Ultrafine particle deposition in subjects with asthma.Ambient air particles in the ultrafine size range (diameter < 100 nm) may contribute to the health effects of particulate matter. However, there are few data on ultrafine particle deposition during spontaneous breathing, and none in people with asthma. Sixteen subjects with mild to moderate asthma were exposed for 2 hr, by mouthpiece, to ultrafine carbon particles with a count median diameter (CMD CMD cerebromacular degeneration. ) of 23 nm and a geometric standard deviation In probability theory and statistics, the geometric standard deviation describes how spread out are a set of numbers whose preferred average is the geometric mean. If the geometric mean of a set of numbers is denoted as μg of 1.6. Deposition was measured during spontaneous breathing at rest (minute ventilation, 13.3 [+ or -] 2.0 L/min) and exercise (minute ventilation, 41.9 [+ or -] 9.0 L/min). The mean [+ or -] SD fractional deposition was 0.76 [+ or -] 0.05 by particle number and 0.69 [+ or -] 0.07 by particle mass concentration. The number deposition fraction increased as particle size decreased, reaching 0.84 [+ or -] 0.03 for the smallest particles (midpoint mid·point n. 1. Mathematics The point of a line segment or curvilinear arc that divides it into two parts of the same length. 2. A position midway between two extremes. CMD = 8.7 nm). No differences between sexes were observed. The deposition fraction increased during exercise to 0.86 [+ or -] 0.04 and 0.79 [+ or -] 0.05 by particle number and mass concentration, respectively, and reached 0.93 [+ or -] 0.02 for the smallest particles. Experimental deposition data exceeded model predictions during exercise. The deposition at rest was greater in these subjects with asthma than in previously studied healthy subjects (0.76 [+ or -] 0.05 vs. 0.65 [+ or -] 0.10, p < 0.001). The efficient respiratory deposition of ultrafine particles increases further in subjects with asthma. Key words: air pollution, asthma, deposition, dosimetry dosimetry /do·sim·e·try/ (do-sim´e-tre) scientific determination of amount, rate, and distribution of radiation emitted from a source of ionizing radiation, in biological d. , inhalation, ultrafine particles. Environ Health Perspect 112:879-882 (2004). doi:10.1289/ehp.6851 available via http://dx.doi.org/[Online 2 March 2004] ********** Epidemiologic studies have shown links between mass concentrations of ambient particulate matter and increased morbidity and mortality Morbidity and Mortality can refer to:
Particles < 100 nm (0.1 [micro]m) in diameter [ultrafine particles (UFPs)] are ubiquitous in ambient particulate pollution and dominate ambient particle number and surface area concentrations, both indoors and outdoors, because of their small size (Oberdorster et al. 1995; Frampton 2001). UFPs may contribute to the health effects of particulate matter because of their high surface area, oxidant oxidant /ox·i·dant/ (ok´si-dant) the electron acceptor in an oxidation-reduction (redox) reaction. ox·i·dant n. See oxidizer. capacity, ability to evade macrophage macrophage /mac·ro·phage/ (mak´ro-faj) any of the large, mononuclear, highly phagocytic cells derived from monocytes that occur in the walls of blood vessels (adventitial cells) and in loose connective tissue (histiocytes, phagocytic phagocytosis phagocytosis: see endocytosis. Phagocytosis A mechanism by which single cells of the animal kingdom, such as smaller protozoa, engulf and carry particles into the cytoplasm. , and propensity for inducing pulmonary inflammation. Although few studies have assessed the health effects of exposure to UFPs, ambient UFP UFP United Federation of Planets (Star Trek) UFP Union des Forces Progressistes (French: Union of the Forces Progressists, Quebec provincial party) UFP URL Filtering Protocol concentrations have been associated with mortality (Wichmann et al. 2000). A panel study of subjects with asthma (Peters et al. 1997) found that peak flow varied more closely with the 5-day mean of UFP number than with fine particle mass concentration, suggesting that the UFP component of fine particle pollution contributes to airway effects in asthmatics. Penttinen et al. (2001) noted that UFP number concentrations tended to be inversely but nonsignificantly associated with measures of lung function. However, some epidemiologic studies have not found associations between UFP exposure and health effects (de Hartog et J. 2003). Inhaled UFPs have a high predicted deposition efficiency in the pulmonary region [International Commission on Radiological Protection The International Commission on Radiological Protection (ICRP) is an advisory body providing recommendations and guidance on radiation protection; It was founded in 1928 by the International Society of Radiology (ISR) and was then called the ‘International X-ray and Radium (ICRP ICRP International Commission on Radiological Protection ICRP International Commission on Radiation Protection (Stockholm, Sweden) ICRP Indonesian Committee on Religion and Peace ICRP Intensive Cognitive Rehabilitation Program ) 1994]. Thus, the expected number of particles retained in the lung with each breath is greater for UFPs than for larger particles. We and others have confirmed the relatively high predicted deposition of UFPs in healthy people breathing at rest (Anderson et al. 1990; Brown et al. 2002; Daigle et al. 2003; Jaques and Kim 2000; Roth et al. 1994; Schiller et al. 1988; Wilson et al. 1985). We recently demonstrated that UFP fractional deposition increases significantly with breathing during exercise in healthy subjects (Daigle et al. 2003). Brown et al. (2002) observed an increased total deposition, expressed as dose rate, for patients with chronic obstructive lung disease Chronic Obstructive Lung Disease Definition Chronic obstructive lung disease, also known as chronic obstructive pulmonary disease (COPD), is a general term for a group of conditions in which there is persistent difficulty in expelling (or exhaling) air , compared with healthy subjects, with exposure to a 33-nm (count median diameter) ultrafine technetium-99m-labeled aerosol. We are unaware of any previous studies measuring UFP deposition in people with asthma. Asthma is characterized by airway obstruction, with air trapping and increases in lung residual volume residual volume n. Abbr. RV The volume of air remaining in the lungs after a maximal expiratory effort. Also called residual air, residual capacity. . Increases in alveolar alveolar /al·ve·o·lar/ (al-ve´o-lar) [L. alveolaris ] pertaining to an alveolus. al·ve·o·lar adj. Relating to an alveolus. volume would be expected to enhance diffusional deposition, the primary mechanism of deposition for UFPs, although impaired alveolar ventilation alveolar ventilation n. The volume of gas expired from alveoli to the outside of the body per minute. would counter this increase. We hypothesized that the fractional deposition of UFPs is greater in subjects with mild asthma than in healthy subjects without asthma, and that UFP deposition increases further with exercise. Materials and Methods Subjects and experimental design. The Research Subjects Review Board of the University of Rochester The University of Rochester (UR) is a private, coeducational and nonsectarian research university located in Rochester, New York. The university is one of 62 elected members of the Association of American Universities. approved the study, and informed written consent was obtained. Subjects were 16 men and women with mild asthma who had never smoked, were 18-55 years of age, and were without a recent respiratory infection. Subjects were considered to have asthma if they had a history of repetitive symptoms characteristic of intermittent bronchoconstriction (wheezing Wheezing Definition Wheezing is a high-pitched whistling sound associated with labored breathing. Description Wheezing occurs when a child or adult tries to breathe deeply through air passages that are narrowed or filled with mucus as a , shortness of breath Shortness of Breath Definition Shortness of breath, or dyspnea, is a feeling of difficult or labored breathing that is out of proportion to the patient's level of physical activity. ) and either a) improvement in forced expiratory volume forced expiratory volume n. Abbr. FEV The maximum volume of air that can be expired from the lungs in a specific time interval when starting from maximum inspiration. in 1 sec ([FEV FEV forced expiratory volume. FEV abbr. forced expiratory volume FEV forced expiratory volume. .sub.1]) [greater than or equal to] 12% with the administration of inhaled albuterol albuterol /al·bu·ter·ol/ (al-bu´ter-ol) a ß agonist used as the base or sulfate salt as a bronchodilator. al·bu·ter·ol n. if abnormally low values were obtained for airway conductance, [FEV.sub.1], or [FEV.sub.1]/forced vital capacity (FVC FVC forced vital capacity. FVC abbr. forced vital capacity FVC, n See forced vital capacity. FVC forced vital capacity. ) (Morris et al. 1971); or b) airway hyperresponsiveness with methacholine challenge. At the time of screening, subjects exercised on a bicycle ergometer ergometer /er·gom·e·ter/ (er-gom´e-ter) a dynamometer. bicycle ergometer an apparatus for measuring the muscular, metabolic, and respiratory effects of exercise. for 15 min to determine the intensity necessary to achieve a target minute ventilation of 20 L/min/[m.sup.2]. Subjects with [FEV.sub.1] < 70% of predicted at baseline screening, or with > 20% reduction in [FEV.sub.1] after the screening exercise, were excluded. For the methacholine challenge, increasing concentrations of methacholine (0.00, 0.08, 0.16, 0.31, 0.63, 1.25, 2.50, 5.00, 10.00 mg/mL) in normal saline normal saline Physiologic saline solution, see there were administered at 4-min intervals using a nebulizer nebulizer /neb·u·liz·er/ (neb´u-li?zer) atomizer; a device for throwing a spray. neb·u·liz·er n. (model 646; Devilbiss Company, Summerset, PA) with a dosimeter do·sim·e·ter n. An instrument that measures the amount of radiation absorbed in a given period. dosimeter an instrument used to detect and measure exposure to radiation. (Rosenthal-French model D-2A; Laboratory for Applied Immunology Inc., Fairfax, VA) calibrated cal·i·brate tr.v. cal·i·brat·ed, cal·i·brat·ing, cal·i·brates 1. To check, adjust, or determine by comparison with a standard (the graduations of a quantitative measuring instrument): to deliver 0.01 mL/breath. Subjects were instructed to take five breaths each lasting 6 sec, and [FEV.sub.1] was measured 30 sec after the last breath. The concentration of methacholine that produced a partial (20%) decrease in [FEV.sub.1] (PD20) was determined by interpolation interpolation In mathematics, estimation of a value between two known data points. A simple example is calculating the mean (see mean, median, and mode) of two population counts made 10 years apart to estimate the population in the fifth year. using the regression line of the methacholine dose response. Subjects with a PD20 > 10 mg/mL were excluded from the study. All exposures were by mouthpiece with a nose clip for 2 hr, with a 10-min break off the mouthpiece after the first hour. In the exposure, subjects (n = 16) were exposed to a target mass concentration of 10 [micro]g/[m.sup.3], which corresponded to an empirically determined number concentration of 2 x [10.sup.6] particles/[cm.sup.3]. Exposures lasted 2 hr and included four alternating 15-min rest and exercise (target minute ventilation, 25 L/min/[m.sup.2] body surface area) periods. Exposure system. The exposures were undertaken within an environmental chamber in the General Clinical Research Center at the University of Rochester Medical Center The University of Rochester Medical Center (URMC), located in Rochester, New York, is one of the main campuses of the University of Rochester and comprises the university's primary medical education, research and patient care facilities. . A mouthpiece exposure system was chosen in order to facilitate accurate and relevant measurements of respiratory deposition. Details of particle generation and the mouthpiece exposure system have been described elsewhere (Chalupa
A chalupa is a kind of tostada platter in Mexican cuisine. et al. 2002; Daigle et al. 2003). Briefly, the design is a one-pass, dynamic-flow exposure system. Particles were generated from pure graphite electrodes by spark discharge in anhydrous an·hy·drous adj. Without water, especially water of crystallization. anhydrous (anhī´drus), adj without water. anhydrous containing no water. argon argon (är`gŏn) [Gr.,=inert], gaseous chemical element; symbol Ar; at. no. 18; at. wt. 39.948; m.p. −189.2°C;; b.p. −185.7°C;; density 1.784 grams per liter at STP; valence 0. , using a commercial generator (Palas Co., Karlsruhe, Germany). The generator settings were adjusted to provide a nominal particle count median diameter (CMD) of 23 nm with a geometric standard deviation of 1.6. Particles were passed through a charge neutralizer after generation, in order to achieve Boltzman's equilibrium, and were delivered continuously into diluting air in a mixing chamber. The dilution air was passed through charcoal and high-efficiency particle filters and supplied into the mixing chamber at 120 L/min. The intake air flow rate was monitored with a Magnahelic pressure gauge (Dwyer Instruments, Inc., Michigan City, IN), which was calibrated using a dry test meter (Singer American Meter Company Division, Wellesley, MA). All tubing was electrically conductive with lengths minimized to avoid particle loss. Subjects wore a nose clip, inhaled through a mouthpiece connected to the exposure system via one-way rebreathing re·breath·ing n. The partial or complete inhalation of previously exhaled gases. rebreathing, n breathing into a closed system. valves (Hans Rudolph Inc., Kansas City, MO), and exhaled into a dedicated exhaust line. Particles in the reservoir entered the circuitry to the mouthpiece according to the demands of the subject. A resilient reservoir was placed on the expiratory ex·pi·ra·to·ry adj. Of, relating to, or involving the expiration of air from the lungs. expiratory relating to or employed in the expiration of air from the lungs. side of the subject, loosely coupled to a dedicated filter and exhaust system. The system was designed to keep both sides of the non-rebreathing valves at atmospheric pressure, unaffected by the subject's respiration. Tubing on the expiratory side was heated to approximately 37[degrees]C to avoid condensation. Measurements of both inhaled and exhaled air included particle number (condensation particle counters, model 3220a; TSI TSI Total Solar Irradiance (sum solar light in energy per unit of time) TSI Trading Standards Institute (UK) TSI Transportation Safety Institute (US DOT) , Inc., St. Paul MN) and particle size distribution The particle size distribution[1] ("PSD") of a powder, or granular material, or particles dispersed in fluid, is a list of values or a mathematical function that defines the relative amounts of particles present, sorted according to size. (Scanning Mobility Particle Sizer, model 3071; TSI, Inc.). Particle mass concentration was continuously measured on the inhaled aerosol [tapered element oscillating os·cil·late intr.v. os·cil·lat·ed, os·cil·lat·ing, os·cil·lates 1. To swing back and forth with a steady, uninterrupted rhythm. 2. microbalance mi·cro·bal·ance n. A balance designed to weigh very small loads, up to 0.1 gram. Noun 1. microbalance - balance for weighing very small objects balance - a scale for weighing; depends on pull of gravity (TEOM TEOM Tapered Element Oscillating Microbalance ); Rupprecht and Patachnick, Albany, NY]. The target exposure mass concentration was 10 [micro]g/[m.sup.3]. Electronic integration (HPChem Integrating Software, Hewlett Packard, Wilmington, DE) of a pneumotachographic airflow transducer (E for M Co., White Plains, NY) on the expiratory limb provided continuous measurements of tidal volume tidal volume n. The volume of air inspired or expired in a single breath during regular breathing. Also called tidal air. tidal volume, n ([V.sub.T]), respiratory rate respiratory rate, n the normal rate of breathing at rest, about 12 to 20 inspirations per minute. systemic inflammatory response syndrome A term that ' , and minute ventilation. To determine particle losses, a reciprocal pump was used to simulate respiration. A resting minute ventilation of 10 L/min was simulated using a volume of 800 mL at 12.5 cycles/min. Mild exercise (22 L/min) was simulated using a volume of 1,200 mL at 18.3 cycles/min. Continuous upstream and downstream measurements of particle number and volume were determined for the whole system and for a respiratory valve alone. Mass losses were calculated using particle volume determined by the electrostatic classifier. During exercise simulation, losses were 0% for particles [greater than or equal to] 23.7 nm midpoint diameter; maximum losses were 3.9% for 7.5 nm particles. At resting conditions, maximum losses were 13.2% for 7.5 nm particles. UFP deposition. The total respiratory deposition fraction (DF) was calculated for both particle number and mass concentrations, with correction for system losses (Chalupa et al. 2002). Inspiratory in·spi·ra·to·ry adj. Of, relating to, or used for the drawing in of air. inspiratory pertaining to or used in the inspiration of air into the lungs. and expiratory UFP number concentrations were measured continuously and recorded every 5 sec during the exposure. Particle number concentration was then averaged for the periods at rest and exercise. Particle size distribution from the inspiratory circuit was determined before each exposure and just after the exposure was completed. Particle size distribution from the expiratory circuit was measured during one rest and one exercise period each hour. For computational simplicity, data on particle size distribution from the scanning mobility particle sizer were grouped into 12 particle size bins. Four size bins each contained less than 1% of the total expired particle number (midpoint diameters < 8.7 and > 64.9 nm), and these were excluded, leaving a total of eight size bins with midpoint CMD from 8.7 to 64.9 nm (particle CMD ranging from 7.5 to 75.0 nm), which included > 98% of the particles. The mean size-specific inspiratory particle concentration was determined by multiplying the average inspiratory number concentration by the percentage of particles in each size bin in the inspiratory circuit. The mean size-specific expiratory particle concentration was determined by multiplying the average expiratory number concentration by the percentage of particles in each size bin in the expiratory circuit. The correction factors for system losses were subtracted from the measured inspired concentrations and added to the measured expired concentrations. The number DF was then calculated by subtracting the corrected expiratory number concentration from the corrected inspiratory number concentration and dividing the difference by the corrected inspiratory number concentration. The particulate mass DF was calculated as follows: Inspired and expired particle volume (mass) concentrations were determined for each size bin from the scanning mobility particle sizer data. The percentages of inspired and expired particles by volume per bin were determined by dividing each bin volume concentration by the total volume concentration (sum of individual bins). The mean expired mass concentration was calculated by multiplying the ratio of the total expired volume concentration to the total inspired volume concentration, times the measured (TEOM) inspired mass concentration. The inspired mass concentration for each bin was calculated as the product of the inspired volume percentage of particles in each bin and the mean inspired mass concentration from the TEOM. The expired mass concentration for each bin was the product of the expired volume percentage for each bin and the calculated overall expired mass concentration. This mass data was corrected for system losses by multiplying each bin by the loss correction factor for that bin and then subtracting that product from the inspired data and adding to the expired data. Finally, a loss-corrected DF was calculated as the loss-corrected inspired mass concentration minus the loss-corrected expired mass concentration, divided by the loss-corrected inspired mass concentration. The data were then compared with theoretical total respiratory DFs calculated using three models: a) ICRP (1994), b) National Council on Radiological Protection and Measurements (NCRP (Network Computer Reference Profile) The specification for network computer compliance established by Oracle and endorsed by Sun, IBM and others. The first version of this specification was known as the NC1 Reference Profile. See network computer. 1997), and c) the Multiple Path Particle Deposition (MPPD MPPD Multi-Purpose Peripheral Device MPPD Machine, Process, and Product Design (University of Alabama) MPPD Multi-Pathing Proxy Driver MPPD Minimal Persistent Pigment Dose ) model (version 1.0; Chemical Industry Institute of Toxicology, Research Triangle Park Research Triangle Park, research, business, medical, and educational complex situated in central North Carolina. It has an area of 6,900 acres (2,795 hectares) and is 8 × 2 mi (13 × 3 km) in size. Named for the triangle formed by Duke Univ. , NC). We found generally good agreement among the three models, and only the data from the MPPD predictions are shown. This model was chosen in part because it allowed predictions to be calculated using each subject's functional residual capacity functional residual capacity n. Abbr. FRC The volume of gas remaining in the lungs at the end of a normal expiration. Also called functional residual air. , mean respiratory frequency, and mean [V.sub.T] during rest and exercise. Default values entered for all subjects were mouth breathing, upper respiratory tract volume 50 mL, inspiratory:expiratory ratio 1:2, and nominal particle density 1.5 g/[cm.sup.3]. Model predictions for 23 nm particles were not affected by changes in particle density or inspiratory:expiratory ratio. Data means were compared using the two-tailed Student's t-test (Brown 1980), with p < 0.05 denoting significance. Results The sex, mean age, and spirometric values of the subjects are shown in Table 1. Spirometry Spirometry The measurement, by a form of gas meter, of volumes of gas that can be moved in or out of the lungs. The classical spirometer is a hollow cylinder (bell) closed at its top. was within normal limits for most subjects; for five subjects the [FEV.sub.1] was < 80% of predicted. Table 2 shows the mean [V.sub.T], respiratory frequency, and minute ventilation during the exposures, at rest, and during exercise. The particle size distributions for the inhaled and exhaled aerosols were nearly identical, indicating little particle agglomeration ag·glom·er·a·tion n. 1. The act or process of gathering into a mass. 2. A confused or jumbled mass: or hygroscopic hygroscopic /hy·gro·scop·ic/ (hi?gro-skop´ik) readily absorbing moisture. hy·gro·scop·ic adj. Readily absorbing moisture, as from the atmosphere. growth. Technical difficulties precluded the measurement of the number DF at rest in one subject, and the mass DF during exercise in another subject. Table 3 lists the DF for each particle size bin at rest and during exercise, as well as the total particle DF by number and mass. The total respiratory number deposition was high at 0.76 and increased further to 0.86 with exercise. The DF increased with exercise in all size bins. The number DF for the smallest particles in the size distribution (< ~15 nm) was > 0.9. No significant sex differences were found. Figure 1 compares these experimental data with predicted deposition according to the MPPD model. Overall, the model predicted little increase in DF with exercise, and the experimental data exceeded model predictions during exercise (Figure 1B). [FIGURE 1 OMITTED] Table 4 and Figure 2 provide comparisons of particle deposition in the present study with our previous findings in healthy subjects. The number DF during breathing at rest was significantly increased in subjects with asthma compared with healthy subjects. Deposition was similar in healthy and asthmatic subjects during exercise. In both healthy and asthmatic subjects, exercise produced an approximate 4-fold increase in particle deposition rate, as a consequence of both increased minute ventilation and DF. The calculated total number (and mass) of deposited particles during the 2-hr exposures was 74% (and 80%) higher during rest, and 43% (and 47%) higher during exercise, for the asthmatic subjects than for the healthy subjects. This was the result of both the higher DF and increased minute ventilation in the asthmatic subjects. When both the healthy subjects from Daigle et al. (2003), and the present subjects with asthma were considered together, there was no significant relationship between [FEV.sub.1] and the DF of UFPs (Figure 3). However, the DF increased with increases in [V.sub.T] (Figure 4). [FIGURES 2-4 OMITTED] Discussion The dose of particles that reaches the lung is a determinant of the pulmonary response to inhalation. If the lung dose of UFPs is higher for people with asthma than for healthy people given the same exposure, the risk for health effects may also be increased. Thus, determining particle deposition is important in understanding susceptibility. These studies confirm our previous observation of high total respiratory deposition of UFPs in humans (Daigle et al. 2003) and indicate that subjects with asthma, when breathing on a mouthpiece, have increased UFP fractional deposition compared with healthy subjects. Previous studies (Anderson et al. 1990; Bennett et al. 1997; Brown et al. 2002; Svartengren et al. 1991) have shown that patients with chronic obstructive lung disease have enhanced deposition of fine particles and UFPs. Fine particle deposition is increased in people with asthma. For example, Kim and Kang (1997) studied healthy and asthmatic subjects inhaling an aerosol of 1 [micro]m sebacate particles. Fractional deposition was 0.14 [+ or -] 0.02 and 0.22 [+ or -] 0.02 for the healthy and asthmatic subjects, respectively, and the DF correlated inversely with the severity of airway obstruction. The present study is the first effort to measure UFP deposition in subjects with asthma. In our previous study of healthy subjects (Daigle et al. 2003), UFP deposition increased significantly with exercise, exceeding model predictions. In the present study, deposition also increased with exercise in the subjects with asthma, but the increase was of a smaller magnitude and was not statistically significant, perhaps because possible factors that increase UFP deposition during exercise, such as increased alveolar volume and airway turbulence, are already present in the asthmatic lung at rest. Patients with obstructive lung disease have a higher minute ventilation than do healthy people, because of increased dead-space ventilation (Tobin et al. 1983). In comparison with our previous study of healthy individuals, during breathing on the mouthpiece at rest, the breathing frequency was 10% higher (17.8 vs. 16.0 breaths/min), and [V.sub.T] was 25% higher (564 vs. 749 mL), giving a minute ventilation for asthmatics that was 32% higher (9.0 vs. 13.3 L/min). We speculate that the increased minute ventilation and hyperinflation Hyperinflation Extremely rapid or out of control inflation. Notes: There is no precise numerical definition to hyperinflation. This is a situation where price increases are so out of control that the concept of inflation is meaningless. that are characteristic of even mild asthma enhance diffusional deposition of UFPs in the distal airways and alveoli Alveoli Small air sacs or cavities in the lung that give the tissue a honeycomb appearance and expand its surface area for the exchange of oxygen and carbon dioxide. . We did not find a significant relationship between [FEV.sub.1] and DF (Figure 3), perhaps partly because this study was limited to subjects with mild airway obstruction, and [FEV.sub.1] was > 70% of predicted for all subjects. It is also possible that the degree of airway obstruction is a less important determinant of UFP deposition than of fine particle deposition, where impaction and sedimentation play more important roles. Additional studies are needed in people with asthma with greater impairment in lung function to determine this relationship. We did observe a significant correlation between [V.sub.T] and DF. Indeed, increases in [V.sub.T] would be expected to increase diffusional deposition because of longer residence time for particles in the distal lung; this has been confirmed experimentally in subjects inhaling UFPs under controlled breathing conditions (Jaques and Kim 2000). Breathing on a mouthpiece tends to alter respiratory patterns, with larger [V.sub.T] and minute ventilation than during unencumbered breathing (Paek and McCool 1992). It is possible that mouthpiece breathing induced greater increases in [V.sub.T] and minute ventilation in the subjects with asthma than in healthy subjects, and that this contributed to the observed increase in UFP deposition. Nasal deposition would also be expected to contribute to the deposition values, further increasing the total value. The demarcation between upper respiratory tract and lower respiratory tract Noun 1. lower respiratory tract - the bronchi and lungs lung - either of two saclike respiratory organs in the chest of vertebrates; serves to remove carbon dioxide and provide oxygen to the blood deposition would be different but mainly in that the former is larger. Thus, the conclusions reached in this study would be expected to apply to nasal breathing studies as well. Further studies using controlled breathing patterns, or face mask exposures, in healthy and asthmatic subjects would help to address this possibility. These studies indicate that UFP deposition is greater in people with asthma than in healthy people. When both the increased DF and minute ventilation were considered, the total number of particles retained in the lung was 74% greater in subjects with asthma than in healthy subjects. Thus, people with asthma have a higher total respiratory dose of UFPs for a given exposure, which may contribute to their increased susceptibility to the health effects of air pollution. This work was supported by National Institutes of Health grants RO1 ES011853, P30 ESO ESO European Southern Observatory ESO Educación Secundaria Obligatoria (Spain: compulsory secondary education) ESO European Organisation for Astronomical Research in the Southern Hemisphere ESO Edmonton Symphony Orchestra 01247, and RRO RRO Regulatory Reform Order (UK Office of the Deputy Prime Minister Fire Safety) RRO Robert's Rules of Order RRO Reproduction Rights Organisation RRO Regional Reliability Organization RRO Registered Roof Observer 0044; U.S. Environmental Protection Agency Environmental Protection Agency (EPA), independent agency of the U.S. government, with headquarters in Washington, D.C. It was established in 1970 to reduce and control air and water pollution, noise pollution, and radiation and to ensure the safe handling and (EPA EPA eicosapentaenoic acid. EPA abbr. eicosapentaenoic acid EPA, n.pr See acid, eicosapentaenoic. EPA, n. ) assistance agreement R827354-01; Electric Power Research Institute grant WO6325-01; and Health Effects Institute The Health Effects Institute (HEI) is a non-partisan, non-profit corporation specializing in research on the health effects of air pollution. It is headquartered in Charlestown, Massachusetts, USA. (HEI HEI Higher Education Institution (UK) HEI Health Effects Institute HEI Hautes Études Internationales HEI House Ear Institute HEI Healthy Eating Index HEI Hautes Etudes d'Ingénieur HEI High-Explosive Incendiary ) contract 98-19. Research described in this article was conducted under contract to the HEI, an organization jointly funded by the U.S. EPA (assistance agreement X-812059) and automotive manufacturers. The contents of this article do not necessarily reflect the views of the HEI, nor do they necessarily reflect the policies of the U.S. EPA or of automotive manufacturers. The authors declare they have no competing financial interests. 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Respiratory allergy: what are the uncertainties? Toxicology 181-182:305-310. Kim CS, Kang TC. 1997. Comparative measurement of lung deposition of inhaled fine particles in normal subjects and patients with obstructive airway disease. Am J Respir Crit Care Med 155:899-905. Morris J, Koski A, Johnson L 1971. Spirometric standards for healthy nonsmoking non·smok·ing adj. 1. Not engaging in the smoking of tobacco: nonsmoking passengers. 2. Designated or reserved for nonsmokers: the nonsmoking section of a restaurant. adults. Am Rev Respir Dis 103:57-61. NCRP. 1997. Deposition, retention and dosimetry of inhaled radioactive substances. NCRP Report No. 125. Bethesda, MD:National Council on Radiation Protection and Measurements The National Council on Radiation Protection and Measurements (NCRP) is a U.S. organization which seeks to formulate and widely disseminate information, guidance and recommendations on radiation protection and measurements which represent the consensus of leading scientific . Oberdorster G, Gelein RM, Ferin J, Weiss B. 1995. Association of particulate air pollution and acute mortality: involvement of ultrafine particles? Inhal Toxicol 7:111-124. Paek D, McCool FD. 1992. Breathing patterns during varied activities. J Appl Physiol 73:887-893. Penttinen P, Timonene KL, Tiittanen P, Mirme A, Ruuskanen J, Pekkanen J. 2001. Number concentration and size of particles in urban air: effects on spirometric lung function in adult asthmatic subjects. Environ Health Perspect 109:319-323. Peters A, Wichmann HE, Tuch T, Heinrich J, Heyder J. 1997. Respiratory effects are associated with the number of ultrafine particles. Am J Respir Crit Care Med 155:1376-1383. Pope CA, Burnett RT, Thurston GD, Thun MJ, Calle EE, Krewski D, et al. 2004. Cardiovascular mortality and long-term exposure to particulate air pollution. Epidemiological evidence of general pathophysiological pathways of disease. Circulation 109:71-77. Roth C, Scheuch G, Stahlhofen W. 1994. Clearance measurements with radioactively labelled ultrafine particles. Ann Occup Hyg 38(suppl 1):191-106. Schiller CF, Gebhart J, Heyder J, Rudolf G, Stahlhofen W. 1988. Deposition of monodisperse A collection of objects are called monodisperse if they have the same size - i.e. their size distribution is effectively a delta function. A sample of objects with a broader size distribution is called polydisperse. In practice, exactly monodisperse collections rarely exist. insoluble aerosol particles in the 0.0005 to 9.2 [micro]m size range within the human respiratory tract. Ann Occup Hyg 32(suppl 1):41-49. Svartengren M, Anderson M, Bylin G, Philipson K, Camner P. 1991. Regional deposition of 3.6-mm particles and lung function in asthmatic subjects. J Appl Physiol 71:2238-2243. Tobin MJ, Chada TS, Jenouri G, Birch SJ, Gazeroglu HS, Sackner MA. 1983. Breathing patterns: 2. Diseased subjects. Chest 84:280-294. Utell MJ, Frampton MW. 2000. Who is susceptible to particulate matter and why? Inhal Toxicol 12(suppl 1):37-40. Wichmann H-E, Spix C, Tuch T, Wolke G, Peters A, Heinrich J, et al. 2000. Daily Mortality and Fine and Ultrafine Particles in Erfurt, Germany. Part I: Role of Particle Number and Particle Mass. HEI Research Report No. 98. Boston, MA: Health Effects Institute, 1-86. Wilson FJ Jr, Hiller FC, Wilson JD, Bone RC. 1985. Quantitative deposition of ultrafine stable particles in the human respiratory tract. J Appl Physiol 58:223-229. David C. Chalupa, (1) Paul E. Morrow, (2) Gunter Oberdorster, (2) Mark J. Utell, (1,2) and Mark W. Frampton (1,2) Department of (1) Medicine and (2) Environmental Medicine, University of Rochester School of Medicine and Dentistry, Rochester, New York This article is about the city of Rochester in Monroe County. For the town in Ulster County, see Rochester, Ulster County, New York. Rochester, once known as The Flour City, and more recently as The Flower City or , USA Address correspondence to M. W. Frampton, University of Rochester School of Medicine, 601 Elmwood Ave., Box 692, Rochester, NY 14642-8692 USA. Telephone: (585) 275-4861. Fax: (585) 273-1114. E-mail: mark_frampton@urmc.rochester.edu
Table 1. Subject demographics and lung function.
Characteristics Mean [+ or -] SD
Age (years) 23.0 [+ or -] 2.7
M/F 8/8
Height (cm) 170 [+ or -] 8
Weight (kg) 80 [+ or -] 15
[FEV.sub.1] (L/% predicted) 3.71 [+ or -] 0.91/97.6 [+ or -] 5.0
FVC (L/% predicted) 4.77 [+ or -] 1.05/106.2 [+ or -] 14.5
[FEV.sub.1]/FVC (%) 77.8 [+ or -] 6.9
[FEF.sub.25-75] (L/% 3.32 [+ or -] 1.34/77.6 [+ or -] 29.7
predicted)
[D.sub.L]CO (mL/min/mmHg/ 31.35 [+ or -] 7.15/99.7 [+ or -] 12.5
% predicted)
Abbreviations: [D.sub.L]CO, diffusing capacity for carbon monoxide;
[FEF.sub.25-75], forced expiratory flow rate at 25-75% of vital
capacity.
Table 2. Breathing parameters (mean [+ or -] SD, n = 16).
Tidal Respiratory Minute
volume frequency ventilation
(L) (breaths/min) (L/min)
Rest 0.78 [+ or -] 0.14 18 [+ or -] 2.5 13.3 [+ or -] 2.0
Exercise 1.71 [+ or -] 0.46 25 [+ or -] 3.8 41.9 [+ or -] 9.0
Table 3. Particle number OF by particle size (n = 15).
Midpoint diameter DF at rest (mean DF during exercise
[range (nm)] [+ or -] SD) (mean [+ or -] SD)
8.7 (7.5-10.0) 0.84 [+ or -] 0.03 0.93 [+ or -] 0.02
11.6 (10.0-13.3) 0.83 [+ or -] 0.04 0.91 [+ or -] 0.03
15.4 (13.3-17.8) 0.80 [+ or -] 0.05 0.89 [+ or -] 0.03
20.5 (17.8-23.7) 0.77 [+ or -] 0.06 0.86 [+ or -] 0.04
27.4 (23.7-31.6) 0.72 [+ or -] 0.07 0.82 [+ or -] 0.05
36.5 (31.6-42.2) 0.68 [+ or -] 0.08 0.77 [+ or -] 0.06
48.7 (42.2-56.2) 0.66 [+ or -] 0.08 0.75 [+ or -] 0.06
64.9 (56.2-75.0) 0.65 [+ or -] 0.09 0.73 [+ or -] 0.07
Total DF by particle number 0.76 [+ or -] 0.05 0.86 [+ or -] 0.04
Total DF by particle mass 0.69 [+ or -] 0.07 0.79 [+ or -] 0.06
Table 4. Fractional and total particle deposition in healthy and
asthmatic subjects exposed to carbon UFPs for 2 hr (mean [+ or -] SD).
No. DF Mass DF
Healthy
Rest 0.65 [+ or -] 0.10 (n = 19) 0.59 [+ or -] 0.10 (n = 19)
Exercise 0.83 [+ or -] 0.04 (n = 7) 0.77 [+ or -] 0.06 (n = 7)
Asthma
Rest 0.76 [+ or -] 0.05 (n = 15) 0.69 [+ or -] 0.07 (n = 15)
Exercise 0.86 [+ or -] 0.04 (n = 15) 0.79 [+ or -] 0.06 (n = 15)
Total no. deposited Total mass deposited
(x [10.sup.12]) ([micro]g)
Healthy
Rest 0.70 [+ or -] 0.17 (n = 16) 3.24 [+ or -] 0.96 (n = 16)
Exercise 3.35 [+ or -] 0.90 (n = 4) 15.31 [+ or -] 0.84 (n = 4)
Asthma
Rest 1.22 [+ or -] 0.23 (n = 15) 5.83 [+ or -] 2.37 ( n = 15
Exercise 4.79 [+ or -] 1.19 (n = 15) 22.56 [+ or -] 8.96 (n = 15)
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