Exposure to Cooking Fumes in Restaurant Kitchens in Norway

Overview

Journal Ann Occup Hyg

Publisher Oxford University Press

Specialty Occupational Medicine

Date 2002 Aug 15

PMID 12176708

Citations 18

Authors

Kristin Svendsen

Hanne Naper Jensen

Ingvill Sivertsen

Ann Kristin Sjaastad

Affiliations

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Abstract

Objectives: The purpose of this study was to assess exposure to fat aerosols and aldehydes in kitchens and to study the variations in exposure between different types of kitchen.

Methods: Measurements were made in four hotel kitchens, two hamburger chain restaurants, 10 à la carte restaurants and three small local restaurants serving mostly fried food. The measurements were performed as personal measurements and each person carried two sampling devices connected to pumps. One pump was connected to a filter cassette with a 37 mm glassfibre filter and the other to a sampling device for aldehydes. The measurements were repeated on 3 days in each kitchen. Variables which could influence the level of exposure were recorded by the occupational hygienist.

Results: The level of fat aerosols varied between the different types of kitchen. The highest measured level of fat aerosol was 6.6 mg/m(3), in a small local restaurant. The arithmetic mean for all the kitchens was 0.62 mg/m(3). The highest level of the sum of the aldehydes was 186 micro g/m(3) (0.186 mg/m(3)), while the arithmetic mean was 69 micro g/m(3).

Conclusions: The exposure to fat aerosols was modest, but could be up to 50% of the Norwegian threshold limit value (TLV) for nuisance dust (10 mg/m(3)). Fat aerosols from frying will, however, contain a mixture of heat- and water-treated fat from the meat which is being fried, hydrolysed vegetable fat and other degradation products, such as fatty acids, other organic acids and aldehydes. As a consequence of this, cooking fumes should be regarded as harmful to the lungs. The levels of formaldehyde, acetaldehyde and acrolein were well below the TLVs.

Citing Articles

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Cooking methods and kitchen ventilation availability, usage, perceived performance and potential in Canadian homes.

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The Chemical Composition Characteristics and Health Risk Assessment of Cooking Fume Condensates from Residential Kitchens in Different Regions of China.

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Gunes G, Yalcin N, Colaklar H Environ Monit Assess. 2022; 194(3):200.

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Gao X, Zhang M, Zou H, Zhou Z, Yuan W, Quan C Sci Rep. 2021; 11(1):15586.

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