Development of Interstitial Lung Disease after Initiation of Apixaban Anticoagulation Therapy.

BACKGROUND: Nonvitamin K antagonist oral anticoagulants may cause interstitial lung disease (ILD) similar to that seen for other cardiovascular drugs. The aim of this study was to determine trends and medical conditions associated with ILD in patients taking apixaban. METHODS: A single-center observational survey conducted between February 2013 and May 2015 examined patients who developed ILD after initiation of apixaban administration. RESULTS: Chest computed tomography showed that 4 (~.45%) out of approximately 870 apixaban users developed ILD. All patients were elderly Japanese men with decreased creatinine clearance who had nonvalvular atrial fibrillation. Three of the four were confirmed smokers, whereas three had a history of lung disease. Dyspnea occurred during the initial week after starting apixaban administration in 3 patients and at 90 days in 1 patient. All patients underwent methylprednisolone pulse therapy, with three requiring mechanical ventilation. Although 2 patients recovered, the other two died of respiratory failure. CONCLUSIONS: Development of ILD during anticoagulation with apixaban is not rare. When apixaban is administered in elderly high-risk patients, subjects need to be carefully monitored for respiratory symptoms. As drug-induced ILD is often reported in Japan, further studies that clarify if these types of cases are common in countries other than Japan will also need to be undertaken.

Changes in FeNO, d-ROMs, and BH4 by Intravenous L-Arginine in Children and Its Putative Role in Asthma Treatment.

Purpose: Pteridines are metabolites of tetrahydrobiopterin (BH4), being coenzymes for nitric oxide synthase (NOS). No study has clarified the relationship among pteridines and NOS, fractional exhaled nitric oxide (FeNO) generated by pteridines, and reactive oxygen species. In this study, we administered arginine, a precursor of NO, and confirmed changes in the levels of pteridines, FeNO, and reactive oxygen species and their relationship to clarify the pathogenesis of airway inflammation in which oxidative stress is involved, such as bronchial asthma. Patients and Methods: This is a prospective, randomized open-label study. Children, aged 2 to 15 years, who were scheduled for growth hormone stimulation tests and were able to undergo a respiratory function test were recruited. They were randomly divided into two groups: arginine-administered and control groups. In the former, L-arginine hydrochloride was intravenously administered. After administration, the levels of diacron-reactive oxygen metabolites (d-ROMs), serum pteridines, serum amino acids, and fractional exhaled NO (FeNO) were measured. Results: We analyzed 15 children aged 4 to 14 years. In the arginine-administered group, there was an increase in the FeNO level and a decrease in the d-ROMs level, reaching a peak 30 min after administration, compared with the control group. In addition, there was a decrease in the serum biopterin level and an increase in the d-ROMs level, reaching peak 60 min after administration. Conclusion: The administration of L-arginine increased the NO level and decreased the d-ROMs level. Due to this, biopterin may be consumed and decreased, leading to an increase in the d-ROMs level. As a reduction in reactive oxygen species leads to the relief of inflammation, arginine and biopterin may be useful for inhibiting inflammation.