Chronopharmacological Study of Interferon-alpha  in Mice

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Vol. 283, Issue 1, 259-264, 1997

Chronopharmacological Study of Interferon- $alpha$ in Mice

Satoru Koyanagi, Shigehiro Ohdo, Eiji Yukawa and Shun Higuchi

Department of Clinical Pharmacokinetics, Division of Pharmaceutical Science, Kyushu University, Fukuoka, Japan

	Abstract

Top Abstract Introduction Methods Results Discussion References

The influence of dosing time on the pharmacological effects (fever and antiviral activity) and the pharmacokinetics of interferon- $alpha$ (IFN- $alpha$ ) was investigated in ICR male mice under light-dark (12:12)cycle. There was a significant circadian rhythm in rectal temperature,as an index of fever, at 0.5 hr after IFN- $alpha$ (10.0 MIU/kg i.v.)injection. The rhythmic pattern resembled overall the rhythm thatoccurs in the nondrugged state. However, the percent change frombasal level of rectal temperature varied according to the dosingtime. The rhythmicity corresponded to the dosing time-dependentdifference of PGE₂ levels in thalamus after IFN- $alpha$ injection, butit did not correspond to that of plasma IFN- $alpha$ concentrations.A significant dosing time-dependent difference was also demonstratedfor 2 $'$ -5 $'$ oligoadenylate synthetase activities, as an index ofantiviral activity, in plasma and liver at 24 hr after IFN- $alpha$ injection.It was related to the rhythmicity in plasma IFN- $alpha$ concentrationsthat was caused by the rhythmicity in clearance of IFN- $alpha$ . Thechoice of the most appropriate time of day for drug administrationmay help to achieve rational chronotherapeutics of IFN- $alpha$ in certainexperimental and clinical situations.

	Introduction

Top Abstract Introduction Methods Results Discussion References

A large number of physiological rhythmic variables are demonstrated in the CNS, in hormone secretion and so on (Kafka et al.,1981; Naber et al., 1981; Thomson et al., 1980). Also, many drugsvary in potency and/or toxicity according to the time in the circadiancycle when they are administered (Ohdo et al., 1988, 1990, 1995a,1995b, 1996; Frederickson et al., 1977; Walker and Owasoyo, 1974).

Interferons, which belong to a group of cytokines, have been widely used as antiviral and antitumor agents in the human. However,interferons cause unavoidable adverse effects such as fever, fatigue,headache, rigors and myalgias. In particular, fever is an indispensableside effect in nearly all patients during the early phase of interferontreatment. Administration of IFN- $alpha$ in cancer patients is bettertolerated in evening than in morning (Abrams et al., 1985). Thereare also significant dosing time-dependent differences in theantitumor and myelosuppressive activity of IFN- $alpha$ in mice (Korenet al., 1993; Koren and Fleischmann, 1993). However, the rhythmicchanges of interferon-induced fever and antiviral activity havenot yet been examined.

Rectal temperature and immune functions show significant circadian rhythms in mammals under both nondrugged and drugged conditions(Ohdo et al., 1995a; Refinetti et al., 1990; Haus et al., 1983;Batalla et al., 1994). Therefore, there may be a chronobiologiceffect on the fever and antiviral activity induced by IFN- $alpha$ . Theincrease in body temperature induced by interferons may be oneaspect of its antiviral activity as an immunoadjuvant effect,but an excessive febrile reaction may be more detrimental thanbeneficial.

The purpose of this study was to examine the diurnal change of IFN- $alpha$ induced fever and antiviral activity in mice. The mechanismsunderlying these phenomena were also investigated from the perspectiveof IFN- $alpha$ pharmacokinetics.

	Methods

Top Abstract Introduction Methods Results Discussion References

Animals and treatments. Male ICR mice (5 weeks old) were purchased from Charles River Japan Inc. (Kanagawa, Japan). Mice were housed 6 or 10 per cagein a light-controlled room (light on from 07:00 to 19:00) at aroom temperature of 24°C ± 1°C and a humidity of 60% ± 10% withfood and water ad libitum. All mice were adapted to their light-darkcycle for 2 weeks before the experiments. In order to study thefever induced by IFN- $alpha$ (Sumiferon, Sumitomo Seiyaku Co., Osaka,Japan), groups of six mice injected i.v. with 1.0, 5.0 or 10.0MIU/kg IFN- $alpha$ or sterilized saline at the same circadian phase(09:00). IFN- $alpha$ was diluted by sterilized saline to adjust theconcentration to 0.2, 1.0 and 2.0 MIU/ml. The volume of injectionwas 0.05 ml/10.0 g b.wt. The drug solutions were used within 30min after preparation in order not to decrease their biologicactivity. Rectal temperature was continuously determined before,and at 0.5, 1.0, 2.0 and 4.0 hr after, IFN- $alpha$ or saline injection.In the study of the circadian rhythms of IFN- $alpha$ -induced fever andplasma IFN- $alpha$ concentrations, groups of 8 to 10 mice were injectedi.v. with 10.0 MIU/kg IFN- $alpha$ or saline at one of six times: 09:00,13:00, 17:00, 21:00, 01:00 or 05:00. Rectal temperature was determinedbefore, and at 0.5, 1.0, 1.5 and 2.0 hr after, IFN- $alpha$ or salineinjection. Percent change of rectal temperature (%) from basallevel was calculated as follows: % = ([rectal temperature afterIFN- $alpha$ injection $-$ rectal IFN- $alpha$ before IFN- $alpha$ injection] / [rectaltemperature before IFN- $alpha$ injection]) × 100. Blood samples weredrawn by cardiac puncture at 2.5 hr after IFN- $alpha$ injection andplaced into polypropylene tubes containing 10 µl of EDTA (4%)solution. To observe the PGE₂ production induced by IFN- $alpha$ , groupsof six mice were injected i.v. with 10.0 MIU/kg IFN- $alpha$ on one oftwo occasions: in the latter half of the light phase (17:00) orin the latter half of the dark phase (05:00). Blood samples weredrawn by cardiac puncture at 0.5 hr after IFN- $alpha$ injection andplaced into polypropylene tubes containing 10 µl of indomethacin(40 mM) / EDTA (4%) solution. Immediately after blood sample collection,thalamus was removed and placed into ice-cold tubes. To examine2 $'$ -5 $'$ OAS activities induced by IFN- $alpha$ , groups of 8 to 10 mice wereinjected i.v. with 10.0 MIU/kg IFN- $alpha$ on one of two occasions asdescribed above. Blood samples were collected by cardiac punctureat 24 hr after IFN- $alpha$ injection and placed into polypropylene tubescontaining 10 µl of EDTA (4%) solution. Immediately after bloodcollection, liver was perfused with 0.01 M PBS. The liver wasquickly removed, rinsed with saline and placed into ice-cold tubes.To study the time course of plasma IFN- $alpha$ concentrations, groupsof six mice were injected i.v. with 10.0 MIU/kg IFN- $alpha$ on one oftwo occasions as described above. Blood samples were drawn byorbital sinus collection at 0.167, 0.5, 1.0, 2.0, 3.0 and 4.0hr after IFN- $alpha$ injection.

Determination of IFN- $alpha$ induced fever. IFN- $alpha$ induced fever was determined by measuring the rectal temperature after IFN- $alpha$ or saline injection. Rectal temperaturewas measured on a digital thermometer (digital thermometer TD-300,Shibaura Electronics, Tokyo, Japan). A lubricated thermocouplewas inserted 1.5 cm into the rectum of mice. Rectal temperaturewas measured at least every 30 min to avoid hyperthermia occasionedby continuous handling stress (Briese et al., 1991).

Determination of PGE₂ concentration in plasma and thalamus. Plasma samples were obtained after centrifugation at 3000 rpm for 3 min. The plasma samples (300 µl) were added to ethanolsolution to give a final concentration of 10% ethanol. The ice-coldthalamus was weighed and homogenized with the cold absolute ethanol(200 µl), distilled water being added to give final concentrationof 10% ethanol. The supernatant, after centrifugation at 1500× g × for 20 min, was used as the thalamus homogenate sample.PGE₂ was extracted from plasma and thalamus samples accordingto the method of Powell (Powell, 1982) and Shono (Shono et al.,1988). The plasma and thalamus homogenate samples were acidifiedto pH 3.0 by acetic acid and applied to a SEP-PAK C₁₈ column (Waters,Massachusetts). The solvent of crude extract was evaporated anddissolved in the HPLC mobile-phase buffer (methanol / H₂O/aceticacid, 60 / 40 / 0.01, v/v/v). Further purification was performedby HPLC using ODS-80Ts column (4.6 mm I.D. × 150 mm) connectedto a pump (655A-11 Liquid Chromatograph, Hitachi, Tokyo, Japan).The flow rate was 0.8 ml/min. The PGE₂ fractions for assay werecollected from 21 to 26 min. The solvent was evaporated, and theresidue was dissolved in assay buffer (0.1% bovine serum albumin/0.1M phosphate-buffered saline pH 7.4). PGE₂ concentrations weredetermined by enzyme immunoassay (PGE₂ immunoassay system, Amersham,Bukinghamshire, U.K.).

Determination of 2 $'$ -5 $'$ OAS activities in plasma and liver. Plasma samples were obtained after centrifugation at 3000 rpm for 3 min and then stored at $-$ 20°C until assayed. The ice-coldliver was immediately homogenized with modified lysis buffer (10mM HEPES-KOH/50 mM KCl/3 mM Mg(OAc)₂/0.3 mM EDTA/10% glycerol/0.01%NaN₃/0.5% Triton-100/100 µM PMSF/7 mM 2-mercaptoethanol, pH 7.5)(Sokawa et al., 1994). The supernatants, after centrifugationat 9000 × g for 20 min at 4°C, were used as the liver sample.The protein concentrations in the liver homogenate sample weredetermined by Lowry's method. The plasma and liver 2 $'$ -5 $'$ OAS activitieswere determined by radioimmunoassay (2-5A kit, Eiken, Tokyo, Japan).The 2 $'$ -5 $'$ OAS activities in liver were expressed as 2 $'$ -5 $'$ oligoadenylatefmol per liver protein concentration.

Determination of IFN- $alpha$ concentration in plasma. Plasma samples were obtained after centrifugation at 3000 rpm for 3 min and stored at $-$ 20°C until assayed. Plasma IFN- $alpha$ concentrationswere determined by enzyme-linked immunosorbent assay (ELISA) (IFN- $alpha$ immunoassay kit, BioSource International Inc, California). Thetiter was expressed in international units (IU) per milliliter,and the detection limit in the sample was 10 IU/ml. There wasno cross-reactivity with endogenous mouse interferons.

Statistical analysis. Pharmacokinetic parameters were calculated by the nonlinear least-squares method, following the two-compartment model: CL,V_c, K₁₂ and K₂₁. Analysis of variance (ANOVA) and Tukey's testwere applied for the multiple comparison. Student's t test wasused for independent comparison between groups. The 5% level ofprobability was considered to be significant.

	Results

Top Abstract Introduction Methods Results Discussion References

Influence of IFN- $alpha$ on body temperature. The effects of three dosages (1.0, 5.0 and 10.0 MIU/kg) of IFN- $alpha$ on rectal temperature in mice injected with the drug at thesame circadian phase (09:00) are shown in figure 1. The rectaltemperature increased from basal level at all dosages of IFN- $alpha$ .The rectal temperature at 0.5 hr after IFN- $alpha$ 10.0 MIU/kg injectionwas significantly different from that after saline injection (P< .01). However, the rectal temperature of mice injected withIFN- $alpha$ 1.0 or 5.0 MIU/kg was not significantly different from thatof mice injected with saline.

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Fig. 1. The time course of rectal temperature after IFN- $alpha$ injection. Each point represents the mean ± S.E. of six mice. ** P < .01when compared with the saline group using Tukey's test. $open circle$ , saline; $bullet$ , IFN- $alpha$ 10.0 MIU/kg; $black-square$ , 5.0 MIU/kg; $black-triangle$ , 1.0 MIU/kg.

Circadian rhythm of IFN- $alpha$ induced fever. The rectal temperature in mice injected with saline showed significant circadian rhythm with a lower level during the lightphase and a higher level during the dark phase (P < .01; fig.2). The rectal temperature after IFN- $alpha$ 10.0 MIU/kg injection wassignificantly higher during the 24-hr cycle when compared withthat after saline injection (P < .01). The rhythmic pattern ofIFN- $alpha$ -induced fever resembled overall the rhythm that occurredafter saline injection. However, fever was not induced by IFN- $alpha$ injection in the latter half of the dark phase (05:00). The timecourse of rectal temperature was expressed as percent change frombasal level, the level before IFN- $alpha$ injection (fig. 3). The percentchanges in rectal temperature at 0.5 hr after IFN- $alpha$ injectionwere significantly higher in the light phase than in the darkphase (P < .01). However, the rectal temperature after IFN- $alpha$ injectionin the latter half of dark phase (05:00) showed no significantdifference from that after saline injection.

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Fig. 2. Circadian rhythm of rectal temperature at 0.5 hr after IFN- $alpha$ (10.0 MIU/kg i.v.) injection ( $bullet$ ) or saline injection ( $open circle$ ). Eachpoint represents the mean ± S.E. of 8 to 10 mice. ** P < .01 whencompared with the corresponding saline group using Tukey's test.

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Fig. 3. The time course of percent change of rectal temperature after IFN- $alpha$ (10.0 MIU/kg i.v.) injection at 09:00 ( $open circle$ ), 13:00 ( $square$ ),17:00 ( $triangle$ ), 21:00 ( $bullet$ ), 01:00 ( $black-square$ ) and 05:00 ( $black-triangle$ ). Value of rectaltemperature is expressed as percent change from basal level. Eachpoint represents the mean ± S.E. of 8 to 10 mice.

Influence of dosing time on PGE₂ levels in plasma and thalamus. The effect of dosing time of IFN- $alpha$ on PGE₂ production in plasma and thalamus is shown in figure 4. There was no significantdifference in PGE₂ levels in plasma and thalamus between miceinjected with saline at 17:00 and 05:00. The PGE₂ levels in plasmaafter IFN- $alpha$ injection at 17:00 tended to be higher than thoseafter saline injection at 17:00 (P < .10). The PGE₂ levels inthalamus at 0.5 hr after IFN- $alpha$ injection were significantly higherin mice injected with the drug at 17:00 than in those injectedat 05:00 (P < .01). The PGE₂ levels in thalamus after IFN- $alpha$ injectionat 17:00 also increased significantly when compared with thoseafter saline injection at 17:00 (P < .01).

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Fig. 4. Influence of dosing time on the plasma and thalamus PGE₂ levels after IFN- $alpha$ (10.0 MIU/kg i.v.) injection at 17:00 or 05:00.Each column represents the mean ± S.E. of six mice. ** P < .01when compared with the saline group or between the two dosingtimes using Tukey's test. $square$ : saline;

: IFN- $alpha$ .

Influence of dosing time on 2 $'$ -5 $'$ OAS activity in plasma and liver. The effect of time dosing with IFN- $alpha$ on 2 $'$ -5 $'$ OAS activity in plasma and liver is shown in figure 5. 2 $'$ -5 $'$ OAS activities inplasma and liver showed no significant difference between miceinjected with saline at 17:00 and 05:00. 2 $'$ -5 $'$ OAS activity inplasma at 24 hr after IFN- $alpha$ injection was significantly higherfor injection at 05:00 than for injection at 17:00 (P < .05),but 2 $'$ -5 $'$ OAS activity in liver at 24 hr after IFN- $alpha$ injectionshowed no dosing time-dependent difference. 2 $'$ -5 $'$ OAS activitiesin plasma and liver after IFN- $alpha$ injection at 05:00 increased significantlywhen compared with those after saline injection (P < .01, P <.05 respectively).

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Fig. 5. Influence of dosing time on the plasma and liver 2 $'$ -5 $'$ OAS activities after IFN- $alpha$ (10.0 MIU/kg i.v.) injection at 17:00 or05:00. Each column represents the mean ± S.E. of 8 to 10 mice.* P < .05; ** P < .01 when compared with the saline group or betweenthe two dosing times using Tukey's test. $square$ : saline;

: IFN- $alpha$ .

Circadian rhythm of IFN- $alpha$ concentrations in plasma. The plasma IFN- $alpha$ concentrations at 2.5 hr after IFN- $alpha$ injection showed a significant circadian rhythm with higher levels fromlate dark phase to early light phase and lower levels from latelight phase to early dark phase (P < .01; fig. 6). The time courseof plasma IFN- $alpha$ concentrations after IFN- $alpha$ injection decayed biphasically(fig. 7). IFN- $alpha$ concentrations at 2.0, 3.0 and 4.0 hr after IFN- $alpha$ injection were significantly higher for injection at 05:00 thanfor injection at 17:00 (P < .05). CL was significantly higherin mice injected with IFN- $alpha$ at 17:00 than in those injected at05:00 (P < .05, table 1). There was no significant differencein any other pharmacokinetic parameters between mice injectedwith the drug at 17:00 and those injected at 05:00.

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Fig. 6. Circadian rhythm of plasma IFN- $alpha$ concentrations at 2.5 hr after IFN- $alpha$ (10.0 MIU/kg i.v.) injection. Each point representsthe mean ± S.E. of 8 to 10 mice.

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Fig. 7. The time course of plasma IFN- $alpha$ concentrations after IFN- $alpha$ (10.0 MIU/kg i.v.) injection at 17:00 ( $open circle$ ) or 05:00 ( $bullet$ ). Each pointrepresents the mean ± S.E. of six mice. * P < .05 when comparedbetween the two groups using Tukey's test.

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TABLE 1
Influence of dosing time of IFN- $alpha$ (10.0 MIU/kg i.v.) injection on pharmacokinetic parameters

	Discussion

Top Abstract Introduction Methods Results Discussion References

Rectal temperature in mice showed a significant circadian rhythm with higher levels during the dark phase and lower levelsduring the light phase under nondrugged conditions. Our resultconfirms previous observations (Ohdo et al., 1995a). Normal bodytemperature is regulated by the relative balance of catecholamineand serotonin levels in the anterior hypothalamus (Feldberg andMyers., 1964). The changes in locomotor activities, eating, drinkingand secretion of several hormones influence the rhythm of rectaltemperature (Refinetti and Menaker, 1992). The rectal temperatureat 0.5 hr after IFN- $alpha$ injection increased significantly duringthe 24-hr cycle, except for the latter half of the dark phase(05:00), when compared with that after saline injection. The rhythmicpattern of IFN- $alpha$ -induced fever resembled overall the rhythm occurringafter saline injection, but the percent changes from basal levelof rectal temperature after IFN- $alpha$ injection varied according tothe dosing time. IFN- $alpha$ acts on the thermosensitive neurons inthe preoptic and anterior hypothalamus and increases body temperaturevia PGE₂ production and/or opioid receptor (Nakashima et al.,1988, 1995; Dinarello et al., 1984). Certainly, cyclooxygenaseinhibitors, by decreasing PGE₂ production, suppress IFN- $alpha$ inducedfever. PGE₂ levels in the thalamus at 0.5 hr after IFN- $alpha$ injectionwere significantly higher in mice injected with the drug at 17:00than in those injected at 05:00. This seems to coincide with thecircadian rhythm of IFN- $alpha$ -induced fever. Although plasma IFN- $alpha$ concentrations showed significant circadian rhythm, it was outof phase with the rhythm of IFN- $alpha$ -induced fever. Thus the rhythmicityof IFN- $alpha$ -induced fever seems to be due to that of the sensitivityof mice to the drug.

The important question still remains whether the antiviral activity of IFN- $alpha$ declines at the dosing time that alleviates IFN- $alpha$ -inducedfever. The antiviral activity of interferon due, at least in part,to the 2 $'$ -5 $'$ oligoadenylate synthetase system (Baglioni, 1979).2 $'$ -5 $'$ OAS is the enzyme directly related to the antiviral actionof interferon. Serum 2 $'$ -5 $'$ OAS activity is used as an index ofthe antiviral effect of interferon in patients with hepatitis.There was no significant dosing time-dependent difference in 2 $'$ -5 $'$ OASactivity between saline injection at 17:00 and that at 05:00.However, both plasma and liver 2 $'$ -5 $'$ OAS activities induced byIFN- $alpha$ were higher in mice injected with drug at 05:00 than inthose injected at 17:00. The rhythm corresponded well to the rhythmicityof IFN- $alpha$ concentration. Therefore, the diurnal difference of 2 $'$ -5 $'$ OASactivity induced by IFN- $alpha$ can be explained, at least in part,by the rhythm of plasma IFN- $alpha$ concentration. The circadian rhythmof antitumor activity induced by IFN- $alpha$ exhibits higher activityin the early light phase (Koren et al., 1993). In the circadianphase, plasma IFN- $alpha$ concentration was higher in the present study.The rhythm of IFN- $alpha$ -induced antitumor activity also seems to bedue to that of IFN- $alpha$ pharmacokinetics.

Plasma IFN- $alpha$ concentrations at 2.5 hr after IFN- $alpha$ injection showed a significant circadian rhythm. A significant dosing time-dependentdifference was also demonstrated for the pharmacokinetic parameterof IFN- $alpha$ , which showed higher CL for injection at 17:00 than forinjection at 05:00. The rhythmicity in CL seems to be closelyrelated to that in plasma IFN- $alpha$ concentration. IFN- $alpha$ concentrationsin plasma have been shown to decay biphasically after an i.v.injection of IFN- $alpha$ , and the distribution phase lasted for 1.0hr after the drug injection (Cantell and Pyhärä, 1973). IFN- $alpha$ is quickly eliminated from the body by several pathways. The mainroute of excretion of IFN- $alpha$ is the kidneys (Bino et al., 1982).Renal tubular cells take up and break down many plasma proteins(Strober and Waldmann, 1974). IFN- $alpha$ is also internalized and catabolizedintracellularly in kidney via receptor-mediated endocytosis (Bocciet al., 1983). Both renal elimination rate and liver metabolismrate increase during the active period in mice (Ohdo et al., 1995a).The rhythmicity can reflect not only the rhythmic activity ofthe enzyme in kidney and liver but also the rhythmic rate of bloodflow (Labrecque et al., 1988). The rhythmicity of CL in our studycorresponds well to that of blood flow. Thus the circadian rhythmin IFN- $alpha$ pharmacokinetics may be caused by the diurnal rhythmof renal function. Although the circadian rhythm of receptor-mediatedendocytosis has not been investigated yet, this should be clarifiedin future.

The present findings in this mouse model support the concept that the choice of the most appropriate time of day for administrationof interferons may reduce their side effects and increase theirantiviral activity in clinical situations.

	Acknowledgments

This research was supported by a Grant-in-Aid for Scientific Research (C) from the Ministry of Education, Science, Sportsand Culture, Japan (S.O., 00223884). Sumitomo Seiyaku Co. (Osaka,Japan) generously supplied IFN- $alpha$ (Sumiferon). We are gratefulto them.

	Footnotes

Accepted for publication June 12, 1997.

Received for publication December 27, 1996.

Send reprint requests to: Shigehiro Ohdo, Ph.D., Department of Clinical Pharmacokinetics, Division of Pharmaceutical Science, Kyushu University, 3-1-1, Maidashi, Higashi-ku, Fukuoka, 812 Japan.

	Abbreviations

IFN- $alpha$ , interferon- $alpha$ ; 2 $'$ -5 $'$ OAS, 2 $'$ -5 $'$ oligoadenylate synthetase; CL, clearance; V_c, central volume of distribution; K₁₂, distribution rate constant from central to peripheral compartment; K₂₁, distribution rate constant from peripheral to central compartment.

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				S. Koyanagi, Y. Kuramoto, H. Nakagawa, H. Aramaki, S. Ohdo, S. Soeda, and H. Shimeno A Molecular Mechanism Regulating Circadian Expression of Vascular Endothelial Growth Factor in Tumor Cells Cancer Res., November 1, 2003; 63(21): 7277 - 7283. [Abstract] [Full Text] [PDF]

				S. Koyanagi, H. Nakagawa, Y. Kuramoto, S. Ohdo, S. Soeda, and H. Shimeno Optimizing the Dosing Schedule of TNP-470 [O-(Chloroacetyl-carbamoyl) Fumagillol] Enhances Its Antitumor and Antiangiogenic Efficacies J. Pharmacol. Exp. Ther., February 1, 2003; 304(2): 669 - 674. [Abstract] [Full Text] [PDF]

				X. Pan, T. Terada, M. Irie, H. Saito, and K.-I. Inui Diurnal rhythm of H+-peptide cotransporter in rat small intestine Am J Physiol Gastrointest Liver Physiol, July 1, 2002; 283(1): G57 - G64. [Abstract] [Full Text] [PDF]

				J. Viyoch, S. Ohdo, E. Yukawa, and S. Higuchi Dosing Time-Dependent Tolerance of Catalepsy by Repetitive Administration of Haloperidol in Mice J. Pharmacol. Exp. Ther., September 1, 2001; 298(3): 964 - 969. [Abstract] [Full Text]

				D.-s. Wang, S. Ohdo, S. Koyanagi, H. Takane, H. Aramaki, E. Yukawa, and S. Higuchi Effect of Dosing Schedule on Pharmacokinetics of Alpha Interferon and Anti-Alpha Interferon Neutralizing Antibody in Mice Antimicrob. Agents Chemother., January 1, 2001; 45(1): 176 - 180. [Abstract] [Full Text]

				S. Ohdo, D.-S. Wang, S. Koyanagi, H. Takane, K. Inoue, H. Aramaki, E. Yukawa, and S. Higuchi Basis for Dosing Time-Dependent Changes in the Antiviral Activity of Interferon-alpha in Mice J. Pharmacol. Exp. Ther., August 1, 2000; 294(2): 488 - 493. [Abstract] [Full Text]

				H. Takane, S. Ohdo, T. Yamada, E. Yukawa, and S. Higuchi Chronopharmacology of Antitumor Effect Induced by Interferon-beta in Tumor-Bearing Mice J. Pharmacol. Exp. Ther., August 1, 2000; 294(2): 746 - 752. [Abstract] [Full Text]

Chronopharmacological Study of Interferon- in Mice

Chronopharmacological Study of Interferon- $alpha$ in Mice