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Year : 2012  |  Volume : 3  |  Issue : 4  |  Page : 304-307  

The incidence and clinical relevance of drug interactions in pediatrics

Institute of Pharmacology and Toxicology, Faculty of Medicine, University of Prishtina, Prishtina, Kosovo, Yugoslavia

Date of Web Publication24-Nov-2012

Correspondence Address:
Hasime Qorraj-Bytyqi
L. e Universitetit, Nr 32, 10000 Prishtina, Kosovo, Yugoslavia

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Source of Support: None, Conflict of Interest: None

DOI: 10.4103/0976-500X.103686

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Objective: To investigate the prevalence of the major drug interactions in children and verify the rate and profile of drug interactions in hospitalized pediatric patients. Materials and Methods: A retrospective study was designed and data collected from the files of hospitalized children in Pulmonology, Nephrology, and Gastroenterology wards of a Pediatric Clinic, from July 1999 to 2004. Results: From the analyzed material, we detected 34 cases of interactions, of which 1 was pharmacodynamics interaction, 13 were pharmacokinetic interactions, and 20 of unknown mechanisms. According to the rate of significance, 4 cases were categorized in the first significance rate of interaction, 18 cases in the second significance rate, 1 case of the third significance rate, 4 cases of the fourth significance rate, and 7 cases of the fifth significance rate. According to onset of cases, 33 cases were of delayed onset, and according to severity of interactions, in 7 cases we noticed major severity interaction, in 19 cases moderate severity and in 8 cases minor severity. Conclusions: The presence of drug interactions is a permanent risk in the pediatric clinic. Then, we can conclude that continued education, computer system for prescriptions, pharmacotherapy monitoring of patients, and the pharmacist participation in the multidisciplinary team are some manners of improving the treatment to hospitalized patients.

Keywords: Children, drug interactions, therapy

How to cite this article:
Qorraj-Bytyqi H, Hoxha R, Krasniqi S, Bahtiri E, Kransiqi V. The incidence and clinical relevance of drug interactions in pediatrics. J Pharmacol Pharmacother 2012;3:304-7

How to cite this URL:
Qorraj-Bytyqi H, Hoxha R, Krasniqi S, Bahtiri E, Kransiqi V. The incidence and clinical relevance of drug interactions in pediatrics. J Pharmacol Pharmacother [serial online] 2012 [cited 2022 Jan 19];3:304-7. Available from:

   Introduction Top

A drug-drug interaction may be the pharmacologic or clinical response to the administration of a drug combination, different from that anticipated from the known effects of the two agents when given alone. Clinically significant drug interactions, which pose potential harm to the patients, may result from changes in pharmaceutical, pharmacokinetic, or pharmacodynamic properties.

Patient factors that increase the risk for drug interactions include being critically-ill, polypharmacy, having impaired hepatic or renal function, hypoxemia, or metabolic disturbances, and being elderly. Given the paucity of data on drug interactions in pediatric patients, children should also be considered at a special risk. [1]

The clinical result of a drug-drug interaction may manifest as antagonism (1 + 1 < 2), synergism (1 + 1 > 2), or idiosyncratic reaction (a response unexpected from the known effects of either agent).

Adverse drug interactions pose a significant threat to hospitalized patients. Most patients receiving potentially interacting drugs do not experience adverse drug events; however, serious adverse events are known to occur. [2],[3],[4] Evidence from epidemiologic studies suggest that drug interactions contribute to a small, but significant number of adverse events in hospitalized patients. [5],[6],[7],[8] With multiple drugs often prescribed, the potential for adverse drug interactions is an important concern. No associated adverse drug events were identified, but the retrospective design of the study probably limited our ability to detect them. The purpose of the study is to verify the rate and profile of drug interactions in medical prescriptions to hospitalized pediatric patients.

   Materials and Methods Top

The data have been collected in a retrospective design from the files and drug list of children hospitalized in Pulmonology Nephrology and Gastroenterology wards in the Pediatric Clinic, from July 1999 to 2004.

Drug interactions have been analyzed by types of interactions. They are as follows:

  1. Pharmacodynamic interactions
  2. Pharmacodynamic-pharmacokinetic interactions
  3. Pharmacokinetic interactions
To evaluate the clinical significance of drug interactions we analyzed the data of 148 patients according to the significance rate of interaction, onset of interactions, severity of interaction, and documentation of clinical manifestation of interaction, in an aim to evaluate the significance rate of interaction the data were divided in to five categories (category 1 through 5), according to severity of interaction and documentation.

The methodology to assess the significance rate of interaction was based on Editorial Group's Assessment of the Interaction's Severity and Documentation. [9]

   Results Top

Initially, we collected data from 148 cases from which 34 cases had drug interactions. We analyzed the cases with drug interaction by the type of interactions, significance of interaction, rate of onset and severity.

[Table 1] presents the structure of drug interaction by type. Of 34 cases of interaction, 1 (2.94%) was pharmacodynamic, 20 (58.82%) cases were unknown, and pharmacokinetic (38.24%) were 13 cases.
Table 1: Drug interactions

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According to the rate of significance, 4 cases were of the first significance rate of interaction, 18 cases of the second significance rate, 1 case of the third significance rate, 4 cases of the fourth significance rate, and 7 cases of the fifth significance rate. According to onset of cases that were of delayed onset, and according to severity of interactions in 7 cases we have noticed major severity interaction, in 19 cases moderate severity, and in 8 cases minor severity.

The case of pharmacodynamic interaction (1/34) is an interaction of the moderate significance, delayed onset, minor severity, and suspect documentation.

Pharmacokinetic interactions have shown greater variability according to the significance rating, severity, and their documentation.

More frequent interactions were those of the second significance rating, delayed onset, moderate severity, and established documentation (5/34 or 14.71%), while 3 cases of interactions were of the first significance rate and other 3 cases of the fifth significance rate (8.87%). The first significance rate pharmacokinetic interactions were of delayed onset, major severity of interaction, and probable documentation, while the fifth significance rate were of delayed onset, minor severity of interaction, and probable documentation. As the fourth significance rate interactions were 5.88% of cases. In these cases, the interaction was of delayed onset and major severity of interaction [Table 2].
Table 2: Drug interactions according to categories (no. 34)

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Unknown type of interactions have shown greater variability according to the significance rate, onset, severity of interaction and their documentation, as well. More frequently, these interactions belonged to the second significance rate (13 or 38.23%) of whom 9 cases (26.47%) are of suspect documentation, while 4 cases (11.76%) are of probable documentation [Table 3].
Table 3: Drug interactions according to categories and drug's name (no. 34)

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   Discussion Top

In our study, we encountered a variety of drug interactions at the pediatrics clinic, but what needs more attention are the cases of first significance rate interaction, rapid onset, and major severity of interaction. Below we elaborate the most important drug interactions seen during the study in detail.

Digoxin interacts with furosemide and other loop diuretics because of changes in the electrolyte concentration induced by diuretics. Although loop diuretic drugs themselves do not alter the kinetics of digoxin excretion, they induce a dose-dependent loss of potassium from the body, resulting in a decreased serum potassium concentration. It is well known that hypokalemia is associated with sensitivity to digitalis and, thus, increases its toxicity but it is not well appreciated that when the serum potassium is as low as 2 to 3 mEq/l, the tubular secretion of digoxin is nearly blocked. This reduced tubular secretion of digoxin results in a diminished plasma clearance of digoxin and thereby a prolonged elimination half-life of digoxin. Thus, hypokalemia itself can result in an increase in the serum digoxin level as well as enhancing toxicity. Such a electrolyte imbalance can precipitate or give contribution to arrhythmias, especially among patients with previous cardiac arrhythmias.

The ability of macrolide antibiotics to interact with the biotransformation of some other drugs has been widely recognized, mostly with erythromycin and troleandomycin. Both drugs bind strongly to and inhibit markedly CYP 3A4.

The nonsedating antihistamine terfenadine is used widely in the treatment of patients with allergies. Terfenadine undergoes rapid first-pass metabolism in the liver, where cytochrome P450IIIA enzyme converts it to the active form, terfenadine carboxylate. If metabolism is inhibited, then the unmetabolized terfenadine accumulates and cardiotoxicity may ensue. This includes the development of torsade de pointes, a potentially fatal cardiac arrhythmia. Thus, co-administration of macrolides and terfenadine causes an increase in the serum level of terfenadine to cardiotoxicity levels.

Co-administration of methylprednisolone and erythromycin can also increase the pharmacologic and toxic effect of methylprednisone. These interactions occur because of increased serum levels of methylprednison.

Therapeutic efficacy of paracetamol (analgesic/antipyretic) may be diminished by rifampicin which can even increase the toxicity of paracetamol. Rifampicin can induce hepatic microsomal enzymes, which metabolizes paracetamol more quickly to metabolites, which are potentially hepatotoxic. [10]

The isoniazid serum level can be decreased by corticosteroids, by increasing the rate of hepatic acetylating in slow accelerations and by increasing renal clearance in slow as well as rapid accelerations.

By decreasing renal clearance, isoniazid can potentiate benzodiazepine action, through inhibition of oxidative metabolism of benzodiazepines in liver.

Administration of amino-glycosides or of loop diuretics, even alone, can cause ototoxicity. [11] Experimental data show that the synergistic effect appears when amino-glycosides are parenterally combined with these diuretics. Manifested ototoxicity depends on doses and serum levels of respective drugs.

Administration of amino-glycosides in combination with cephalosporin can increase nephrotoxicity through an unknown yet mechanism.

Parenteral penicillins inactivate certain amino-glycosides. Synergism of these antimicrobials is well documented. Nevertheless, some amino-glycosides are more inactivated by some penicillin's. These problems are even bigger when this happens in vitro or in a syringe where physicochemical incompatibility occurs. In vivo inactivation of amino- glycosides by penicillin depends on diminished renal function and that is why the patient should be carefully monitored. The dose of antimicrobials should be lowered, if the patient has moderate or high renal insufficiency.

Rifampicin can reduce therapeutic effects of nifedipine, potentially through increased metabolism of nifedipine on the bowel wall (cytocrome P 450 3A4) induced by rifampicin.

Combination of penicillin and chloramphenicol may show synergism against certain microorganisms, but on animal studies it has been reported even for cases of antagonism.

The mechanism of this antagonism is not clear and still not entirely determined. The same reaction happened when combining with erythromycin. [12]

   Conclusion Top

The presence of drug interactions is a permanent risk in hospitals especially in pediatric hospitals. Then, we can conclude that continued education, serum drug concentration monitoring in children, and participation of clinical pharmacologist in the multidisciplinary team during the application of drug therapy, computer system prescriptions (a computer software that provides a program that does not let entering two or more drugs that interfere with each other, and also that informs the doctor of the adverse effects and interactions of each drug prescribed) are necessary for the prevention of drug interactions, for improvement of treatment of hospitalized children.

   References Top

1.Tom-Revzon C. Drug Interactions. Pediatr Rev 2006;27:315-7.  Back to cited text no. 1
2.Gandy W. Severe epinephrine-propranolol interaction. Ann Emerg Med 1989;18:98-9.  Back to cited text no. 2
3.Leahey EB Jr, Reiffel JA, Drusin RE, Heissenbuttel RH, Lovejoy WP, Bigger JT Jr. Interaction between quinidine and digoxin. JAMA 1978;240:533-4.  Back to cited text no. 3
4.Anderson JR, Poklis A, Slavin RG. A fatal case of theophylline intoxication. Arch Intern Med 1983;143:559-60.  Back to cited text no. 4
5.Puckett WH Jr, Visconti JA. An epidemiologic study of the clinical significance of drug-drug interactions in a private community hospital. Am J Hosp Pharm 1971;28:247-53.  Back to cited text no. 5
6.Boston Collaborative Drug Surveillance Program. Adverse drug interactions. JAMA 1972;220:1238-9.  Back to cited text no. 6
7.Leape LL, Brennan TA, Laird N, Lawthers AG, Localio AR, Barnes BA, et al. The nature of adverse events in hospitalized patients. Results from the Harvard Medical Practice Study II. N Engl J Med 1991;324:377-84.  Back to cited text no. 7
8.Leape LL, Bates DW, Cullen DJ, Cooper J, Demonaco HJ, Gallivan T, et al. Systems analysis of adverse drug events. JAMA 1995;274:35-43.  Back to cited text no. 8
9.Tatro DS, editor. Drug interaction facts. St. Louis: Facts and Comparison; 2004.  Back to cited text no. 9
10.Stephenson I, Qualie M, Wiselka MJ. Hepatic failure and encephalopathy attributed to an interaction between acetaminophen and rifampicin. Am J Gastroenterol 2001;96:1310-1.  Back to cited text no. 10
11.Bates DE, Beaumont SJ, Baylis BW. Ototoxicity induced by gentamicin and furosemide. Ann Pharmacother 2002;36:446-51.  Back to cited text no. 11
12.Tatro DS, editor. Drug interaction fact. Philadelphia: Lippincott Williams & Wilkins; 2006.  Back to cited text no. 12


  [Table 1], [Table 2], [Table 3]

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