6533b827fe1ef96bd1287165
RESEARCH PRODUCT
Nitrate therapy: new aspects concerning molecular action and tolerance.
Tommaso GoriThomas MünzelAndreas Daibersubject
medicine.medical_specialtymedicine.disease_causeNitric oxideSuperoxide dismutasechemistry.chemical_compoundPhysiology (medical)Internal medicineMedicineHumansEndothelial dysfunctionchemistry.chemical_classificationReactive oxygen speciesNitratesbiologybusiness.industrySuperoxideDrug Tolerancemedicine.diseaseNitric oxide synthaseOxidative StressEndocrinologychemistryCardiovascular Diseasesbiology.proteinEndothelium VascularCardiology and Cardiovascular MedicinebusinessPeroxynitriteOxidative stressdescription
Although the short-term vasodilatory properties of organic nitrates are potent and well known, a number of vascular and extravascular changes have been shown to compromise their hemodynamic effects on long-term administration. Among these changes, systemic phenomena such as neurohormonal activation and intravascular volume expansion1 as well as specific vascular changes such as increased vascular superoxide (O2·−) production,2 increased sensitivity to vasoconstrictors,3 and decreased responsiveness to nitric oxide (NO) donors4,5 have long been identified as playing a role. Several hypotheses have been proposed to explain these abnormalities, and over the last 15 years, our groups have focused on the concept that an inappropriate production of reactive oxygen species (ROS), an impairment in the scavenging of these mediators (Figure 1), or both might have a crucial mechanistic importance in all these modifications.6,7 Independently of the role of ROS in tolerance, the possibility that nitrate-induced oxidative stress might affect patients' prognosis has important implications, and the observation that long-term therapy with most of the drugs in this class causes endothelial dysfunction, the prognostic significance of which is well accepted in patients with coronary artery disease, hypertension, and heart failure,8 should not be taken as an academic curiosity. Figure 1. Free radical biochemistry. The radical nitric oxide reacts with superoxide to form the highly reactive intermediate peroxynitrite. Superoxide is dismutated by superoxide dismutase (SOD), leading to the formation of hydrogen peroxide (H2O2) and molecular oxygen (O2). Beyond these as-yet insufficiently investigated prognostic implications, recognition of the role of ROS suggests that a number of interventions thought to interfere with the vascular redox balance might also retard or prevent the development of nitrate tolerance and nitrate-induced side effects. Evidence that therapy with angiotensin-converting enzyme (ACE) inhibitors, angiotensin-1 receptor blockers, certain …
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2011-05-17 | Circulation |