HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Figures Only Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Calmanovici, G. P. Articles by Zubillaga, M. B. Search for Related Content PubMed PubMed Citation Articles by Calmanovici, G. P. Articles by Zubillaga, M. B.

Quality Control Validation for Exogenous Natural Surfactant Labeled with ^99mTc

¹ Radioisotopes Laboratory, School of Pharmacy and Biochemistry, University of Buenos Aires, Buenos Aires, Argentina;
² Laboratorios Bacon S.A.I.C., Buenos Aires, Argentina;
³ Physics Department, School of Pharmacy and Biochemistry, University of Buenos Aires, Buenos Aires, Argentina;
⁴ Quality Control Department, School of Pharmacy and Biochemistry, University of Buenos Aires, Buenos Aires, Argentina

ABSTRACT

Objective: Exogenous natural surfactant (ENS) labeled with ^99mTc shows an elevated lung specificity allowing the acquisition of high-quality images for ventilation scintigraphy.

Methods: The methods for ^99mTc-ENS quality control (physical properties, pH determination, radiochemical studies, and biologic studies) were evaluated and validated.

Results: The physical properties of the nonradioactive precursor and of the radiopharmaceutical were analyzed as general descriptors of the product. The pH of the radiopharmaceutical was determined by using pH test papers, a method described and validated in the United States Pharmacopeia. Chromatographic studies performed using the acetone/Whatman-1 paper system were validated as a method to evaluate the radiochemical purity of the ^99mTc-ENS. Biodistribution studies on rats after intratracheal administration were validated as a method to estimate the radiopharmaceutical biodistribution in humans.

Conclusion: The proposed method for ^99mTc-ENS quality control studies and stability studies was evaluated and validated following international standards.

Key Words: diagnostic radiopharmaceutical; ventilation; quality control; ^99mTc-ENS; validation

Exogenous natural surfactant (ENS) labeled with ^99mTc is under study as a specific aerosol scintiscanning agent (1–3). The lung distribution pattern obtained after the administration of ^99mTc-ENS is more homogeneous than the pattern obtained after the administration of diethylenetriaminepentaacetic acid labeled with ^99mTc, the radiopharmaceutical most commonly used for this study in our country, Argentina (2,3). The preparation of radiopharmaceuticals should include testing of quality assurance parameters (4) to preclude any undesirable effect on patients. Quality control for ^99mTc-ENS involves the determination of physical properties, pH, radiochemical purity (using acetone/Whatman-1 paper chromatography), and biodistribution in rats (using tracheal instillation) (5). This report describes the evaluation, selection, and validation of quality control methods for ^99mTc-ENS to ensure that these methods perform at the level required by their intended application (6–8).

MATERIALS AND METHODS

Radiolabeling Procedure
The nonradioactive precursor was a freeze-dried formulation of ENS provided by Bacon Laboratories. To obtain the ^99mTc-ENS, we added to the nonradioactive precursor a solution of pertechnetate eluted from a ⁹⁹Mo–^99mTc generator (Radiofarma) with an activity of 18,500 MBq. The final volume was 3 mL, and the final activity concentration was 0.37 GBq/mL. The content of each vial was shaken vigorously for 60 s and then allowed to stand at room temperature for at least 10 min before the analysis.

Physical Properties and pH
The physical characteristics before and after reconstitution of the formulation were examined. The sample pH was measured using pH test papers (pH 1–10; Merck), a method that has been described and validated in the United States Pharmacopeia (9,10).

Chromatographic Studies
In previous works, we demonstrated that ^99mTc-ENS remains at the origin and that free pertechnetate travels with the solvent front in this chromatographic system (5). In this work, chromatographic studies were validated as a method that evaluates the radiochemical purity of ^99mTc-ENS. For its determination, an aliquot (15 µL) of ^99mTc-ENS was spotted on Whatman-1 paper (RJM Sales, Inc.) and was developed with acetone as the mobile phase (Merck), with the solvent migrating 10 cm (1,5).

Biodistribution Studies
Biodistribution studies of radiopharmaceuticals have been validated as a methodology that estimates the biodistribution of the radiopharmaceuticals in humans (11). The experiments performed on animals adhered to ethical standards and were conducted according to local animal care regulations. Each of 70 Sprague–Dawley rats (weight range, 250–500 g) was anesthetized with 300 mg of chloral hydrate AR (Mallinckrodt) per kilogram of body weight and received an intratracheal injection of ^99mTc-ENS (0.3 mL). Thirty minutes after injection, each rat was sacrificed using a lethal dose (800 mg/kg) of chloral hydrate, and organs of interest (lungs, gastrointestinal system, heart, blood, liver, spleen, and kidneys) were excised, blotted dry, and measured for radioactivity (1,5).

Measurements
The activity of the radiopharmaceutical was measured in an ionization chamber (RADX model 255 Remote; RADX Corp.). Samples for the radiochemical purity and biodistribution studies were measured in a monochannel -spectrometer with a 5 x 5 cm NaI(Tl) standard well crystal, which was previously set to optimal electronic conditions. All counting measurements were performed with a relative error of less than 1%.

Validation of Methods
Specificity was evaluated by intentional degradation studies of the nonradioactive precursor, including acid hydrolysis (HCl, 5N; 30 min), base hydrolysis (NaOH, 5N; 30 min), oxidation (H₂O₂, 30 g/L; 30 min), heat treatment (50°C, 20 h), and exposure to artificial light (20 h). After the degradation treatments, the samples were allowed to cool to room temperature, were neutralized when required, and then were labeled with ^99mTc. For comparison, an untreated sample was labeled with ^99mTc (control sample). To evaluate precision, we studied repeatability (instrumental precision) and intermediate precision (method precision). Repeatability was evaluated by the same operator performing 10 determinations on the same day and on the same equipment. Intermediate precision was evaluated by 2 operators performing 10 determinations on different days, different weeks, and different equipment within the same laboratory, with the results compared by the Student t test (P < 0.05) (12). The results for specificity, repeatability, and intermediate precision were expressed as percentage of radioactivity at the origin (chromatographic studies) and activity concentration in the lungs (biodistribution studies). Accuracy was assessed using the addition-matrix method, by adding 10% of the radiopharmaceutical to each sample (n = 3) at 80%, 100%, and 120% of the defined activity concentration. The results were expressed as the percentage of recovery, where the added activity was the spotted activity in the chromatogram (chromatographic studies) and the injected activity by tracheal instillation (biodistribution studies). Linearity was studied by analyzing, 3 times, each of 5 radiopharmaceutical suspensions of activity concentration ranging from 0.28 to 0.56 GBq/mL. The results were expressed as the equation obtained for the linear regression and its correlation coefficient (r²) with P < 0.05 (13). Robustness for chromatographic studies was evaluated by the variation of cube saturation time (0.5–6 h), time for drying of the chromatographic strips (15 min–1 h), and distance to which the solvent migrated (8–12 cm). Robustness for biodistribution studies was evaluated by the variations of age (3–6 mo) and sex of the animals, time of measurement after dissection (15 min–2 h), and injected volume (0.2–0.4 mL) (6–8).

RESULTS

Physical Properties and pH
The nonradioactive precursor of the radiopharmaceutical was a white powder. ^99mTc-ENS was a white suspension with a pH of 4.0–6.0.

Validation of Chromatographic Studies
In specificity studies we observed—after oxidation, acid hydrolysis, and alkaline hydrolysis of the nonradioactive precursor—a heterogeneous distribution of radioactivity in the chromatogram, with a lower percentage of radioactivity at the origin than that in the control sample. We observed no heat-treatment or light-exposure differences from the control sample. In the repeatability studies (instrumental precision), the mean radioactivity at the origin was 99.5% (SD, 0.3%; coefficient of variation [CV], 0.3%). In the intermediate precision studies (method precision), the mean remaining at the origin was not statistically different between the 2 operators (99.5% and 99.0%; SD, 0.3% and 0.6%; CV, 0.4% and 0.6%; P > 0.05). The accuracy studies demonstrated nearly 100% recovery (98.0%–99.5%; mean, 98.9%), with a CV of 0.95% (Table 1). The regression curve proved linearity (r² = 0.9999; P < 0.05), with a y-intercept of (0.01046 ± 0.00979) and a slope of (7.92900 ± 0.02715) (Fig. 1). The robustness studies showed a lack of influence of the operative variables under study compared with the results obtained without variables (Table 2).

View larger version (10K): [in this window] [in a new window]   FIGURE 1. Linearity evaluation for chromatographic studies. AC = activity concentration of 99mTc-ENS; A origin = activity at origin of acetone/Whatman-1 paper chromatography.

View larger version (10K): [in this window] [in a new window]   FIGURE 2. Linearity evaluation for biodistribution studies. AC = activity concentration of 99mTc-ENS; A lungs = activity in lungs in biodistribution studies.

As general descriptors of the product, the physical properties of the nonradioactive precursor and of the radiopharmaceutical were analyzed—a useful preliminary evaluation (14). The pH of the radiopharmaceutical was determined by a method described in the United States Pharmacopeia (9,10). Application of this method took into account the fact that radiopharmaceuticals must have an appropriate concentration of hydrogen ions for their stability and integrity (11) and that degradation of many drugs in solution is accelerated or decelerated exponentially as the pH is varied over a specific range (15).

The chromatographic studies were validated as a method to evaluate the radiochemical purity of ^99mTc-ENS. The biodistribution studies were validated as a method to estimate radiopharmaceutical biodistribution in humans according to biodistribution in animals. Both methods were proven to be specific, precise, accurate, linear, and robust. Regarding specificity, after intentional degradation of the nonradioactive precursor of the radiopharmaceutical, we observed a heterogeneous distribution of the radioactivity in the chromatographic studies and in the biodistribution studies, indicating the presence of degradation products. Precision was proven by the low SD shown for both methods in the repeatability studies (instrumental precision) and by the nonsignificant difference between the 2 operators shown in the intermediate precision studies (method precision). Accuracy was proven by the nearly 100% recovery shown for both methods. Linearity was proven by the regression curve for both methods. Regarding robustness, for the variables studied we observed neither a variation in the percentage of radioactivity remaining at the origin (for the chromatographic studies) nor a variation in the percentage of radioactivity in the lungs (for the biodistribution studies) (6–8,16).

CONCLUSION

The proposed method for ^99mTc-ENS quality control and stability studies was evaluated and validated following international standards (6–8). This method involves determining the physical properties of the nonradioactive precursor and of the radiopharmaceutical, determining pH, determining radiochemical purity by acetone/Whatman-1 paper chromatography, and determining biodistribution in rats after intratracheal administration of the radiopharmaceutical. In this way, we can guarantee the quality of the product for its proposed use.

FOOTNOTES

For correspondence or reprints contact: Gabriela P. Calmanovici, PhD, Radioisotopes Laboratory, School of Pharmacy and Biochemistry, University of Buenos Aires, Junín 956, Piso Bajo, 1113 Buenos Aires, Argentina.

E-mail: gcalmano{at}ffyb.uba.ar

REFERENCES

1. Calmanovici G, Zubillaga M, Lysionek A, et al. ^99mTc-ENS, a new radiopharmaceutical for aerial lung scintigraphy: comparative studies in rats. Nucl Med Biol. 1998;25:511–513.[Medline]
2. Calmanovici G, Boccio J, Goldman C, et al. ^99mTc-ENS ventilation scintigraphy: preliminary study in human volunteers. Nucl Med Biol. 2000;27:215–218.[Medline]
3. Mayosky C, Saravia G, Nicolini JO, et al. ^99mTc-ENS vs ^99mTc-DTPA as aerosol lung scintiscanning agents. Alasbimn Journal [serial online]. 2004;6(24):article no. AJ24–3.
4. Decristoforo C, Siller R, Chen F, et al. Radiochemical purity of routinely prepared ^99mTc-radiopharmaceuticals: a retrospective study. Nucl Med Commun. 2000;21:349–354.[Medline]
5. Calmanovici GP, Caro RA, Goldman CG, et al. Quality control methods for ^99mTc-labeled exogenous natural surfactant (^99mTc-ENS). J Labelled Compds Radiopharm. 2004;47:47–53.
6. The United States Pharmacopeia—The National Formulary (USP-NF). Validation of compendial methods. In: USP 27-NF 22, 2004. Rockville, MD: United States Pharmacopeial Convention Inc; 2003:2622–2625.
7. Expert Working Group (Quality) of the International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use (ICH). Guidance for industry: Q1A(R2)—stability of new drug substances and products. In: International Conference on Harmonization. Edited by the European Agency for the Evaluation of Medicinal Products (EMEA), London, U.K., February 20, 2003. Available at: www.emea.eu.int/pdfs.human/ich/273699en.pdf. Accessed October 7, 2005.
8. Comisión Permanente de la Farmacopea Argentina. Validación de métodos analíticos. In: Farmacopea Argentina Séptima Edición. Vol. 1. Argentina: Ministerio de Salud, Administración Nacional de Medicamentos, Alimentos y Tecnología Médica; 2003:403–407.
9. The United States Pharmacopeia—The National Formulary (USP-NF). pH. In: USP 27-NF 22, 2004. Rockville, MD: United States Pharmacopeial Convention Inc; 2003:2344–2345.
10. The United States Pharmacopeia—The National Formulary (USP-NF). Indicators and indicator test papers. In: USP 27-NF 22, 2004. Rockville, MD: United States Pharmacopeial Convention Inc.; 2003:2722–2723.
11. Castiglia S, da Silva C, de Pereira N, et al. Capítulo III: requisitos de control de calidad. In: Manual de Protocolos de Calidad de Radiofármacos. Vienna, Austria: International Atomic Energy Agency; 1999:15–23.
12. Dawson-Sanders B, Trapp R. Capítulo 7: estimación y comparación de medias. In: Bioestadística Médica. Mexico City, Mexico: Manual Moderno; 1997:119–147.
13. Motulosky H, Christopoulos A. Fitting models to biological data using linear and nonlinear regression: a practical guide to curve fitting. San Diego, CA: GraphPad Software Inc; 2003.
14. The United States Pharmacopeia—The National Formulary (USP-NF). Description and solubility. In: USP 27-NF 22, 2004. Rockville, MD: United States Pharmacopeial Convention Inc; 2003:2747–2788.
15. The United States Pharmacopeia—The National Formulary (USP-NF). Stability considerations in dispensing practice. In: USP 27-NF 22, 2004. Rockville, MD: United States Pharmacopeial Convention Inc; 2003:2605–2608.
16. Quattrocchi O, Abelaira de Andrizzi S, Laba R. Capítulo 12: validación de métodos. In: Introducción a la HPLC: Aplicación y Práctica. Buenos Aires, Argentina: Artes Gráficas S.A.; 1992:301–328.

This Article Abstract Figures Only Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Calmanovici, G. P. Articles by Zubillaga, M. B. Search for Related Content PubMed PubMed Citation Articles by Calmanovici, G. P. Articles by Zubillaga, M. B.