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Transcript
Abnormal Hemodynamics Darren Powell, RCIS, FSICP Blaufuss Multimedia - Heart Sounds CD Disclosure Statement for Darren Powell • No disclosures Topics • The Physics of Blood Flow Turbulence - Murmurs Gradients • Recognize Abnormal Hemodynamics Stenosis Regurgitation Focus on ASD Shunts Cardiac Anatomy Blaufuss Multimedia - Heart Sounds CD Laminar Flow Cardiovascular Physiology 8th ed Page 119 Turbulence Cardiovascular Physiology 8th ed Page 126 Physics of Blood flow Effect of velocity on pressure Cardiovascular Physiology 8th ed Page 117 Aortic Stenosis Cardiovascular Physiology 8th ed Page 119 Poiseuille’s Law • Q= (Pi-Po) π r4 • 8nl • • • • Q = Flow through system Pi = Pressure into the system Po = Pressure out of system π = pi • r = Radius raised to the 4th power • n = Viscosity of fluid • l = Length of tube Physics Summary • Laminar flow is more efficient than turbulent. • Radius of tube is the most important variable in determining flow/gradients. True in valves for AS but also in the LAD for an ACS patient The Wiggers Diagram Blaufuss Multimedia - Heart Sounds CD Hemodynamic Theorems • • • • • • Valves open and close due to pressure gradients. When pressure lines cross, valves are opening or closing. To evaluate a valve you must know the pressure on both sides. MV&TV are open in diastole/closed in systole. AV & PV are open in systole /closed in diastole. Stenosis shows when valves are open. Potential to kinetic = gradient/ pressure step-down • Regurgitation shows when valves are closed. Large pulse pressure or large V waves = triangles Normal Valve areas/adult Aortic Mitral • Normal = 2.5 Cm2 • Normal = 5.0 Cm2 • Critical=0.5-0.8 Cm2 • Critical = 1.0 Cm2 • • • Aorta twice as large Read the Echo report Calibrate transducers • • Critical when 1/5th normal Temporal alignment with CO and Gradient Calcific Acquired AS www.pathology.vcu.edu Aortic Stenosis : • LV-Ao pressure gradient throughout systole – murmur occurs w/ upstroke CW Doppler: • high velocity outflow – reaches peak of 5 m/sec – est. 100 mmHg gradient Severe AS: • LV pressure rises – increases LV-Ao gradient • murmur peaks later Blaufuss Multimedia - Heart Sounds CD Hemodynamic effects of heart rate 80 bpm: • tachycardia exacerbates LA emptying dysfunction • loud S1 • loud MDM, PSM 110 bpm: • loud murmur was thought to be systolic by house staff • murmur ends with loud S1 • mid-diastolic murmur 66 bpm: • each component can be heard • loud S1, S2/OS, MDM, PSM Chronic vs. Acute Aortic Regurgitation Chronic: • at Base: – MSM (Ao outflow) – EDM (Ao regurgitation) • at Apex: – Austin Flint (mitral inflow) – “split” S1 (S1 + ejection sound) Acute: • at Base: – MSM (Ao outflow) – EDM is abbreviated • at Apex: – Austin Flint (mitral inflow) – absent S1 (ejection sound only) Hemodynamics of Acute and Chronic Normal: • S1, S2, no murmurs Mitral valve prolapse: • midsystolic click, possible late systolic murmur of MR Acute MR: • here, from chordal rupture • loud S1, initiates explosive systolic murmur • S3 with mid-diastolic murmur Compensation: • increased compliance of LA, LV • blowing holosystolic murmur • mid-diastolic rumble Intra Cardiac Shunts Normally Pulmonary Flow = Systemic Flow QP = QS Pulmonary Artery Pulmonary Venous O2 sat O2 sat Systemic Venous O2 sat Systemic Arterial Flamm O2 sat Intra Cardiac L to R Shunts Acyanotic Pulmonary Flow greater than Systemic Flow QP > QS Elevated PA O2 sat PV O2 sat SV SA O2 sat O2 sat Intra Cardiac R to L Shunts Cyanotic Systemic Flow greater than Pulmonary Flow Qp < Qs PA O2 sat Pulmonary Venous O2 sat SV O2 sat Decreased SAO2 sat ASD- Anatomy/Prevalence • Secundum 75% • Primum 15% • Sinus Venosus 10% • Cor Sinus (rare) Braunwauld’s Heart Disease, 6th ed Cardiac Output = CO • CO is the blood flow out of the heart in L/min • Normal CO is 5 L/min (CI=2.5-4.0 L/min/ M2 ) • Qs is SBF (systemic Blood Flow) = 5 L/min • Qp is PBF (Pulmonic Blood Flow) = 5 L/min • Qp:Qs Ratio (5:5) =1:1 Shunt Example • Qp is PBF (Pulmonic Blood Flow) = 12 L/min • Qs is SBF (systemic Blood Flow) = 4L/min • Qp:Qs Ratio (12:4) =3:1 • Absolute shunt (PBF-SBF) 12-4=8 lpm • % shunt (PBF-SBF/PBF) 12-4/12 8/12=67% Question • Here are the sats: IVC=78% RA=85%, • • • • • RV=86%, PA=85%LV=98%,DescAo=98%. The PBF = 6 l/m and SBF = 4 l/m. Where is the shunt and what direction? a. ASD Rt to Lt b. ASD Lt. to Rt c. VSD Rt to Lt d. VSD Lt to Rt References • Wes Todd CD • Kern The Cardiac Cath Handbook • Grossman/Baim Cardiac Catheterization, Angiography, and Intervention • Berne and Levy Cardiovascular Physiology • Watson and Gorsky Invasive Cardiology A manual for Cath Lab Personnel • Blaufuss multimedia - Heart Sounds CD Hemodynamics summary: You’ve got to know where to look
