Microangiopathy (also known as microvascular disease, small vessel disease (SVD) or microvascular dysfunction) is a disease of the microvessels, small blood vessels in the microcirculation. It can be contrasted to macroangiopathies such as atherosclerosis, where large and medium-sized arteries (e.g., aorta, carotid and coronary arteries) are primarily affected.
Small vessel diseases (SVDs) affect primarily organs that receive significant portions of cardiac output such as the brain, the kidney, and the retina. Thus, SVDs are a major etiologic cause in debilitating conditions such as renal failure, blindness, lacunar infarcts, and dementia.
Types
Microangiopathies are involved in a variety of different diseases including:
Pathophysiology
The main target of small vessel diseases is the endothelium, which plays a key role in vascular homeostasis.
Diabetic microangiopathy, which is the most common cause of microangiopathy, is more prevalent in the kidney, retina and vascular endothelium since glucose transport in these sites isn't regulated by insulin and these tissues cannot stop glucose from entering cells when blood sugar levels are high. Among all biochemical mechanisms involved in diabetic vascular damage such as the polyol pathway and the renin–angiotensin system (RAS), the advanced glycation end products (AGEs) pathway appears to be the most important in the pathogenesis and progression of microvascular complications.
Chronic high blood sugar levels lead to the attachment of sugar molecules to various proteins, including collagen, laminin, and peripheral nerve proteins. This process, called glycosylation, creates advanced glycation end products (AGEs). AGEs formation cross-links these proteins, making them resistant to degradation. This leads to accumulation of AGEs, thickening of the basement membrane, narrowing the blood vessels, reducing blood flow to the tissues and causing ischemic injury.
In addition, oxidative stress, caused by AGEs and the other pathways, causes apoptosis of pericytes and podocytes in the retina and the kidneys respectively leading to capillary wall fragility and increased vascular leakage. This results in local swelling (e.g. macular edema) and impaired tissue function.
Microvascular diseases as a multisystem disorder
Some researchers have suggested that SVD may be a multisystem disorder, meaning that it can affect multiple organs in the body, including the heart and brain. This is supported by multiple studies stating that cardiac pathologies are more prevalent in patients with pathological evidence of cerebrovascular SVD and vice versa.
Coronary microvascular diseases (CMDs) can be caused by:
Many studies have demonstrated that evaluation of the retinal microvascular changes using OCTA or other methods such as fluorescein angiography may reflect the systemic microvascular functions as in patients with coronary microvascular disease, cerebral small vessel diseases or systemic sclerosis (The potential of retinal microvascularopathy as a biomarker for assessing microvascular status of other circulations).
Unlike the retinal microcirculation, the coronary microvasculature cannot be directly imaged. Instead, a number of different tests can be used to measure how much blood is flowing through the coronary microvasculature. These tests can be used to assess how well the coronary microvasculature is functioning and to diagnose coronary microvascular disease.
Similarly, CSVD is typically recognized on both brain magnetic resonance imaging (MRI) and computed tomography (CT) scans, but MRI has greater sensitivity and specificity. Neuroimaging of CSVD primarily involves visualizing radiological phenotypes of CSVD such as recent subcortical infarcts or cerebral microbleeds (CMBs). |Intensive management of coexisting conditions and risk factors (e.g. adequate control of blood pressure, diabetes and related metabolic abnormalities and lipid management).