Digitoxin is a
cardiac glycoside used for the treatment of
heart failure and certain kinds of
heart arrhythmia. It is a
phytosteroid and is similar in
structure and effects to
digoxin, though the effects are longer-lasting. Unlike digoxin, which is eliminated from the body via the kidneys, it is eliminated via the liver, and so can be used in patients with poor or erratic kidney function. While several controlled trials have shown digoxin to be effective in a proportion of patients treated for heart failure, the evidence base for digitoxin is not as strong, although it is presumed to be similarly effective.[1]
Medical uses
Digitoxin is used for the treatment of heart failure, especially in people with impaired kidney function. It is also used to treat certain kinds of
heart arrhythmia, such as
atrial fibrillation.[2][3]
Digitoxin exhibits similar toxic effects to
digoxin, namely:
anorexia,
nausea, vomiting, diarrhea, confusion, visual disturbances, and cardiac
arrhythmias. Antidigoxin
antibody fragments, the specific treatment for digoxin poisoning, are also effective in serious digitoxin toxicity.[4]
Interactions
Drugs that can increase digitoxin toxicity include:[3]
Digitoxin inhibits the
sodium-potassium ATPase in heart muscle cells, resulting in increased force of contractions (positive
inotropic), reduced speed of electric conduction (negative
dromotropic), increased excitability (positive
bathmotropic), and reduced frequency of heartbeat (negative
chronotropic).[3]
Pharmacokinetics
The drug is almost completely absorbed from the gut. When in the bloodstream, 90 to 97% are bound to
plasma proteins. Digitoxin undergoes
enterohepatic circulation. It is
metabolized in part by CYP3A4; metabolites include
digitoxigenin,
digoxin (>2%), and
conjugate esters. In healthy people, 60% are eliminated via the kidneys and 40% via the faeces. In people with impaired kidney function, elimination via the faeces is increased. The
biological half-life is 7 to 8 days except when kidney and liver functions are impaired, in which case it is usually longer.[3][5]
History
The first description of the use of
foxglove dates back to 1775.[6] For quite some time, the active compound was not isolated.
Oswald Schmiedeberg was able to obtain a pure sample in 1875. The modern therapeutic use of this molecule was made possible by the works of the pharmacist and the French chemist
Claude-Adolphe Nativelle (1812–1889). The first structural analysis was done by
Adolf Otto Reinhold Windaus in 1925, but the full structure with an exact determination of the sugar groups was not accomplished until 1962.[7][8]
Digitoxin and related cardenolides display anticancer activity against a range of human
cancer cell lines in vitro but the clinical use of digitoxin to treat
cancer has been restricted by its narrow
therapeutic index.[9][10] Digitoxin
glycorandomization led to the discovery of novel
digitoxigenin neoglycosides which displayed improved anticancer potency and reduced inotropic activity (the perceived mechanism of general toxicity).[11]
^Kurowski V, Iven H, Djonlagic H (1992). "Treatment of a patient with severe digitoxin intoxication by Fab fragments of anti-digitalis antibodies". Intensive Care Medicine. 18 (7): 439–42.
doi:
10.1007/BF01694351.
PMID1469187.
S2CID2324996.
Johansson S, Lindholm P, Gullbo J, Larsson R, Bohlin L, Claeson P (June 2001). "Cytotoxicity of digitoxin and related cardiac glycosides in human tumor cells". Anti-Cancer Drugs. 12 (5): 475–83.
doi:
10.1097/00001813-200106000-00009.
PMID11395576.
S2CID19894541.
Hippius M, Humaid B, Sicker T, Hoffmann A, Göttler M, Hasford J (August 2001). "Adverse drug reaction monitoring--digitoxin overdosage in the elderly". International Journal of Clinical Pharmacology and Therapeutics. 39 (8): 336–43.
doi:
10.5414/cpp39336.
PMID11515708.
Comparing the Toxicity of Digoxin and Digitoxin in a Geriatric Population: Should an Old Drug Be Rediscovered? on
Medscape(
registration required), a convenience link from the
original. (subscription required)