Renal Arteries--> Segmental Arteries--> Lobar Arteries--> Interlobar Arteries--> Arcuate Arteries--> Cortical Radiate Arteries--> Afferent Arterioles--> Glomeruli--> Efferent Arterioles--> Peritubular Capillaries--> Cortical Radiate Veins--> Arcuate Veins--> Interlobar Veins--> Renal Vein.
Why would you want to do that. You would have to cut open the heart and watch the blood move from the pulmonary artery through the heart and into the right radial artery.
Renal artery - segmental artery - interlobar artery - arcuate artery - interlobular artery
The answer starts with Aortic arch to left brachiocephalic trunk to left common carotid to left external carotid to left occipital artery.
In the presence of renal artery stenosis, the resistance in the afferent arteriole is increased. As compensation, Angiotensin II acts to constrict the efferent arteriole in order to achieve adequate profusion of the glomerulus. ACE inhibitors block the conversion of angiotensin I into angiotensin II. Without its vasoconstrictive effect, the efferent arteriole becomes dilated. This leads to a drop in GFR and may lead to renal failure.
The only artery that is supposed to carry deoxygenated blood is the pulmonary artery. It carried deoxygenated blood from the right ventricle to the lungs for oxygenation. Any artery can carry deoxygenated blood, so be careful how you word questions.
Why would you want to do that. You would have to cut open the heart and watch the blood move from the pulmonary artery through the heart and into the right radial artery.
Renal artery - segmental artery - interlobar artery - arcuate artery - interlobular artery
The common path is aortic arch > brachiocephalic artery > internal carotid arteryThe internal carotid artery branches off to provide blood to different regions of the brain e.g. ophthalmic, anterior/middle/posterior cerebral
the veins
The answer starts with Aortic arch to left brachiocephalic trunk to left common carotid to left external carotid to left occipital artery.
acute renal failure
Here we go! [First, the pulmonary circuit.] R atrium; R ventricle; pulmonary artery (L or R); arteriole; capillary adjacent to an alveolus of lung; venule; pulmonary vein [Now the blood returns to the heart for the systemic (body) circuit.] L atrium; L ventricle; aorta; R iliac artery; arteriole; capillary in a toe of the R foot; venule; R femoral vein; vena cava; back to the R atrium
In tracing a drop of blood from the pulmonary to radial artery, there are 5 circulatory points. Pulmonary follows through to the subclavian artery, axillary artery, brachial artery, and then to the radial.
The only artery that is supposed to carry deoxygenated blood is the pulmonary artery. It carried deoxygenated blood from the right ventricle to the lungs for oxygenation. Any artery can carry deoxygenated blood, so be careful how you word questions.
In the presence of renal artery stenosis, the resistance in the afferent arteriole is increased. As compensation, Angiotensin II acts to constrict the efferent arteriole in order to achieve adequate profusion of the glomerulus. ACE inhibitors block the conversion of angiotensin I into angiotensin II. Without its vasoconstrictive effect, the efferent arteriole becomes dilated. This leads to a drop in GFR and may lead to renal failure.
There are receptors on the lining of the carotid artery that sense a change in blood pressure. When they are stimulated, they can cause a drop in blood pressure/heart rate.
Right atrium > right ventricle > pulmonary artery > lung > pulmonary vein > left atrium > left ventricle > aorta > arteries > arterioles > capillaries > venules > veins > vena cava > right atrium (again)