produced some acetic acid, most of which was lost in the whey; commercial starters produced considerably more, due to the presence in them of Streptococcus diacetilactis. Later in maturation lactobacilli increased the acetic acid content, a greater increase being observed with homo-than with heterofermentative strains.The initial levels of butyric and higher fatty acids in the milk varied with source of the milk and with the season, summer milk having higher levels than winter milk. During cheese-making a slight increase of these acids occurred in every cheese made with starter and a further small increase occurred during ripening. However, there was no increase in the content of these acids in the cheese made with δ-gluconic acid lactone, indicating that lactic acid bacteria were weakly hydrolysing the milk fat.Flavour trials showed that Cheddar flavour was present not only in the reference flora and commercial cheese, but also in the cheese made with starter only. Different starters produced different intensities of flavour; one strain produced an intense fruity off-flavour. Cheeses made with δ-gluconic acid lactone were devoid of cheese flavour.

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DUST-BORNE TRACE GASES AND ODORANTS The analysis of dust-borne trace gases requires their i-solation from the dust particles. Procedures for the isolation and characterization of trace gases and odorants in the dust from pig houses are given by SCHAEFER et al. (29), HAMMOND et al.(30) and TRAVIS and ELLIOTT (31). Alcoholic solvents were found to be effective for the extraction of volatile fatty ac ids and phenols from the dust of hen (32) and pig houses (33), (34). Today, gas chromatography is usually used for the sepa ration and identification of the trace gases. Table IV gives a literature review of compounds identified in the dust of pig houses. There are only very few reports on investigations on the dust from hen houses (32). Most of the odours coming from livestock production units are associated with the biological degradation of the animal wastes (35), the feed and the body odour of the animals (1). Volatile fatty acids and phenolic compounds were found to con tribute mostly to the strong, typical odour of animal houses by the help of sensory evaluations parallel to the chemical analysis (29),(30). Table V gives quantitative values of volatile fatty acids and phenolic/indolic compounds found in the aerosol phase and in settled dust of piggeries, respectively. The results from the aerosol phase coincide, particularly as far as acetic acid is concerned. For the investigations of the settled dust the coefficients of variation (CV) and the relative values (%) characterizing the percentage of the single compounds as part of the total amount are quoted. The values are corrected with the dry matter content of the dust. Main components are acetic acid and p-cresol, respectively. Table VI compares results from air, dust and slurry in vestigations on VFA and phenolic/indolic compounds in piggeries. Relative values are used. When comparing the results derived from investigations on dust, air or slurry it is necessary to use relative values because of the different dimensions, for experience shows that in spite of large quantitative differ ences between two samples within the group of carboxylic acids and within the group of phenolic/indolic compounds the propor tions of the components remain rather stable (36). In the group of VFA acetic acid is the main component in air, dust, and slurry followed by propionic and butyric acid. The other three acids amount to less than 25%. In the group of phenols/ indoles p-cresol is the main component in the four cited in vestigations. However, it seems that straw bedding can reduce the p-cresol content; in this case phenol is the main compo nent , i nstead (37 ). 4. EMISSION OF DUST-BORNE VFA AND PHENOLS/INDOLES FROM PIGGERIES The investigations of dust from piggeries show that both VFA and phenols/indoles are present in a considerable amount. However, compared to the air-borne emissions calculated on the base of the results of LOGTENBERG and STORK (38) less than the tenth part (1/10) of phenols/indoles and about the hundredth part (1/100) of VFA are emitted by the dust, only. Table VII compares the dust-borne and air-borne emissions of VFA and

Odour Prevention and Control of Organic Sludge and Livestock Farming ◽

10.1201/9781482286311-131 ◽

1986 ◽

pp. 337-337

Keyword(s):

Fatty Acids ◽

Acetic Acid ◽

Volatile Fatty Acids ◽

Trace Gases ◽

Matter Content ◽

Biological Degradation ◽

Indolic Compounds ◽

Settled Dust ◽

Main Components ◽

Main Component

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DISTRIBUTION OF ENERGY SOURCE EXPENDITURE IN WARM- AND COLD-EXPOSED SHEEP

Canadian Journal of Animal Science ◽

10.4141/cjas84-254 ◽

1984 ◽

Vol 64 (5) ◽

pp. 265-266 ◽

Cited By ~ 10

Author(s):

TSUNEYUKI TSUDA ◽

YOSHIO SHOJI ◽

KAICHI AMBO ◽

MASANORI FUJITA ◽

KATSUNORI SUNAGAWA

Keyword(s):

Energy Source ◽

Fatty Acids ◽

Acetic Acid ◽

Free Fatty Acids ◽

Key Words ◽

Heat Production ◽

Total Heat

The heat production of sheep exposed to 0 °C increased 2.14 times compared with that at 20 °C. At 0 °C, the percentage of heat derived from oxidation of acetic acid decreased but that of free fatty acids increased remarkably. The substances which comprise 50% of total heat production remained unknown. Key words: Sheep, cold, heat production, energy source

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POTENTIAL OF LIVESTOCK MANURE FOR COAL ACTIVATION

Jurnal Biologi Udayana ◽

10.24843/jbiounud.2017.vol21.i01.p06 ◽

2017 ◽

Vol 21 (1) ◽

pp. 26 ◽

Cited By ~ 1

Author(s):

EllIN HARlIA HARlIA ◽

MARlINA ET ◽

MASITA R ◽

RAHMAH KN

Keyword(s):

Carbon Dioxide ◽

Fatty Acids ◽

Acetic Acid ◽

Volatile Fatty Acids ◽

Coal Bed ◽

Coal Bed Methane ◽

Anaerobic Conditions ◽

Descriptive Approach ◽

Carbon Dioxide Co2 ◽

Reduction Of Co2

The natural methane formed by bacteria in anaerobic conditions is known as biogenic gas. Gas trapped in coal, formed through thermogenesis as well as biogenesisis known as coal-bed methane (CBM). The availability of organic material as decomposition of this material into methane is continuously required for the production of methane in the coal aquifer. The aim of this research was to investigate whether or not cattle feces bacteria were able to grow and produce methane in coal. Parameters measured were Volatile Fatty Acids (VFA) and the production of biogas, such as nitrogen, hydrogen, carbon dioxide, and methane. Explorative method was used and data obtained was analyzed by descriptive approach. The results showed that the bacteria found in the feces survived in the coal and produce biogas. On day 2 when the process was at the acidogenesis phase, it produced VFA with the largest component of acetic acid. Acetic acid would undergo decarboxylation and reduction of CO2 followed by reactions of H2and CO2 to produce methane (CH4) and carbon dioxide (CO2) as the final products. ,

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Enhanced lipid production by Yarrowia lipolytica cultured with synthetic and waste-derived high-content volatile fatty acids under alkaline conditions

Biotechnology for Biofuels ◽

10.1186/s13068-019-1645-y ◽

2020 ◽

Vol 13 (1) ◽

Cited By ~ 7

Author(s):

Ruiling Gao ◽

Zifu Li ◽

Xiaoqin Zhou ◽

Wenjun Bao ◽

Shikun Cheng ◽

...

Keyword(s):

Fatty Acids ◽

Acetic Acid ◽

Propionic Acid ◽

Yarrowia Lipolytica ◽

Butyric Acid ◽

Lipid Content ◽

Volatile Fatty Acids ◽

Lipid Production ◽

Initial Ph ◽

Alkaline Conditions

Abstract Background Volatile fatty acids (VFAs) can be effective and promising alternate carbon sources for microbial lipid production by a few oleaginous yeasts. However, the severe inhibitory effect of high-content (> 10 g/L) VFAs on these yeasts has impeded the production of high lipid yields and their large-scale application. Slightly acidic conditions have been commonly adopted because they have been considered favorable to oleaginous yeast cultivation. However, the acidic pH environment further aggravates this inhibition because VFAs appear largely in an undissociated form under this condition. Alkaline conditions likely alleviate the severe inhibition of high-content VFAs by significantly increasing the dissociation degree of VFAs. This hypothesis should be verified through a systematic research. Results The combined effects of high acetic acid concentrations and alkaline conditions on VFA utilization, cell growth, and lipid accumulation of Yarrowia lipolytica were systematically investigated through batch cultures of Y. lipolytica by using high concentrations (30–110 g/L) of acetic acid as a carbon source at an initial pH ranging from 6 to 10. An initial pH of 8 was determined as optimal. The highest biomass and lipid production (37.14 and 10.11 g/L) were obtained with 70 g/L acetic acid, whereas cultures with > 70 g/L acetic acid had decreased biomass and lipid yield due to excessive anion accumulation. Feasibilities on high-content propionic acid, butyric acid, and mixed VFAs were compared and evaluated. Results indicated that YX/S and YL/S of cultures on butyric acid (0.570, 0.144) were comparable with those on acetic acid (0.578, 0.160) under alkaline conditions. The performance on propionic acid was much inferior to that on other acids. Mixed VFAs were more beneficial to fast adaptation and lipid production than single types of VFA. Furthermore, cultures on food waste (FW) and fruit and vegetable waste (FVW) fermentate were carried out and lipid production was effectively improved under this alkaline condition. The highest biomass and lipid production on FW fermentate reached 14.65 g/L (YX/S: 0.414) and 3.20 g/L (YL/S: 0.091) with a lipid content of 21.86%, respectively. By comparison, the highest biomass and lipid production on FVW fermentate were 11.84 g/L (YX/S: 0.534) and 3.08 g/L (YL/S: 0.139), respectively, with a lipid content of 26.02%. Conclusions This study assumed and verified that alkaline conditions (optimal pH 8) could effectively alleviate the lethal effect of high-content VFA on Y. lipolytica and significantly improve biomass and lipid production. These results could provide a new cultivation strategy to achieve simple utilizations of high-content VFAs and increase lipid production. Feasibilities on FW and FVW-derived VFAs were evaluated, and meaningful information was provided for practical applications.

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Studies on the production of volatile fatty acids from grass by rumen liquor in an artificial rumen: II. The volatile fatty acid production from dried grass

The Journal of Agricultural Science ◽

10.1017/s0021859600036157 ◽

1957 ◽

Vol 49 (2) ◽

pp. 171-179 ◽

Cited By ~ 4

Author(s):

A. John ◽

G. Barnett ◽

R. L. Reid

Keyword(s):

Fatty Acids ◽

Acetic Acid ◽

Propionic Acid ◽

Metabolic Pathways ◽

Volatile Fatty Acid ◽

Volatile Fatty Acids ◽

Water Soluble ◽

Fatty Acid Production ◽

Growing Seasons ◽

Titration Curves

1. A study has been made of the production of volatile fatty acids obtainable from dried grass and its gross water-soluble and water-insoluble separates, in the artificial rumen, over two growing seasons.2. In contradistinction to fresh grass, the dried grass gives a consistent production of acetic acid proportionately greater than propionic acid, at all stages of maturity, but when aqueous extracts of the dried grass, and the resultant extracted grass, respectively, are examined separately in the artificial rumen, it is found that the former yield preponderating amounts of acetic acid while the latter give amounts of propionic acid equal to, or exceeding, the corresponding productions of acetic acid.3. An examination of the titration curves for the total acids obtained from the dried grass, extracted grass and grass extract runs, indicates an approach to an incomplete relationship between the residual carbohydrate in the extracted grass and cellulose, while the grass extract reveals itself as the chief source of acetic acid in the whole dried grass, the acid being formed very speedily at the start of the run.4. The suggested sources and some of the possible metabolic pathways involved in the formation of v.f.a. from grass are discussed in the text.

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