Negligible clearance of ultrafine particles retained in healthy and affected human lungs

Epidemiological studies provide evidence that air pollution contributes to systemic as well as pulmonary diseases and reactive airway effects 1–6. These findings pertain to elderly people and susceptible persons with underlying diseases of various origins 7. Ultrafine particles (<100 nm diameter) represent a substantial component of the particulate matter in ambient air. Ultrafine particles are more toxic and induce more severe inflammation than larger particles 8. The mechanisms underlying the effects are largely unknown, but autonomic regulation of the heartbeat, inflammation and systemic coagulation effects, and direct metal toxicity to the heart muscle are proposed mechanisms 7, 9, 10. It is essential to establish if insoluble particles can enter the systemic circulation, or if particles’ specific effects are initiated in the lung.

Recently, Nemmar et al. 11 exposed five human subjects by inhalation to technetium 99m (^99mTc)-labelled ultrafine particles and observed translocation of ^99mTc into the blood compartment. Leaching of the label affected the result due to the difficulty in differentiating between the solute label and labelled ultrafine particles in blood and extrapulmonary organs.

The aim of the study was to examine whether there is a significant uptake of ultrafine particles (∼100 nm) into the systemic circulation, by measuring pulmonary retention and activity over the liver. The test particles were generated with a new modified method developed by the research groups involved.

MATERIALS AND METHODS

Exposure

A fresh aerosol of radiolabelled carbonaceous particles of 100-nm diameter was produced for every subject using a Technegas Generator^TM (fig. 1⇓).

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Fig. 1—

Experimental set-up. The concentrated aerosol in the Technegas Generator^TM (Tetley Manufacturing Ltd, Sydney, Australia) is diluted into the flexible conductive bag (70 L). Size distribution and number concentration of the diluted aerosol is monitored before and after inhalation (differential mobility particle sizer (DMPS) classifier model 3071, condensation particle counter (CPC) models 3010 and 3020). The test subject inhales aerosol via a mouthpiece connected to the flexible bag.

The subjects were instructed to inhale aerosol in deep and slow breaths with a breath-hold. Mean±sd deposited activity was 26±11 MBq. The specific activity of each aerosol was calculated as activity deposited on teflon filters (0.2-μm pore, PTFE; Pall Corporation, East Hills, NY, USA) divided by the aerosol volume sampled through the filter.

Measurement of retention and clearance

Activity in the chest region was measured with the subject in a supine position, immediately after aerosol inhalation and after 2, 24, 46 and 70 h (fig. 2⇓). In the first three measurements, planar images were performed with a gamma camera (TRIAD XLT 20; Trionix, Twinsburg, OH, USA), and the subsequent measurements were made with a whole-body scanner with sodium iodide (NaI) detectors (Harshaw, Paris, France) 13.

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Fig. 2—

Schematic diagram showing study design. Exposure started ∼4 min after aerosol generation. Activity in the lungs, thyroid and liver was measured initially by gamma camera (GC; 5+5 min planar scan of the anterior and posterior lung day 1, and 10+10 min day 2) and then by whole body scanner (WBS). The first measurement with the WBS (3b) was normalised to the last measurement with the GC (3a). In vitro leaching tests (↑) were performed on the remaining aerosol particles from each exposure occasion. The cumulative amount of activity leached from the particles was measured at approximately the same time interval as lung measurements were taken. In an additional leaching test, activity was measured in urine samples provided by the subjects during the first 24 h following exposure.

Deposition fraction is defined as deposited activity divided by inhaled activity. The deposited activity is the inhaled activity minus exhaled activity.

A whole-lung region of interest (ROI) was placed around the borders of each lung. Retention was computed from combined counts of left and right whole-lung ROIs.

RESULTS

Particles

The aerosols had a count median diameter of 98 nm (87 nm before inhalation; 110 nm after inhalation), a geometric sd of 1.7 (1.7–1.7), and the number concentration was 1.5×10⁶ cm^-3 (2.2×10⁶−0.9×10⁶; fig. 3⇓).

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Fig. 3—

Size distribution of technetium 99m particle aerosol. Size distribution was measured by a differential mobility particle analyser before inhalation (•) and after inhalation (○). The decrease in particle number concentration and the slight shift of the spectrum to larger sizes reflects the dynamic changes of coagulation and wall losses of the aerosol within the two time-points of measurement.

Retention, clearance and pulmonary deposition

Lung retention at 24, 46 and 70 h was 99±3.0%, 99±4.6% and 99±10.4%, respectively (fig. 4⇓). No activity could be detected in the liver or thyroid during the first and second days. The deposition fraction was 41±10%. The median value for tidal volume during exposure was 1.8 L (0.8–3.3).

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Fig. 4—

Relative retained fraction of radioactivity as a percentage of the initial lung deposition. Mean retention values of all subjects (n = 15) during 70 h of observation are shown. Data from each subject were normalised to the initial measurement of the gamma camera. Error bars indicate sd.

Leaching

Leaching data are presented in figure 5⇓. Cumulative leaching from particles at 70 h was 2.6±0.96%. Activity leaching in urine was 1.0±0.55% during the first 24 h. In contrast, leaching from particles produced with the standard Technegas Generator^TM method was 11% within 24 h (fig. 5⇓). Individual leaching did not correlate to individual retention.

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Fig. 5—

Cumulative technetium 99m leaching from particles as a percentage of initial activity. Leaching from particles generated by the modified method (▪; n = 15, except at 21 h (n = 14) and 70 h (n = 7)) is compared with the standard method (▴; n = 2). Twenty-four hour cumulative urine excretion after particle exposure (•; n = 15) is also shown for particles generated with the modified method (n = 2). Error bars indicate sd.

DISCUSSION

The current authors have shown that inhaled 100-nm carbonaceous particles largely remain inside the lungs for >3 days. Except for radiotracer leaching (1%), the particles do not show significant clearance from the lung during the 70-h observation period. If translocation occurred, it was below the detection limit of the experimental approach of the current study. There is a possibility that inhaled particles may translocate into the pulmonary interstitium without reaching the circulation 16. Other methods are required to make this distinction in particle location.

In the current study, the authors were able to produce aerosols of ultrafine carbonaceous particles labelled with ^99mTc isotopes. Particle coagulation was greatly reduced, which is clear from the results of size monitoring before and after particle inhalation. Leaching estimates were assessed for all exposures. Results on retention, activity in urine and leaching from particles indicate limited leaching of activity.

Lung retention was measured for 70 h with very sensitive detectors, which corresponds to a 3,300-fold natural decay in ^99mTc activity. The present authors think this can explain the uncertainty seen in the measurement at 70 h.

The current study shows that a convenient way to study ultrafine particles in the human lungs is to use radiolabelled particles, such as particles generated with the Technegas Generator^TM. The standard use, however, has limitations. Presence of oxygen during particle generation produces pertechnetate (^99mTcO^4-), which instantaneously leaches off the labelled particles in body fluids 17–19. Pertechnetate assembles in the thyroid and is excreted with urine within days 14, 15. This may contribute to the results interpreted as translocation in the study by Nemmar et al. 11, in which thyroid glands and bladder were visible in the whole body scan. Particle-bound ^99mTc, on the contrary, accumulates in the liver and only a limited amount is found in the bladder 20. Another problem with the standard method is that particle size grows rapidly due to large coagulation rates. Primary Technegas particles are 5–20 nm, but coagulate to a median diameter of >100 nm within minutes if not diluted into filtered air 21–23.

No retention results are reported in the study by Nemmar et al. 11, but they found 8% of the inhaled activity in the liver almost immediately after inhalation when using particles comparable to those produced with a Technegas Generator^TM under standard conditions. In the current study, no activity was found in the liver immediately after exposure or on day 2. This can be due to sensitivity problems, as only a small percentage of the activity escaped from the lung in the current study. The results of Nemmar et al. 11, however, present evidence of leaching activity from the particles, and it is not clear whether the activity in the liver is bound to primary carbon particles or plasma proteins.

Another human study reporting declining retention values was performed by Brown et al. 24, who assessed lung retention in healthy and chronic obstructive pulmonary disease patients. The ultrafine carbon particles were generated using a commercially available generator, arcing between graphite electrodes under a high-purity argon atmosphere. Lung retention was 86% 1 day after deposition, but because leaching from the particles was substantial (23%), 24-h retentions were corrected based on measured in vitro leaching of label from the particles. Another difference from the current study is that the subjects inhaled smaller particles (60 nm) under realistic resting breathing conditions (i.e. not deep breathing with breath-holding), which may have resulted in a greater fraction of particles depositing on bronchial airways, i.e. particles that might clear by mucociliary clearance.

Particle-bound and free activity in blood samples was not examined in the current study; this would have added valuable information about possible translocation. However, it is uncertain if the low levels of translocated activity seen in the current study were sufficient to be detected in the blood. In a recent study by Mills et al. 25, humans were exposed to 108-nm Technegas particles produced by the standard method. Retention was measured for a shorter time period than in the current study; at the last measurement at 6 h, retention was 95.6%. In vitro leaching from the particles was slightly higher: 5% after 6 h versus 2.6% after 70 h in the current study. Besides retention, and similar to the approach of Nemmar et al. 11, Mills et al. 25 also measured blood activity and performed thin layer chromatography; however, in contrast to Nemmar et al. 11, Mills et al. 25 found the small amount of blood-borne ^99mTc to be unbound and thus concluded that translocation of particles from the lungs to the circulation is negligible, a result confirmed by the current study.

In an animal study by Kreyling et al. 16 using ¹⁹²Ir particles, the fraction of translocated particles from the lung to extrapulmonary organs was only <0.002 and 0.001 for deposited 15- and 80-nm particles, respectively. The ¹⁹²Ir particles did not leach and the results of Kreyling et al. 16 are in agreement with the current findings.