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1.
J Agric Food Chem ; 66(39): 10242-10251, 2018 Oct 03.
Article in English | MEDLINE | ID: mdl-30196698

ABSTRACT

The unique flavor of Beijing Youji (BJY) chicken broth compared with that of commercial broilers (CB) was investigated by solvent-assisted flavor evaporation combined with AEDA/GC-O (aroma extract dilution analysis of gas chromatography-olfactometry), quantitation, and aroma recombination. A total of 71 odorants with almost the same major odorants (≥10 ng/g broth) were found by GC-O in both BJY and CB broths. However, BJY broth had thirty-two more extra odorants than CB broth, indicating the rich fragrance of the former. Aroma recombination and omission experiments demonstrated that 21 versus 17 odorants (with OAV ≥ 1) contributed significantly to BJY and CB broth aromas, respectively. Those key odorants mainly included sulfur-containing compounds and aliphatic aldehydes, such as 2-methyl-3-furanthiol, 3-(methylthio)propanal, ( E, E)-2,4-decadienal, etc. Furthermore, composition analysis of the meat suggested that the better flavor, with rather more odorants, of BJY broth is probably due to higher contents of polyunsaturated fatty acids and water-soluble flavor precursor, including ribose, cysteine, thiamine, etc., present in the BJY meat.


Subject(s)
Flavoring Agents/chemistry , Meat/analysis , Volatile Organic Compounds/chemistry , Animals , Beijing , Chickens , Cooking , Female , Flavoring Agents/economics , Gas Chromatography-Mass Spectrometry , Humans , Male , Meat/economics , Odorants/analysis , Olfactometry , Taste , Volatile Organic Compounds/economics , Young Adult
2.
J Clin Anesth ; 35: 253-258, 2016 Dec.
Article in English | MEDLINE | ID: mdl-27871537

ABSTRACT

STUDY OBJECTIVE: Volatile anesthetic agents comprise a substantial portion of every hospital's pharmacy budget. Challenged with an initiative to lower anesthetic drug expenditures, we developed an education-based intervention focused on reducing volatile anesthetic costs while preserving access to all available volatile anesthetics. When postintervention evaluation demonstrated a dramatic year-over-year reduction in volatile agent acquisition costs, we undertook a retrospective analysis of volatile anesthetic purchasing data using time series analysis to determine the impact of our educational initiative. DESIGN/SETTING: We obtained detailed volatile anesthetic purchasing data from the Central Supply of Wake Forest Baptist Health from 2007 to 2014 and integrated these data with the time course of our educational intervention. PATIENTS: Aggregate volatile anesthetic purchasing data were analyzed for 7 consecutive fiscal years. INTERVENTION: The educational initiative emphasized tissue partition coefficients of volatile anesthetics in adipose tissue and muscle and their impact on case management. MEASUREMENTS: We used an interrupted time series analysis of monthly cost per unit data using autoregressive integrated moving average modeling, with the monthly cost per unit being the amount spent per bottle of anesthetic agent per month. MAIN RESULTS: The cost per unit decreased significantly after the intervention (t=-6.73, P<.001). The autoregressive integrated moving average model predicted that the average cost per unit decreased $48 after the intervention, with 95% confidence interval of $34 to $62. As evident from the data, the purchasing of desflurane and sevoflurane decreased, whereas that of isoflurane increased. CONCLUSIONS: An educational initiative focused solely on the selection of volatile anesthetic agent per case significantly reduced volatile anesthetic expense at a tertiary medical center. This approach appears promising for application in other hospitals in the rapidly evolving, value-added health care environment. We were able to accomplish this with instruction on tissue partition coefficients and each agent's individual cost per MAC-hour delivered.


Subject(s)
Anesthesia, Inhalation/methods , Anesthesiology/education , Anesthetics, Inhalation/economics , Cost Savings/economics , Hospital Costs/statistics & numerical data , Pharmacy Service, Hospital/economics , Volatile Organic Compounds/economics , Anesthesia, Inhalation/instrumentation , Anesthesiologists/education , Anesthetics, Inhalation/administration & dosage , Anesthetists/education , Humans , Internship and Residency , Retrospective Studies , Volatile Organic Compounds/administration & dosage
3.
Environ Sci Technol ; 50(8): 4149-58, 2016 Apr 19.
Article in English | MEDLINE | ID: mdl-27007187

ABSTRACT

As local governments plan to expand airport infrastructure and build air service, monetized estimates of damages from air pollution are important for balancing environmental impacts. While it is well-known that aircraft emissions near airports directly affect nearby populations, it is less clear how the airport-specific aircraft operations and impacts result in monetized damages to human health and the environment. We model aircraft and ground support equipment emissions at major U.S. airports and estimate the monetized human health and environmental damages of near airport (within 60 miles) emissions. County-specific unit damage costs for PM, SOx, NOx, and VOCs and damage valuations for CO and CO2 are used along with aircraft emissions estimations at airports to determine impacts. We find that near-airport emissions at major U.S. airports caused a total of $1.9 billion in damages in 2013, with airports contributing between $720 thousand and $190 million each. These damages vary by airport from $1 to $9 per seat per one-way flight and costs per passenger are often greater than airport charges levied on airlines for infrastructure use. As the U.S. aviation system grows, it is possible to minimize human and environmental costs by shifting aircraft technologies and expanding service into airports where fewer impacts are likely to occur.


Subject(s)
Air Pollution/analysis , Air Pollution/economics , Airports , Air Pollutants/analysis , Air Pollutants/economics , Aircraft , Airports/economics , Aviation/economics , Carbon Dioxide/analysis , Carbon Dioxide/economics , Carbon Monoxide/analysis , Carbon Monoxide/economics , Humans , Models, Theoretical , Nitrogen Oxides/analysis , Nitrogen Oxides/economics , Public Health , United States , Vehicle Emissions/analysis , Volatile Organic Compounds/analysis , Volatile Organic Compounds/economics
4.
J Agric Food Chem ; 64(3): 627-36, 2016 Jan 27.
Article in English | MEDLINE | ID: mdl-26690018

ABSTRACT

By application of aroma extract dilution analysis (AEDA) on the volatile fraction isolated from commercial cold-pressed rapeseed oil prepared from unpeeled seeds, 35 odor-active constituents in the flavor dilution (FD) factor range of 8-8192 were detected. The identification experiments showed that the earthy, pea-like-smelling 2-isopropyl-3-methoxypyrazine showed the highest FD factor of 8192, followed by 1-octene-3-one (FD 4096) and (E,Z)-2,6-nonadienal with an FD of 2048. After quantitation of the 16 key odorants showing FD factors ≥32 by stable isotope dilution assays and a determination of their odor thresholds in deodorized sunflower oil, odor activity values (OAV; ratio of concentration to odor threshold) could be calculated. The results indicated 2-isopropyl-3-methoxypyrazine, (E,E)-2,4-nonadienal (deep-fried, fatty), and (E,Z)-2,6-nonadienal (cucumber-like) with the highest OAVs. To confirm that the key aroma compounds were correctly identified and quantitated, a recombination experiment was performed by mixing the reference odorants in the same concentrations as they occurred in the rapeseed oil using odorless sunflower oil as the matrix. The recombinate showed a very good agreement with the overall aroma of the oil. In a commercial rapeseed oil prepared from peeled seeds, the same odorants were identified; however, in particular, the FD factor of dimethyl sulfide (DMS) was clearly higher. Quantitation of DMS in 10 commercial rapeseed oils from either peeled and unpeeled seeds revealed significant differences in DMS, but no influence of the peeling process on the amounts of DMS was found. The data can serve as a basis for the quality assessment of cold-pressed rapeseed oil.


Subject(s)
Brassica rapa/chemistry , Flavoring Agents/chemistry , Food Handling/methods , Plant Oils/chemistry , Volatile Organic Compounds/chemistry , Fatty Acids, Monounsaturated , Flavoring Agents/economics , Odorants/analysis , Plant Oils/economics , Rapeseed Oil , Seeds/chemistry , Smell , Volatile Organic Compounds/economics
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