Publications

Dr. Pryor and colleagues at Louisiana State University developed methods for measuring ozone reaction products in in vitro models of lung lining fluids exposed to ozone and in lung fluids from rats exposed to ozone. During the study, Dr. Mark Frampton of the University of Rochester provided Pryor with lung fluids from humans exposed to air or ozone under controlled conditions. Frampton and colleagues exposed exercising smokers and nonsmokers to filtered air or to 0.22 parts per million (ppm) ozone for four hours.

In a follow-up study to previous research, Dr. Mercer and colleagues at Duke University exposed three groups of rats continuously for six weeks to 2 or 6 ppm nitric oxide (NO) or to filtered air to learn more about the toxicity of NO so as to compare it with two other important oxidants, ozone and nitrogen dioxide (NO₂). At the end of the exposure period he used an electron microscope to measure the number of holes in the alveolar septa and to observe other structural changes, such as in the surface area and the number and type of other abnormalities in the alveolar septa.

A Special Report of the Institute's Diesel Epidemiology Expert Panel. Although epidemiologic data have been used generally to identify the hazards associated with exposure to diesel exhaust, questions remain as to whether the human data can be used to develop reliable estimates of the magnitude of any risk for lung cancer (that is, through quantitative risk assessment [QRA]), and whether new research efforts could provide any additional data needed. In response to such issues, the Health Effects Institute initiated the Diesel Epidemiology Project in 1998.

Dr. Kleeberger and colleagues at Johns Hopkins University compared ozone-induced inflammation, epithelial cell injury, and epithelial cell proliferation (a marker of cell injury) in three types of mice: mice with a normal content of mast cells, mutant mice without mast cells, and mutant mice whose mast cells were repleted by a bone marrow transplant from normal mice. Each group of mice was exposed to clean air or to ozone for varying lengths of time.

Drs. Douglas Dockery at the Harvard School of Public Health and C. Arden Pope III at Brigham Young University speculated that exposure to PM might lead to a transient drop in blood oxygenation, which might have serious consequences in humans with heart or lung problems. The investigators designed a study to increase the possibility of observing PM effects by testing a potentially at-risk group (the elderly) at a time of year that historically had experienced relatively high levels of PM (the winter).

Daniel L. Albritton and Daniel S. Greenbaum, cochairs. Report of the PM Measurements Research Workshop, Chapel Hill NC, July 22 and 23, 1998. Aeronomy Laboratory of the National Oceanic and Atmospheric Administration, Boulder, CO, and Health Effects Institute, Cambridge, MA.

Dr. John Peters and colleagues of the University of Southern California School of Medicine compared the lung function, respiratory symptoms, activity levels, and bronchodilator use of 10- to 12-year-old healthy, asthmatic, and wheezy children. They conducted the study in Southern California during mid-spring (when ozone levels were expected to be low) and late summer (when ozone levels were expected to be high).

Dr. Thom and Dr. Ischiropoulos at the University of Pennsylvania Medical Center examined the effects of low concentrations of carbon monoxide on platelets and cells isolated from blood vessels. The investigators exposed blood platelets (taken from rats) and endothelial cells (isolated from bovine blood vessels) to varying concentrations of carbon monoxide and measured how much nitric oxide was released. To determine if exposure to carbon monoxide causes endothelial cells to produce peroxynitrite, the investigators looked for markers of its presence in the culture medium and in the cells.

Communication 5 contains proceedings of a workshop held in Cambridge, MA, December 3–4 1996. Presentations included: Current Understanding of the Health Effects of Particles and the Characteristics That Determine Dose or Effect; Particle Formation in Combustion; The EPA Particle Emissions Testing Procedure; Characterizing Particulate Matter in Motor Vehicle Exhaust; Atmospheric Aerosol Transformation; Generating Particles for Laboratory Studies; and Issues and Research Needs for Particle Characterization.

Dr. John Balmes and colleagues of the University of California, San Francisco, and Dr. Mark Frampton and associates of the University of Rochester characterized ozone-induced responses in two different study populations: normal and asthmatic men and women in the Balmes study (Part I), and male and female nonsmokers and smokers in the Frampton study (Part II). The investigators addressed three issues: (1) Is an individual's reactivity to inhaled methacholine related to changes in lung function after exposure to ozone? (2) What is the relation between ozone-induced airway inflammation and changes in lung function? and (3) Do the changes in lung function and markers of inflammation in response to ozone exposure differ between normal people and people with asthma?