Long-term biokinetics and radiation exposure of patients undergoing 14C-glycocholic acid and 14C-xylose breath tests.

The (14)C-glycocholic acid and (14)C-xylose breath tests are clinically used for the diagnosis of intestinal diseases, such as bacterial overgrowth in the small intestine. The two tests have in earlier studies been thoroughly evaluated regarding their clinical value, but due to the long physical half-life of (14)C and the limited biokinetic and dosimetric data, which are available for humans, several hospitals have been restrictive in their use. The aim of this study was to investigate the long-term biokinetics and dosimetry of the two (14)C compounds in patients and volunteers, using the highly sensitive accelerator mass spectrometry (AMS) technique. Eighteen (18) subjects were included, 9 for each compound. The (14)C content in samples from exhaled air, urine, and, for some subjects, also feces were analyzed with both liquid scintillation counting (LSC) and AMS. The results from the glycocholic acid study showed that, up to 1 year after the administration, 67%+/-6% (mean+/-standard deviation) of the administered activity was recovered in exhaled air, 2.4%+/-0.4% was found in urine, and 7.6% (1 subject) in feces. In the xylose study, the major part was found in the urine (66%+/-2%). A significant part was exhaled (28%+/-5%), and the result from an initial 72-hour stool collection from 2 of the subjects showed that the excretion by feces was insignificant. The absorbed dose to various organs and tissues and the effective dose were calculated by using biokinetic models, based on a combination of experimental data from the present study and from earlier reports. In the glycocholic acid study, the highest absorbed dose was received by the colon (1.2 mGy/MBq). In the xylose study, the adipose tissue received 0.8 mGy/MBq. The effective dose was estimated to 0.5 (glycocholic acid) and 0.07 mSv/MBq (xylose). Thus, from a radiation protection point of view, we see no need for restrictions in using the two (14)C-labeled radiopharmaceuticals on adults with the activities normally administered (0.07-0.4 MBq).

Site of deposition and absorption of an inhaled hydrophilic solute.

AIMS: To characterize the absorption kinetics and bioavailability of an inhaled hydrophilic solute deposited at various sites within the airways. METHODS: Nine healthy nonsmokers received one intravenous, one oropharyngeal and two pulmonary doses of technetium-99 m-labelled diethylene triamine pentaacetic acid ((99m)Tc-DTPA) in an open and crossover fashion. Pulmonary doses were administered as nebulized large and fine droplet-sized aerosols by Pari and UltraVent nebulizers at fairly rapid and slow inhalation flows, respectively. Plasma concentration-time profiles and 24 h urinary excretion of radioactivity were determined. One dose of (99m)Tc-labelled Nanocoll, as a marker of mucociliary clearance (MCC), was also administered by Pari for similar lung deposition as the (99m)Tc-DTPA and followed by repeated chest gamma-imaging. RESULTS: Intrapulmonary deposition patterns of (99m)Tc-DTPA differed significantly (the mean ratio of penetration index (Pari : UltraVent) was 76% with 95% CI 63%, 91%). However, no differences in rate or extent of (99m)Tc-DTPA absorption were detected. Mean absorption time was 1.8 h (mean difference (Pari-UltraVent): -0.1 h with 95% CI -0.6 h, 0.3 h) and the bioavailability was 70% (mean ratio (Pari : UltraVent): 101% with 95% CI 90%, 115%). The pulmonary elimination half-life of (99m)Tc-Nanocoll (8 h and 45 min) was significantly longer than that of (99m)Tc-DTPA (less than 2 h). The oral bioavailability of (99m)Tc-DTPA was estimated to be 3.1%. CONCLUSIONS: The main elimination pathway of the inhaled hydrophilic solute (99m)Tc-DTPA from the lungs is trans-epithelial absorption. Despite different intrapulmonary radioaerosol deposition patterns, as verified by gamma scintigraphy, no differences in (99m)Tc-DTPA absorption kinetics or bioavailability were detected.

Effects of sodium taurocholate on the absorption of inhaled 99mTc-DTPA.

PURPOSE: The effects of a natural surface-active agent, sodium taurocholate (NaTC), on the absorption of a hydrophilic solute, technetium-99m-labelled diethylene triamine pentaacetic acid (99mTc-DTPA), deposited at various sites within the airways were evaluated in this open, cross-over, and single-dose study. METHODS: Nine healthy non-smokers received 99mTc-DTPA with or without the addition of NaTC, administered as an oropharyngeal aerosol and as nebulized large and fine droplet-sized pulmonary aerosols delivered by Pari and UltraVent nebulizers inhaled at fairly rapid and slow flows, respectively. Plasma concentration versus time profiles and 24-h urinary excretion of radioactivity were assessed. Further, 99mTc-labelled human serum albumin nanocolloidal particles (99mTc-Nanocoll) were administered with or without NaTC by Pari and followed by repeated chest gamma-imaging. RESULTS: NaTC changed no pharmacokinetic parameters for oropharyngeal 99mTc-DTPA. Independent of intrapulmonary 99mTc-DTPA deposition pattern, NaTC reduced Tmax (Pari: -0.8 h; UltraVent: -1.5 h) and mean absorption time (MAT) (-0.4 h; -0.7 h), and increased bioavailability (+13%; +44%) and dose-adjusted Cmax (+54%; +103%). NaTC decreased the pulmonary 99mTc-Nanocoll disappearance half-life from 8 h and 45 min to 4 h and 19 min. CONCLUSIONS: Our findings suggest that NaTC increases both rate and extent of 99mTc-DTPA absorption throughout the lower airways, without changing 99mTc-DTPA absorption in the oral cavity.

Dose delivery late in the breath can increase dry powder aerosol penetration into the lungs.

In addition to aerosol particle size and mode of inhalation, the time-point of dose delivery during inhalation may be an important factor governing the intrapulmonary distribution of aerosolized drug. To generate different intrapulmonary deposition patterns of a drug model aerosol, a device with the capability of delivering small amounts of technetium-99m-labeled lactose dry powder at pre-set time-points during inhalation was developed. A single dose of the radioaerosol was delivered after inhalation of 20% (A) or 70% (B) of the vital capacity inhaled through the device. Twelve healthy subjects were studied in a randomized crossover fashion. Planar gamma scintigraphy was carried out, and the penetration index, PI, defined as the ratio of peripheral to central lung zone deposition of radioactivity, was estimated. A significant increase in PI from 3.0 (A) to 3.7 (B) was observed with the change from early to late delivery of the dose (p < 0.01). No difference in the total amount of radioactivity within the lungs could be detected. In conclusion, independent of total pulmonary deposition, deeper dry powder aerosol penetration into the lungs was found for the dose delivered at near end instead of at the beginning of inhalation. By computational modeling of the aerosol transport and deposition, that finding was mechanistically explained by differences in airway caliber as a consequence of the level of lung inflation at the time-point of dose delivery.

Planar gamma scintigraphy--points to consider when quantifying pulmonary dry powder aerosol deposition.

Methodological aspects of planar gamma scintigraphy used to quantify pulmonary aerosol deposition were investigated using an experimental dry powder formulation. Particles of micronized salbutamol sulphate were labelled with technetium-99m and admixed to an ordered mixture of unlabelled micronized salbutamol sulphate and larger carrier particles of lactose. The radioaerosol was administered to 24 healthy subjects, 12 in each of two consecutive, similarly designed studies. Pulmonary deposition was determined using two methods: repeated planar imaging, and pharmacokinetic assessments following charcoal co-administration to prevent gastrointestinal salbutamol absorption. After due consideration had been taken to ensure appropriate radiolabelling, image acquisition and processing procedures, a scintigraphic estimate of 26.2% (with 95% confidence interval of 24.2-28.4%) was obtained, which did not significantly differ from the pharmacokinetic estimate of 26.4% (24.4-28.7%). In summary, pre-study validation of the radiolabelling technique, quality control of radioaerosols produced during the study, correction for re-distribution of radiolabel from the lungs, selection of regions of interest, assessment of lung contours, correction for tissue attenuation of gamma rays and establishment of the actual recovery of radioactivity in the scintigraphic measurements could potentially affect the accuracy of the scintigraphic estimate of pulmonary deposition and, thus, should be carefully considered in the design or evaluation of any such study.

Planar gamma scintigraphy--points to consider when quantifying pulmonary dry powder aerosol deposition.

Methodological aspects of planar gamma scintigraphy used to quantify pulmonary aerosol deposition were investigated using an experimental dry powder formulation. Particles of micronized salbutamol sulphate were labelled with technetium-99m and admixed to an ordered mixture of unlabelled micronized salbutamol sulphate and larger carrier particles of lactose. The radioaerosol was administered to 24 healthy subjects, 12 in each of two consecutive, similarly designed studies. Pulmonary deposition was determined using two methods: repeated planar imaging, and pharmacokinetic assessments following charcoal co-administration to prevent gastrointestinal salbutamol absorption. After due consideration had been taken to ensure appropriate radiolabelling, image acquisition and processing procedures, a scintigraphic estimate of 26.2% (24.2-28.4%) was obtained, which did not significantly differ from the pharmacokinetic estimate of 26.4% (24.4-28.7%). In summary, pre-study validation of the radiolabelling technique, quality control of radioaerosols produced during the study, correction for re-distribution of radiolabel from the lungs, selection of regions of interest, assessment of lung contours, correction for tissue attenuation of gamma rays and establishment of the actual recovery of radioactivity in the scintigraphic measurements could potentially affect the accuracy of the scintigraphic estimate of pulmonary deposition and, thus, should be carefully considered in the design or evaluation of any such study.

In vitro and in vivo aspects of quantifying intrapulmonary deposition of a dry powder radioaerosol.

Pulmonary delivery of pharmaceutical aerosols can be quantified using gamma scintigraphy. Technetium-99m, the most commonly used radionuclide in scintigraphic studies, cannot be incorporated into the drug molecule and, therefore, may be distributed differently from the drug itself, particularly if the drug is presented as a solid in a liquid suspension or as a dry powder formulation. This study demonstrated the importance of using conditions relevant to the in vivo situation in the in vitro characterisation of a dry powder aerosol of 99mTc-labelled lactose. The influence of inspiratory flow on the distribution of aerosol within the lungs was investigated in eight healthy subjects who inhaled the 99mTc-labelled lactose at four flows (30,40,60 and 80 l/min). No differences in penetration index (PI) or count density distribution of radioactivity were seen, indicating that regional distribution of aerosol in healthy airways was insensitive to differences in the inspiratory effort exerted by the subject while inhaling the experimental dry powder radioaerosol.