`
`Experimental Cell Research 45, 158466 (1966)
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`© 1967 by Academic Press Inc.
`
`COMPARATIVE EFFECTIVENESS 0F INTRAPERITONEAL
`
`AND INTRAMUSCULAR 3H-TDR INJECTION
`
`ROUTES IN MICE1
`
`M. R. SKOUGAARD2 and P. A. STEWART3
`
`Biology Department, Brookhaven National Laboratory, Upton, N. Y. 11973, U.S.A.
`
`Received August 8, 1966
`
`IN tritiated thymidine (3H~TDR) autoradiography, intraperitoneal injection
`of label is very frequently used, especially in small animals. The kinetics
`of the numerous processes involved between injection and incorporation into
`nuclear DNA are not well established, however. Recent work 011 the marmo-
`
`set [14] has shown that only a small fraction of the injected 3H—TDR is incor-
`porated into DNA, and that the yield of autoradiographic grain counts
`depends on the time course of tracer concentration in the bloodstream.
`
`3H-TDR is a major part of the nonvolatile 3H-plasma activity only during
`the first few minutes after injection. Significantly different results were ob-
`tained when intramuscular (1M) rather than intraperitoneal (IP) injection
`was used The four-factor model introduced by Quastler [9] predicts such
`results, but has been tested in detail only for IP injection in the mouse [17].
`The kinetics of thymidine incorporation into DNA after IP injection into
`mice have also been studied indirectly by a number of workers. On the
`basis of time taken for maximum crypt cell labeling to occur, Quastler and
`
`Sherman [11] concluded that IP injected 3H-TDR was completely absorbed
`from the peritoneal cavity by 16 min post-injection. Quastler and Kember
`[10] measured the tritium content of peritoneal washings as a function of
`time after injection, and concluded that uptake of 3H-TDR into the circula-
`tion followed a double exponential curve with half-times of approximately
`% min and 5 min. They also found that maximum autoradiographic labeling
`had occurred in the intestinal crypt cells 15 min after the injection. Staroscik
`et al.
`[15] found uptake of 3H-TDR still occurring into mouse mammary
`
`1 Research carried out at Brookhaven National Laboratory under the auspices of the US.
`Atomic Energy Commission.
`2 Present address: Department of Periodontology, Royal Dental College, Copenhagen, Den—
`mark.
`3 Present address: Division of Medical Science, Brown University, Providence, R.I. 02912,
`U.S.A.
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`Experimental Cell Research 45
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`Intraperitoneal and intramuscular 3H—TDR injection routes in mice
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`159
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`gland tumors 40 min after injection. They estimated the rate of uptake by
`evaluating the derivative of the curve of autoradiographic labeling versus
`time after injection and found a rapid initial phase followed by an exponen-
`tial curve with a half-time of about 10 min. Bresciani [2] used the derivative
`
`of the autoradiographic labeling curve from the same tissue to estimate the
`activity of 3H-TDR in the bloodstream. He found an approximately exponen-
`tial decrease with a half-time of about 7 min. Rubini et al. [13] carried out
`
`studies of 3H-activities measured directly in the blood plasma of man follow-
`ing intravenous injection of 3H-TDR. They found a double exponential
`disappearance curve with half-times of 0.2 and 6 min.
`
`In the present study, intraperitoneal and intramuscular injection routes
`for 3H—TDR in mice have been compared with respect to the following para-
`meters:
`
`(1) Time course of blood plasma activity level of total tritium, volatile
`tritium, nonvolatile tritium and tritiated thymidine.
`
`(2) Final levels of labeling intensity (mean grains per labeled nucleus) in
`oral epithelial and intestinal crypt cell autoradiographs.
`
`MATERIALS AND METHODS
`
`Ninety-six Walter Reed Hospital Swiss pathogen—free mice from the laboratory
`colony were used for the experiment [5]. Three- to 4-month—old males from 26 litters,
`ranging from 27 to 36 g were selected. Tritiated thymidine with a specific activity
`of 6.5 c/mole was heated to 36°C and injected at a dose of 2 ye per g body weight,
`either IP or IM, into the right thigh muscle mass.
`Blood samples were taken at intervals of 1 to 90 min after injection, only one sample
`being taken from each animal. One—minute samples Were obtained by decapitating
`the animals over a heparinized centrifuge tube. Samples of 0.5 ml were obtained
`in 3 to 5 sec in this way, but the blood tended to coagulate extremely rapidly. There—
`fore this technique was only used for the 1-min samples, for which the time factor
`was critical. The later blood samples were taken by aspiration through a thin hepa—
`rinized glass pipette inserted behind the eyeball into the infraorbital venous plexus.
`Samples of 0.5 ml were obtained within 20 to 30 sec by this technique. All samples
`were immediately sealed, chilled to 4°C and centrifuged 30 min at 3450 xg. Expo—
`sure of samples to air was kept at a minimum to avoid loss of volatile tritium-con-
`taining components.
`Aliquots of 100 ,ul of plasma were transferred to counting vials and 3.9 ml ethyl
`alcohol plus 16 ml of 0.3 per cent PBD-xylene added for measurement of total plasma
`tritium activity. Volatile tritium activity was determined on another 100 [Al aliquots
`by distilling the volatile components into a counting vial chilled with dry ice and
`acetone (Fig. 1). The sample was placed in the small lower vial, which was imme—
`diately clamped to the closely—fitting upper via]. The lower vial was then heated in
`
`Experimental Cell Research 45
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`AstraZeneca Exhibit 2128 p. 2
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`160
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`M. R. Skougaard and P. A. Stewart
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`a boiling water bath while the upper vial was surrounded by the dry ice-acetone freez~
`ing mixture. After 5 min the whole unit was disassembled and the upper Vial sealed
`immediately after addition of ethyl alcohol and PB D-xylene.
`Test runs with known amounts of tritiated water showed 100 per cent recovery
`by this technique. All samples were counted in a liquid scintillation spectrometer
`for a period of time sufficient to reach a minimum of 104 counts. Background and
`standard counts were determined for each day of counting, and results corrected
`accordingly. The efficiency of the scintillation spectrometer was found to be 8 per
`cent. Nonvolatile tritium activity of plasma was calculated by subtracting volatile
`activity from total activity as determined from these two aliquots of each sample.
`For determinations of the per cent of 3H-TDR in the nonvolatile tritium activity,
`samples of pooled blood from four animals at each specific time were centrifuged.
`After protein precipitation with trichloracetic acid, plasma samples were centrifuged
`at 3450 x g for 30 min. The supernatant was neutralized to pH 7.0 with 1.0 N NaOH,
`lyophylized and reconstituted to 200 ,ul with distilled water. A 10 ,ul aliquot of this
`solution was then analyzed by ascending paper chromatography using the upper
`layer
`from an ethyl acetate:water:f0rmic acid:60:35:5 mixture [4]. Additional
`thymidine carrier was added to the sample spot before chromatography. The thy-
`midine spot was identified under ultraviolet light, cut out of the paper, eluted into
`Bray’s solution [1] and counted in the liquid scintillation spectrometer.
`The activity of 10 ,ul of the reconstituted sample was also determined by letting
`it dry into a spot on filter paper, cutting out this spot, and treating it exactly as
`the 3H—TDR spot was treated. The percentage of 3H—TDR in the total nonvola—
`tile plasma tritium activity was then calculated from the ratio of the two counts.
`For autoradiography, small pieces of intestine and sublingual tissue were fixed
`in Carnoy’s solution immediately after sacrifice, stained by conventional Feulgen
`technique and dissected to provide squash preparations of the epithelia on micro-
`scope slides. Kodak NTB liquid emulsion was used, and emulsion-covered slides were
`exposed for appropriate periods of time in the cold, with dessicant [3]. After photo-
`graphic processing, grains over the nuclei were counted and the resulting data pro-
`cessed by an IBM 7094 computer.‘
`
`RESULTS AND DISCUSSION
`
`Time course of tritiated components in bloodstream
`
`The total volatile and nonvolatile (by subtraction) plasma activities are
`plotted against time in Figs. 2—4. Each point on these curves represent the
`average value for the 4 mice sacrificed at the indicated time after injection.
`In the IP injected mice, total 3H-activity reached its maximum value of
`2 x104 cpm/IOO Ml plasma almost
`immediately following injection, and
`remained at this level during the rest of the experiment. Volatile 3H-activity
`
`1 The program for the computer was devised by Mr K. Thompson of the Biology Department,
`Brookhaven National Laboratory.
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`Experimental Cell Research 45
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`Intraperitoneal and intramuscular 3H— TDR injeclion routes in mice
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`161
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`increased at a slower rate, but eventually reached a plateau level indis—
`tinguishable from that of the total activity. The nonvolatile activity, measured
`as the difference between total and volatile, increased to a maximum and
`
`then fell off slowly to negligible values. The form of the curves for the IM
`
`(I)
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`TIME AFTER INJECTION (MINUTES)
`
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`Fig. 1.
`
`Fig. 2.
`
`Fig. 1.——Device used to collect volatile plasma components in the liquid scintillation counting
`vial (B). When sealed by the clamp the two vials, A and B, fit closely. a, dry ice acetone; b, vial;
`c, boiling water.
`Fig. 2,—Semilogarithmic graph demonstrating the total and the volatile 3H—activities in the blood
`plasma vs. time after IP injection of 3H-TDR. Each point represents the average activity for
`the 4 mice sacrificed at the time interval in question. 0—0, total plasma ”II-activity; O—O,
`volatile plasma 3H-activity.
`
`injected mice was similar, but all changes were slower. It was possible in
`this case to observe the increase in total plasma activity during the first
`5 min after IM injection, and the rate of disappearance of nonvolatile
`activity was much less than after IP injection. It is evident from the figures
`that the decrease in nonvolatile 3H-activity was exponential following IP as
`well as IM injection and dropped to negligible values by 30 min after IP or
`60 min after IM injection.
`
`Attempts were made to determine total plasma activity immediately after
`IP injection. In all cases results on the order of 2 x104 cpm/IOO yl plasma
`were obtained, so that we may take this number as a measure of the initial
`
`11 — 67 1 8 1 1
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`Experimental Cell Research 45
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`AstraZeneca Exhibit 2128 p. 4
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`162
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`M. R. Skougaard and P. A, Stewart
`
`total plasma activity. If all the injected 3H-TDR (2 uc/g) were distributed
`uniformly over the extracellular water phase, which we take to be 20 per
`cent of the body weight [6, 16], the expected initial activity would be 2 X 105
`cpm/IOO ,ul plasma. This suggests that approximately 90 per cent of the IP
`
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`Fig. 3.
`
`Fig. 4.
`
`Fig. 3,—Semilogarithmic graph demonstrating the total and the volatile 3H—activities in the blood
`plasma vs. time after 1M injection of 3H—TDR. Each point represents the average activity for
`the 4 mice sacrificed at the time interval in question. Ce 0, Total plasma aH—activity; Ogo,
`volatile plasma 3H—activity.
`
`Fig. 4.—Semilogarithmic graph showing the nonvolatile 3H-activity in the plasma vs. time after
`IP and 1M injections. 0—0, IP injection; o—O, IM injection.
`
`injected 3H—TDR is catabolized, probably via the hepatic portal system and
`the liver [8] and not released into the systemic circulation.
`Results of the paper-chromatographic analysis of the plasma tritium acti-
`vities are plotted in Fig. 5. The 3H-TDR activity constituted a rapidly decreas-
`ing percentage of the nonvolatile activity, and decreased more rapidly after
`IP than after IM injection. This difference might be expected to result from
`the more direct route to liver catabolic mechanisms from intraperitoneal sites
`than from intramuscular.
`
`Multiplying the 3H-TDR percentages from Fig. 5 by the nonvolatile acti-
`vities for corresponding times (Fig. 4) gives the actual plasma 3H-TDR values
`expressed as cpm/100 [11 plasma. In Fig. 6 these 3H—TDR concentrations
`
`Experimental Cell Research 45
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`AstraZeneca Exhibit 2128 p. 5
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`Intraperitoneal and intramuscular 3H-TDR injection routes in mice
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`163
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`are plotted as a function of time after injection. Following 1P injection, the
`plasma 3H-TDR curve is a rapidly decreasing exponential, with a half-time
`of about 2.9 min. It can be closely approximated by a single exponential
`function of the form 2.0 x104 xe‘“‘“5. After IM injection, plasma 3H-TDR
`
`IP
`
`IM
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`Fig. 5.
`
`Fig. 6.
`
`Fig. 5.~The 3H-TDR as per cent of the nonvolatile aH—activity vs. time after IP and IM injec-
`tions. 0—0, IP injection; O—O, IM injection.
`
`Fig. 6.~3H—TDR plasma activity vs.
`O—O, IM injection.
`
`time after IP and IM injections. 0—0, IP injection;
`
`activity increased to a maximum of 9 ><103 cpm/lOO ,ul plasma at about 5
`min after injection, followed by an exponential decrease. This curve can be
`approximated by a double exponential of
`the form 2.5 ><10‘1 ><(e'“”—
`e—t/2.5).
`Since in both cases negligible plasma 3H-TDR activity was left after
`60 min, the integral of either function from zero to 60 min is a measure of
`the cumulative amount of 3H-TDR available for incorporation after a single
`injection in counts per 100 u] plasma. The same quantities can be calculated
`by measuring the areas under the curves of 3H-TDB activity. The results of
`these calculations show that the cumulative 3H—TDR available was 92 ><103
`
`counts/100 ‘ul plasma after IP and 120 ><103 counts/100 ,ul after IM injection.
`In summary, these results show that after IP injection, plasma 3H-TDR
`
`Experimental Cell Research 45
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`AstraZeneca Exhibit 2128 p. 6
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`164
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`M. R. Skougaard and P. A. Stewart
`
`levels rise extremely rapidly and then fall off exponentially. After IM injec-
`tion, plasma 3H-TDR levels rise more slowly to a maximum after about
`5 min, and then fall off exponentially, but more slowly than after IP injec—
`tion. The cumulative amount of plasma 3H—TDB available for incorporation
`
`TABLE I. Labeling intensity expressed as the average of the mean grain counts
`from autoradiographs of crypt and tongue epithelium following IP and IM
`injections of 3H—TDR.
`Each average for the crypt cell data is compiled from 5 mice and for the tongue
`epithelium from 4 mice.
`
`Average mean
`Injection
`grain count
`Standard error
`
`Cell type
`route
`(grains/nucleus)
`(grains/nucleus)
`
`Crypt
`Crypt
`Tongue
`Tongue
`
`IP
`IM
`1P
`1M
`
`24.5
`13.7
`17.2
`15.5
`
`1.4
`1.5
`2.5
`2.7
`
`into nuclear DNA is approximately the same in each case, in spite of these
`marked differences in kinetics.
`
`Autoradiograph grain counts
`
`The grain count distributions from the autoradiographs obtained from
`10 mice sacrificed 1 hr after either IM or IP injection of 3H-TDR all showed
`the same general pattern. The numerous problems involved in interpreting
`precisely such a distribution have been discussed previously [7, 12, 14].
`For the present purposes we have arbitrarily taken the mean grains per
`nucleus for nuclei with 4 or more grains as the parameter to characterize
`labeling intensity. The results are listed in Table I. It will appear that
`there is no marked difference in labeling intensity between tongue epithelial
`cells in IP and IM injected mice, as would be expected from the figures ob-
`tained above for the amounts of 3H-TDR available. In the IM case, there is
`
`also no significant difference between tongue epithelial cells and intestinal
`crypt cells, as would be expected if both cell types are taking up 3H-TDR
`from the same plasma, and have similar DNA synthesis rates.
`There is, however, a significant difference between the labeling intensities
`of crypts cells and tongue epithelial cells in mice after 1P injection, the crypt
`cells having roughly twice the labeling intensity of the tongue epithelial cells.
`
`Experimental Cell Research 45
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`Intraperitoneal and intramuscular 3H-TDR injection routes in mice
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`165
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`The simple fact of proximity of the crypt cells to the high concentration of
`3H-TDR injected may provide a partial explanation for this difference.
`Direct uptake of tracer from the peritoneal cavity into the tissue fluid sur-
`rounding the intestinal crypt cells might occur. More in line with the comments
`above concerning the importance of the hepatic portal system, however, is
`the notion that uptake from the peritoneal cavity into the intestinal circula-
`tion may be significant, both in channeling the 3H-TDR to the liver, for
`removal, and in supplying the intestinal crypt cells initially with a much
`higher effective dose than that eventually supplied to cells such as tongue
`epithelium more remote from the injection site.
`In all cases, the variability in the grain counts, expressed as the standard
`
`error of the mean grains per nucleus, is about 20 per cent. The reasons for
`such a high variation are still not clear [17]. There seems to be no evidence
`
`in this study that IM injection in mice results in a lower variability, in either
`cell type.
`
`SUMMARY AND CONCLUSIONS
`
`Blood samples were taken from 96 mice at various time intervals after
`
`intraperitoneal (IP) or intramuscular (1M) injections of 3H—TDR. The total
`volatile and nonvolatile 3H-plasma activities were determined in a liquid
`scintillation spectrometer. The 3H-TDR time curve was found by paper
`chromatography analysis of the nonvolatile plasma components. Following
`IP injections, the plasma 3H-TDR concentration decreased exponentially with
`a half-time of 2.9 min, and with effectively complete plasma clearance, by
`30 min. With IM injection, the maximum 3H-TDR concentration occurred
`after 5 min, followed by a slower exponential decrease than that after the
`IP injection. Following either route of administration, the cumulative 3H-
`TDR amount was approximately the same.
`Autoradiographic grain counts were carried out on squash preparations
`from tongue and crypt epithelium. The yield of grain counts was about the
`same in the tongue epithelium following IP and IM injection and in crypt
`cells following IM injection. In the crypt cells after IP injection, however,
`the mean grain count was about twice that in the other 3 groups. It is sug-
`gested that this difference might be due to the uptake of 3H-TDR from the
`peritoneal cavity into the intestinal circulation resulting in a higher effective
`dose for the gut compared to the tongue epithelium.
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`Experimental Cell Research 45
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`M. R. Skougaard and P. A. Stewart
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`REFERENCES
`
`P‘FWP!‘
`
`.5’
`
`BRAY, G. A., Anal. Biochem. l, 279 (1960).
`BRESCIANI, F., Intern. Congr. Biochem. Abstr. Papers, p. 45 (1964).
`ELIAS, J., Stain Technol. 39, 235 (1964).
`FINK, K., CLINE, R. E., HENDERSON, R. B. and FINK, R. M., J. Biol. Chem. 221, 425 (1956).
`INNEs, J. R. M. and BORNER, G., Informal Report BNL 6744, Brookhaven Natl Laboratory,
`Upton, New York, 1962.
`NICHOLS, G., JR., NICHOLS, N., WEIL, W. B. and WALLACE, W. M., J. Clin.
`1299 (1953).
`7. PELC, S. R., in L. F. LAMERTON and R. J. M. FRY (eds.), Cell Proliferation, p. 94. Blackwell
`Sci. Publ., Oxford, 1963.
`8. POTTER, V. R., in F. STOHLMAN (ed.), The Kinetics of Cellular Proliferation, p. 104. Grune
`and Stratton, New York, 1959.
`9. QUASTLER, H., in M. HAISSINSKY (ed.), Chemical and Biological Effects of Radiation, p. 149.
`Masson et Cie, Paris, 1963.
`10. QUASTLER, H. and KEMBER, N. F., Unpublished manuscript (1963).
`11. QUASTLER, H. and SHERMAN, F. G., Exptl Cell Res. 17, 420 (1959).
`12. QUASTLER, H. and WIMBER, D. R., Unpublished manuscript (1963).
`13. RUBINI, J. R., CRONKITE, E., BOND, V. P. and FLIEDNER, T. M., J. Clin. Invest. 39, 909
`(1960).
`14. SKOUGAARD, M. R., Acta Odontol. Scand. 22, 693 (1964).
`15. STAROSCIK, R. N., JENKINS, W. H. and MENDELSOHN, M. L., Nature 202, 456 (1964).
`16. STEELE, R., WALL, J. 8., DE B000, R. C. and ALTSZULER, N., Am. J. Physiol. 187, 15 (1956).
`17. STEWART, P. A., QUASTLER, H., SKoUGAARD, M. R., WKMBER, D. R., WOLFSBERG, M. F.,
`PERROTTA, C. A., FERBEL, B. and CARLOUGH, M., Radiation Res. 24, 521 (1965).
`
`Invest. 32,
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