RESEARCH ARTICLE


Pleuropulmonary Toxicity of Another Anti-Parkinson’s Drug: Cabergoline



Yolanda Belmonte1, Oriol de Fàbregues2, Marta Marti3, Christian Domingo*, 1, 4
1 Pneumology Service, Corporació Sanitària Parc Taulí, Sabadell, Barcelona, Spain
2 Neurology Service, Corporació Sanitària Parc Taulí, Sabadell, Barcelona, Spain
3 Clinical Pharmacology Service, Corporació Sanitària Parc Taulí, Sabadell, Barcelona, Spain
4 Autonomous University of Barcelona (UAB), Barcelona, Spain


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Creative Commons License
© Belmonte et al.; Licensee Bentham Open.

open-access license: This is an open access article licensed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/) which permits unrestricted, non-commercial use, distribution and reproduction in any medium, provided the work is properly cited.

* Address correspondence to this author at the Pulmonary Service, Hospital de Sabadell (Corporacio Parc Taulí), Parc Taulí s/n, 08208 Sabadell, Barcelona, Spain; Tel: 34-93-723 10 10, Ext. 21 160; Fax: 34-93 716 06 46; E-mail: cdomingo@tauli.cat


Abstract

Many drugs may cause toxic injury to the lungs and the pleura. Cabergoline is an ergoline derivative which has been used in Spain for seven years to control symptoms of Parkinson’s disease. We report a patient with dyspnea, bilateral pleural effusion and distal swelling. After a series of complementary tests (blood analysis, chest CT, echocardiogram, pleural tap, pleural biopsy), etiological screening ruled out infection, malignancy or inflammation. Given the patient’s history of three years’ treatment with cabergoline, the drug was considered a possible cause and was progressively withdrawn. The patient’s clinical condition improved and radiological images were disease-free. Using Karch and Lasagna’s classical criteria, we defined a relationship of “probable causality” between the drug and the adverse effects reported.

Keywords: Pleural effusion, pleural fibrosis, parenchymal lung opacity, cabergoline..



INTRODUCTION

Today, more than 350 drugs are known to produce pleuro-pulmonary damage [1]. The diagnosis of drug-induced pulmonary disease is usually per exclusionem since in most cases there is no specific diagnostic test [1]. If disease is suspected, Karch and Lasagna’s classical criteria are applied to try to establish causal relations [2]. We report a patient who developed pleuro-pulmonary pathology, mainly in the form of pleural effusion, after prolonged administration of cabergoline.

CASE REPORT

Sixty-five year-old male, ex-smoker with an accumulated dose of 40 packs-year and without any work-related history of interest. He had undergone surgery for colon cancer and was currently disease-free. He had Parkinson’s disease of more than 10 years’ evolution and had been receiving L-Dopa (1600mg/d) combined with carbidopa (250mg/d) and benserazide (150mg/d) since the diagnosis, entacapone (800mg/d) and cabergoline 4mg/d (the latter added three years previously). He was referred to our unit for progressive dyspnea, swollen ankles and intolerance of the supine position for over a month. The only finding of interest in the physical examination was the presence of bilateral basal hypophonesis in the respiratory auscultation, regular heart rhythm without murmurs and pitting edemas in the lower half of both legs. Blood analysis: ESR 70, LDH 333, CRP 1.3, PSA, Reumatoid factor and anti-tissue antibodies were within reference values. Chest x-ray: bilateral pleural effusion (Fig. 1). Electrocardiogram: sinus rhythm 75 per minute, without repolarization disturbance. Echocardiogram: alteration in ventricular relaxation with a left ventricle ejection fraction of 60% without valvulopathy and preserved global contractility. Initially, heart failure was considered; diuretic treatment was initiated, but only achieved a slight improvement in the distal swelling. Diagnostic pleural tap was compatible with a lymphocyte exudate with low ADA value (Table 1); cytological and microbiological studies (Ziehl-Neelsen stain and Lowenstein-Jensen culture) were negative. Pleural biopsy showed marked fibrosis and isolated areas of reactive mesothelial proliferation without evidence of malignancy. Chest CT showed bilateral pleural thickening and effusion affecting the underlying parenchyma (Fig. 2). Respiratory function testing: FVC 2.88L (73%), FEV1 2.18L (77%), FEV1/FVC 76% (bronchodilator test was non-significant), TLC 4.55L (73%), RV 1.60L (76%), DLCO 71%, KCO 84%. Arterial blood gas analysis on room air: pH 7.43, PaO2 88.7 mmHg, PaCO2 36.7 mmHg, bicarbonates 25.3 mEq/L, Alveolo-arterial gradient 14 mmHg, COHb 0.4%. Due to the poor clinical response to diuretic treatment and after ruling out other possible causes of the symptoms (infection, malignancy, systemic disease, renal failure) a pharmacological etiology was considered possible, and so carbegoline treatment was withdrawn (after agreeing on a new therapeutic approach with the neurology service). After two years of clinical and radiological follow-up, the patient had clinically improved, mild left pleural thickening persists (Fig. 3) and the pulmonary function testing shows a relative improvement of the restriction pattern (FVC 2.94L (75%), FEV1 2.16L (76%), FEV1/FVC 74%, TLC 4.57L (73%), RV 1.58L (73%), DLCO 70%, KCO 78%).

Fig. (1).

Chest x-ray at the beginning of the study. Observe the pleural effusion affecting both hemithoraces.


Fig. (2).

(A: Mediastinal window and B: parenchymal window). CT Scan at the beginning. Observe the pleural effusion affecting both hemithoraces. Parenchymal lung opacities are also seen.


Fig. (3).

(A: Mediastinal window and B: parenchymal window) CT scan at the end of follow-up. Observe the improvement in the pleuro-pulmonary abnormalities compared with the previous chest CT scan. The pleural effusion has disappeared, but pleural fibrosis remains to some extent.


Table 1.

Characteristics of Patient’s Pleural Fluid


  • Cellularity: 750 leukocytes per mm3,
      95% lymphocytes,
      5% neutrophils;
  • Ratio Proteins in Pleural Fluid/Blood (g/L): 51/ 79= 0.65
  • Ratio LDH in Pleural Fluid/Blood (U/L) 560/ 333 = 1.68
  • ADA: 15.2 U/L
Table 2.

Review of the Literature


Reference Cabergoline Dose Cabergoline’s Treatment Duration Length of Respiratory Symptoms Adverse Effect Treatment with Oral Steroids
Villavicencio [2] 1mg/day Four months Three months Pleural efusión
Intersticial lung diasease
Pericardial thickening
No
Bhatt MH [12] 3mg/day * One month Pleuropulmonary disease No
Frans E [13] * Ten months Three months Pleuropulmonary disease No
Ling LH [14] 10mg/day Two years 8-10 weeks Pleuropulmonary inflammatory-fibrotic syndrome No
Frank W [15] 1mg/day Four months 4-8 weeks Intersticial pneumonitis No
Townsend M [16] 5mg/day Six years Three months Constrictive pericarditis
Pleural effusion
Yes
Guptha SH [17] 4mg/day Four years Four months Pleural thickening
Pleural effusion
No
Hashiguchi S [18] 3mg/day Six years Three months Pleural effusion No

Missing data.

DISCUSSION

Drug-induced pleural effusion is less frequent than drug-induced parenchymal lung disease, though the two conditions may co-occur [1]. Some thirty substances are known to be possible causes of pleural effusion, among which the most frequent are: cardiovascular drugs (propranolol, amiodarone), ergoline derivatives (methysergide, bromocriptine), chemotherapy drugs (bleomycin, mitomycin, procarbazine, methotrexate, cyclophosphamide), antibiotics such as nitrofurantoin and the sclerotherapeutic agents sodium morrhuate and absolute alcohol [1, 2].

Cabergoline is an ergoline derivative with potent dopamine agonist properties. It was approved by the Food and Drug Administration (FDA) in 1997 and has been marketed in Spain since 2001 for the treatment of signs and symptoms associated with Parkinson’s disease [3]. The incidence of pleuro-pulmonary damage due to cabergoline is estimated to be between 2 and 6% [1, 4].

The mechanism via which ergoline derivatives produce fibrosis (either pleuropulmonary, retroperitoneal or cardiac) seems to be related to their serotoninergic effect, acting as 5-HT2b receptor agonists [5]. This leads to the activation of cellular mitogenesis (fibroblasts) inducing fibrosis in the organ affected (for instance, the cardiac valve, the pleura and so on) [5, 6-10].

The clinical presentation of drug-induced pleural effusion varies from asymptomatic forms to acute pleuritis [1], dry cough, dyspnea and distal swelling [4]. Chest X-ray shows the presence of uni- or bilateral pleural effusion with or without pulmonary infiltrates [4]. The biochemical analysis of pleural effusion usually corresponds to an exudate of lymphocytes and/or eosinophils with low ADA [1, 4]. Our patient presented all these features. Cases of constrictive pericarditis [11] and cardiac valve regurgitation [3] have also been reported. The time between the initiation of treatment and appearance of symptoms ranges between 5 and 48 months (Table 2); in our case, the clinical symptoms appeared after 3 years of treatment

Withdrawal of the drug leads to an improvement – on occasions, resolution of the pleural effusion – though the fibrotic changes in the pleura and parenchyma may persist [1, 4]. Treatment with systemic corticoids reduces the pleural thickening and the pulmonary interstitial involvement although not all the patients have been treated with oral corticosteroids (Table 2). Our patient improved with the withdrawal of the drug though oral corticoids were added (prednisolone at doses of ½ mg /Kg weight in decreasing doses over 4 months) but some pleural thickening and parenchimal fibrotic damage remained. Our case meets four of Karch and Lasagna’s five criteria [6, 19]. The fifth criterion (reintroduction of the drug to test side effects) could not be confirmed. Since the side effect was already known, it was not considered ethical to reinitiate the drug treatment after the clinical improvement. In the case of a pleural effusion with a lymphocyte exudate, any drug being administered as treatment should be considered a possible cause before a more exhaustive study is carried out which may incur unnecessary economic cost and discomfort to the patient [1].

For all these reasons, we agree with the authors who recommend radiology and a pulmonary function study prior to the start of treatment with an ergoline derivative, and subsequent active monitoring of pleuropulmonary toxicity. We also recommend follow-up studies of this potential side effect after a minimum of 6-12 months of treatment.

CONFLICT OF INTERESTS

Dr. Christian Domingo reports receiving lecture fees from GSK, ASTRA-ZENECA, NOVARTIS, BOEHRINGER, MENARINI, BAYER, CHIESI. There are no conflicts of interest for the rest of the authors.

ABBREVIATIONS

ADA = Adenosine Deaminase
COHb = Carboxyhemoglobine
Chest CT = Chest Computed Tomography
CRP = C-Reactive Protein
DLCO = Diffusing Lung capacity for carbon monoxide
ESR = Erythrocyte Sedimentation Rate
FEV1 = Forced Espiratory Volum in the 1st minute
FVC = Forced Vital Capacity
KCO = Corrected DLCO
LDH = Lactate Dehydrogenase
PaO2 = Arterial oxygen tension
PaCO2 = Arterial carbon dioxide tension
PSA = Prostate Specific Antigen
RV = Residual Volume
TLC = Total Lung Capacity

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