Characterization of the Myelotoxicity of Chloramphenicol Succinate in the B6C3F1 Mouse

Overview

Journal Int J Exp Pathol

Publisher Wiley

Specialty Pathology

Date 2006 Apr 21

PMID 16623754

Citations 6

Authors

John A Turton

Rajni Fagg

William R Sones

Thomas C Williams

C Michael Andrews

Affiliations

Soon will be listed here.

Abstract

Chloramphenicol (CAP) is haemotoxic in man, inducing two types of toxicity. First, a dose-related, reversible anaemia with reticulocytopenia, sometimes seen in conjunction with leucopenia and thrombocytopenia; this form of toxicity develops during drug treatment. The second haemotoxicity is aplastic anaemia (AA) which is evident in the blood as severe pancytopenia. AA development is not dose-related and occurs weeks or months after treatment. We wish, in the longer term, to investigate CAP-induced AA in the busulphan-pretreated mouse. However, as a prelude to that study, we wanted to characterize in detail the reversible haemotoxicity of CAP succinate (CAPS), administered at high dose levels in the mouse, and follow the recovery of the bone marrow in the post-dosing period. Female B6C3F1 mice were gavaged with CAPS at 0, 2500 and 3500 mg/kg, daily, for 5 days and sampled (n = 5) at 1, 7, 14 and 21 days post-dosing. Blood, bone marrow and spleen samples were analysed and clonogenic assays carried out. At day 1 post-dosing, at both CAPS dose levels, decreases were seen in erythrocytes and erythrocyte precursors; marrow erythroid cells were reduced. Reductions were also evident in splenic nucleated cell counts, blood high fluorescence ratio (HFR) reticulocyte counts and total reticulocyte counts; burst-forming units-erythroid and colony-forming units-erythroid showed decreases. At day 7 post-dosing (2500 mg/kg CAPS), there was regeneration of erythrocyte production, with marked splenic erythropoietic activity, and raised blood HFR reticulocytes. At day 7, at 3500 mg/kg CAPS, erythrocyte and reticulocyte parameters remained depressed. At 14 days post-dosing (2500 mg/kg CAPS), many erythrocyte parameters had returned to normal; at 3500 mg/kg CAPS, there was erythroid regeneration. By 21 days post-dosing, at both CAPS dose levels, most erythrocytic parameters were equivalent to control values. For leucocyte parameters, there was some depression at day 1 post-dosing (at both CAPS dose levels) and signs of recovery at day 7. At days 14 and 21 post-dosing, most leucocyte parameters were close to control values. Marrow smears at day 1 post-dosing (at both CAPS dose levels) showed vacuolation of early normoblasts, of myeloid and of monocytic precursors. We conclude that the administration of CAPS at 2500 and 3500 mg/kg for 5 days induced significant myelotoxicity in female B6C3F1 mice, with cessation of erythropoiesis at day 1 post-dosing; recovery was seen over the following 7/14 days. The blood HFR reticulocyte count was a precise indicator of CAPS-induced depressive effects and subsequent recovery. It is concluded that the administration of five daily doses of CAPS at 2500 and 3500 mg/kg to the female B6C3F1 mouse induces an anaemia with reticulocytopenia, in conjunction with leucopenia, in the immediate post-dosing period; no evidence was seen at 21 days post-dosing of peripheral blood pancytopenia or a hypocellular/acellular bone marrow, which are both characteristic features of AA in man.

Citing Articles

Potential protection by vitamin D against DNA fragmentation and bone marrow cytotoxicity induced by chloramphenicol.

El-Alfy N, Emam A, Mahmoud M, Morgan O, El-Ashry S Toxicol Rep. 2024; 13:101828.

PMID: 39654996 PMC: 11626822. DOI: 10.1016/j.toxrep.2024.101828.

Occurrence, toxicity and adsorptive removal of the chloramphenicol antibiotic in water: a review.

Nguyen L, Nguyen N, Nguyen T, Nguyen T, Nguyen D, Tran T Environ Chem Lett. 2022; 20(3):1929-1963.

PMID: 35369683 PMC: 8956153. DOI: 10.1007/s10311-022-01416-x.

Mitochondria as a therapeutic target for cardiac ischemia‑reperfusion injury (Review).

Marin W, Marin D, Ao X, Liu Y Int J Mol Med. 2021; 47(2):485-499.

PMID: 33416090 PMC: 7797474. DOI: 10.3892/ijmm.2020.4823.

Chloramphenicol Derivatives as Antibacterial and Anticancer Agents: Historic Problems and Current Solutions.

Dinos G, Athanassopoulos C, Missiri D, Giannopoulou P, Vlachogiannis I, Papadopoulos G Antibiotics (Basel). 2016; 5(2).

PMID: 27271676 PMC: 4929435. DOI: 10.3390/antibiotics5020020.

Adverse effects of antimicrobials via predictable or idiosyncratic inhibition of host mitochondrial components.

Barnhill A, Brewer M, Carlson S Antimicrob Agents Chemother. 2012; 56(8):4046-51.

PMID: 22615289 PMC: 3421593. DOI: 10.1128/AAC.00678-12.

References

Morley A, Blake J . An animal model of chronic aplastic marrow failure. I. Late marrow failure after busulfan. Blood. 1974; 44(1):49-56. View

Vincent P . In vitro evidence of drug action in aplastic anemia. Blut. 1984; 49(1):3-12. DOI: 10.1007/BF00320378. View

Miura A, Yoshida K, Yamaguchi A, Fukuda M . The effect of chloramphenicol and thiamphenicol on the ultrastructure of the erythroblasts in mouse splenic colonies. Tohoku J Exp Med. 1980; 130(4):335-40. DOI: 10.1620/tjem.130.335. View

Scott J, Finegold S, BELKIN G, Lawrence J . A CONTROLLED DOUBLE-BLIND STUDY OF THE HEMATOLOGIC TOXICITY OF CHLORAMPHENICOL. N Engl J Med. 1965; 272:1137-42. DOI: 10.1056/NEJM196506032722201. View

Rich M, RITTERHOFF R, Hoffmann R . A fatal case of aplastic anemia following chloramphenicol (chloromycetin) therapy. Ann Intern Med. 1950; 33(6):1459-67. DOI: 10.7326/0003-4819-33-6-1459. View

Klassen L, Birks J, Allen E, GURNEY C . Experimental medullary aplasia. J Lab Clin Med. 1972; 80(1):8-17. View

KRAKOFF I, KARNOFSKY D, Burchenal J . Effects of large doses of chloramphenicol on human subjects. N Engl J Med. 1955; 253(1):7-10. DOI: 10.1056/NEJM195507072530102. View

JIJI R, Gangarosa E, DE LA MACORRA F . Chlorampehnicol and its sulfamoyl analogue. Report of reversible erythropoietic toxicity in healthy volunteers. Arch Intern Med. 1963; 111:70-82. DOI: 10.1001/archinte.1963.03620250074011. View

SCHOBER R, KOSEK J, Wolf P . Chloramphenicol-induced vacuoles. Their ultrastructure in bone marrow pronormoblasts and immature myeloid cells. Arch Pathol. 1972; 94(4):298-302. View

10.

RIGDON R, CRASS G, Martin N . Anemia produced by chloramphenicol (chloromycetin) in the duck. AMA Arch Pathol. 1954; 58(1):85-93. View

11.

Saidi P, Wallerstein R, AGGELER P . Effect of chloramphenicol on erythropoiesis. J Lab Clin Med. 1961; 57:247-56. View

12.

YUNIS A, Bloomberg G . CHLORAMPHENICOL TOXICITY: CLINICAL FEATURES AND PATHOGENESIS. Prog Hematol. 1964; 4:138-59. View

13.

Bostrom B, Smith K, Ramsay N . Stimulation of human committed bone marrow stem cells (CFU-GM) by chloramphenicol. Exp Hematol. 1986; 14(2):156-61. View

14.

Kumar P, Verma I . Antibiotic therapy for bacterial meningitis in children in developing countries. Bull World Health Organ. 1993; 71(2):183-8. PMC: 2393459. View

15.

Holt D, Harvey D, Hurley R . Chloramphenicol toxicity. Adverse Drug React Toxicol Rev. 1993; 12(2):83-95. View

16.

Fraunfelder F, Morgan R, YUNIS A . Blood dyscrasias and topical ophthalmic chloramphenicol. Am J Ophthalmol. 1993; 115(6):812-3. DOI: 10.1016/s0002-9394(14)73653-0. View

17.

de Haan G, Loeffler M, Nijhof W . Long-term recombinant human granulocyte colony-stimulating factor (rhG-CSF) treatment severely depresses murine marrow erythropoiesis without causing an anemia. Exp Hematol. 1992; 20(5):600-4. View

18.

Anagnostou A, Zander A, Barone J, Fried W . Mechanism of the increased splenic erythropoiesis in mice treated with estradiol benzoate. J Lab Clin Med. 1976; 88(5):700-6. View

19.

Welch H, LEWIS C, KERLAN I . Blood dyscrasias; a nationwide survey. Antibiot Chemother (Northfield). 2014; 4(6):607-23. View

20.

Trevett A, Naraqi S, Wembri J . Typhoid fever complicated by chloramphenicol toxicity, ataxia and psychosis. P N G Med J. 1992; 35(3):205-9. View