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Cardiovascular system- L7
Faisal I. Mohammed, MD, PhD Yanal A. Shafagoj MD, PhD University of Jordan
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Long term Regulation of BP…cont
3. Renin-Angiotensin-Aldosterone system 1 hour to be effective Angiotensinogen (14 a.a peptide) converted into Angiotensin I (10 a.a peptide) by Renin that come from afferent arteriolar cell, the angiotensin I is converted into angiotensin II (8 a.a peptide) by Angiotensin converting enzyme mainly in the lungs. Angiotensin II (A II) is very potent vasoconstrictor. AII also stimulates aldosterone synthesis and secretion from the adrenal coretx (Zona glomerulosa), aldosterone increases Na+ reabsorption from the renal nephrone and so water. AII is also a positive inotropic agent 2
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Juxtaglomerular Apparatus
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Renin-Angiotensin System
Renin is synthesized and stored in modified smooth muscle cells in afferent arterioles of the kidney. Renin is released in response to a fall in pressure. Renin acts on a substance called angiotensinogen to form a peptide called angiotensin I. AI is converted to AII by a converting enzyme located in the endothelial cells in the pulmonary circulation. 4
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Long term Regulation of BP …cont
4. Atrail Natriuretic peptide (ANP): An 28 a.a peptide released mainly from the Rt. Atrium in response to stretch. It causes increase in GFR and thus, increase Na+ and water excretion . Its concentration decreases when BP is low and its concentration increases if BP is high, mainly due volume overload 5
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Cardiac Output and Venous return
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Effect of Venous Valves
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Effect Of Gravity on Venous return
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Effect of Venous Valves
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The Capillaries
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The Microcirculation Important in the transport of nutrients to tissues. Site of waste product removal. Over 10 billion capillaries with surface area of square meters perform function of solute and fluid exchange. 11
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Diffusion Most important method Substances move down their concentration gradient O2 and nutrients from blood to interstitial fluid to body cells CO2 and wastes move from body cells to interstitial fluid to blood
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Fluid Exchange - Starling Forces
As blood flows to the tissues of the body, hydrostatic and osmotic forces at the capillaries determine how much fluid leaves the arterial end of the capillary and how much is then reabsorbed at the venous end. These are called Starling Forces. Filtration is the movement of fluid through the walls of the capillary into the interstitial fluid. Reabsorption is the movement of fluid from the interstitial fluid back into the capillary. 13
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Fluid Exchange - Starling Forces
Two pressures promote filtration: Blood hydrostatic pressure (BHP) generated by the pumping action of the heart - decreases from 35 to 16 from the arterial to the venous end of the capillary Interstitial fluid osmotic pressure (IFOP), which is constant at about 1 mmHg 14
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Fluid Exchange - Starling Forces
Two pressures promote reabsorption: Blood colloid osmotic pressure (BCOP) is due to the presence of plasma proteins too large to cross the capillary - averages 36 mmHg on both ends. Interstitial fluid hydrostatic pressure (IFHP) is normally close to zero and becomes a significant factor only in states of edema. 15
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Fluid Exchange - Starling Forces
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Fluid Exchange - Starling Forces
Normally there is nearly as much fluid reabsorbed as there is filtered. At the arterial end, net pressure is outward at 10 mmHg and fluid leaves the capillary (filtration). At the venous end, net pressure is inward at –9 mmHg (reabsorption). On average, about 85% of fluid filtered is reabsorbed. 17
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Fluid Exchange - Starling Forces
Fluid that is not reabsorbed (about 3L/ day for the entire body) enters the lymphatic vessels to be eventually returned to the blood. 18
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Net Filtration Pressure (NFP)
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Filtration Rate = Kf{(Pc – Pif) – ( c - if)}
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Filtration Rate = Kf{(Pc – Pif) – ( c - if)}
Mean capillary hydrostatic pressure (Pc)-tends to force fluid outward through the capillary membrane. Interstitial fluid pressure (Pif)- opposes filtration when value is positive. Plasma colloid osmotic pressure (π c)- opposes filtration causing osmosis of water inward through the membrane Interstitial fluid colloid pressure (π if) promotes filtration by causing osmosis of fluid outward through the membrane Filtration coefficient (Kf)
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Gas And Nutrient Exchange
In contrast to the bulk flow of fluids at the capillaries, the exchange of gases and small particles (like certain nutrients and wastes) is a purely passive diffusion process. Gases and these other substances simply move into or out of the capillary down their concentration gradient. 22
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Factors that Facilitate Venous Return
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Thank You 24
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