Outline Chapter 16 — Edematous States part 2

• Symptoms and diagnosis

  • Three factors important in the mechanism of edema

    • The pattern of distribution of edema which reflects those capillaries with altered hemodynamic forces

    • The central venous pressure

    • Presence or absence of pulmonary edema

  • Pulmonary edema

    • Shortness of breath and orthopnea

    • Tachypnic, diaphoretic, wet rales, gallops, murmurs

    • Check a chest x-ray

    • Cardiac disease is most common

    • But differential includes primary renal Na retention and ARDS

    • Wedge pressure will exceed 18-20 mmHg with heart or primary Na retention, but is relatively normal with ARDS

    • Uncomplicated cirrhosis does not cause pulmonary edema

      • Increased capillary pressure in this disorder is only seen below the hepatic vein

      • Normal or reduced blood volume in the cardiopulmonary circulation

  • Peripheral edema and ascites

    • Peripheral edema is cosmetically undesireable but produces less serious symptoms

    • Symptoms: swollen legs, difficulty walking, increased abdominal girth, shortness of breath due to pressure on the diaphragm.

      • Pitting edema found in dependent areas

      • Ascites found in abdomen

    • Nephrotic syndrome low tissue pressure areas like eye orbits

    • Heart Failure (right sided) peripheral edema, abdominal wall, SOB is due to concomitant pulmonary disease. Right sided heart failure increases venous pressure

    • Cirrhosis develop cirrhosis and lower extremity edema, pressure above the hepatic vein is normal or low.

      • Tense ascites can increase the pressure above the diaphragm but is relieved with a tap

      • Portal pressure > 12 mmHg required for fluid retention

      • Love the case history 16-1

    • Primary renal sodium retention

      • Pulmonary and peripheral edema

      • Jugular venous pressure is elevated

    • Nephrotic Syndrome

      • Periorbital and peripheral edema, rarely ascites

      • CVP normal to high

    • Idiopathic edema

      • Behaves as volume depleted (especially with diuretics)

• Etiology and treatment

  • General principles of treatment

    • When must edema be treated

    • What are the consequences of the removal of fluid

    • How rapidly should fluid be removed

  • When

    • Pulmonary edema is the only form of generalized edema that is life threatening and demands immediate treatment

    • Important for note: laryngeal edema and angioedema. Cerebral edema

  • What are the consequences

    • If the edema fluid is compensatory (heart failure, cirrhosis, capillary leak syndromes) then removal of fluid with diuretics will diminish effective circulating volume.

    • Despite this drop in effective circulating volume, most patients benefit from the appropriate use of diuretics.

      • Cardiac output falls 20% with diuresis of pulmonary congestion but exercise tolerance increases

      • Says to be careful in diuresis leads to increases in Cr

  • How rapidly should edema fluid be removed

    • Removing vascular fluid changes starling forces (reduced venous pressure) so fluid rapidly mobilized from interstitium. 2-3 liters per 24 hours can often be removed without difficulty

    • An exception is cirrhosis and ascites without peripheral edema. Mobilizing ascites is limited to 500-750 ml/day

  • Heart failure

    • Edema is due to increase in venous pressure raising capillary hydrostatic pressure

    • Ischemic and hypertensive CM impairs left ventricular function causing pulmonary but little peripheral edema

      • In acute pulmonary edema the LV disease results in increased LVEDP and increased left atrial pressure which transmit back to the pulmonary vein

      • When wedge exceeds 18-20 (normal is 5-12) get pulmonary edema

    • Cor pulmonale due to pure right heart failure prominent edema in the lower extremities

    • Cardiomyopathies tend to affect right and left ventricles leading to simultaneous onset of pulmonary and peripheral edema.

    • Discusses forward hypothesis in which reduction in cardiac output triggers decreased tissue perfusion activation of SNS and RAAS.

      • Catecholamines increase cardiac output

      • RAAS increase Sodium retention

      • Edema is absent and patients can be compensated at the expense of increased LVEDP see Figure 16-6

      • Figure 16-6 A to B to C with compensation

      • Eventually the increased sodium retention and increased intracranial pressure are enough to cause edema.

      • He then brings up multiple important points (in bullets none the less)

        • Dual effects of fluid retention:

          • Increased cardiac output

          • Potential harmful elevation in venous pressure

          • Benefit is found with increase in LVEDP from 12 to 15, after that it seems mostly deleterious

        • Vascular congestion (elevated LVEDP) and a low cardiac output do not have to occur together. See points B and C on 16-6.

        • Frank-Starling relationship varies with exercise.

        • Patients with moderate heart disease may be okay at rest but fail with mild exertion. This leads to more neurohormonal activation. This can worsen sodium retention and ischemia. Rest here can help augment diuretic effect. Doubling diuretic response. 40% increase in GFR.

        • Mild to mod heart disease may have no edema with dietary Na restriction. Na intake will initially increase preload and improve cardiac output and allow the Na to be excreted but as the Frank Starling curves flatten then excess sodium cannot be excreted.

      • Diastolic vs Systolic dysfunction

        • Decreased compliance in diastolic dysfunction can lead to flash pulmonary edema

          • More common with hypertension

        • Look to the ejection fraction

      • Neurohormonal adaptation

        • Initial benefit long term adverse effects

        • Norepi, renin, ADH all are vasoconstrictors

          • They raise cardiac output

          • Raise BP which is maladaptive in the long term

      • Treatment of cardiogenic pulmonary edema

        • Morphine

        • Oxygen

        • Loop diuretic

        • NTG/nitroprusside

        • If patient remains in pulmonary edema and has systolic dysfunction consider inotropic agent

      • Treatment of chronic heart failure

        • Feels dated

        • Mentions dig and loop diuretic

        • But also ACEi/BB and AA

        • Deep dive

          • Loop diuretics

          • ACEi

    • Cor Polminale

      • Edema here comes with increased CO2

      • Associated with increased HCO3 which means increased

      • HCO3 reabsorption int he proximal tubule which leads to more sodium retention

      • Hypoxemia can increase Na retention

    • Cirrhosis and Ascites

      • Both lymphatic obstruction and increased capillary permeability contribute

      • Sinusoidal obstruction leads to increased hydraulic pressure in the sinusoids.

      • Portal hypertension is necessary for ascites

        • > 12 mmHg

      • The low albumin is often present but is not contributory to edema

        • Sinusoids are freely permeable to albumin so no oncotic pressure from albumin here

      • Mechanism of ascites

        • Renal sodium conservation is an early finding and some evidence for primary sodium retention but…

        • Mostly underfill is thought to drive Na retention

          • Splanchnic vasodilation starts this of

          • NO drives this

            • Endotoxin absorption stimulates No

            • Normally endotoxin is detoxed in liver but portosystemic shunting allows endotoxin to escape the liver.

      • Hepatorenal syndrome

        • Progressive hemodynamically mediated fall in GFR

        • Induced by intense renal vasocontstriction

          • Where are the PGE and Kinins

        • Fall in GFR is masked by decreased muscle mass and decreased BUN production

        • Hyponatremia is a grave prognostic sign, as it is in heart failure, Indicates increased activation of vasopressin

        • Treatment

          • Low Na intake

          • Low water intake

          • Care with diuretics, can only mobilize 300-500 ml of ascetic fluid a day

          • Avoid hypokalemia

            • Stimulates NH3 production

            • Talks about the mechanism in proximal tubule

            • Also discusses pKA of NH3->NH4 reaction and if the pH rises, this will shift the Eq to produce NH3

              • Important aspect in NH3 is lipid soluble and NH is not

          • Says that Spiro is diuretic of choice

            • States it is more effective than furosemide in this condition

            • Effectiveness related to slower rate of drug excretionin urine (compromises furosemide but not spiro) competition with bile salts

            • Recommends 40 furosemide and 100 of spiro

          • Resistant ascites

            • Options

              • paracentesis

              • TIPS

                • Complicated by higher mortality

              • Peritoneovenous shunt

                • Largely abandoned,

    • Primary renal sodium retention

      • CKD or AKI where low GFR linits excretion of Water and Na

    • Acute GN or nephrotic syndrome

      • Broken glom with intact tubules, mean the tubules see less Na so they think “underperfused” and then they increase renal retention of NA

    • Drugs

      • Direct vasodilators like minoxidil

        • Require super high furosemide doses to counter

        • Other antihypertensives either block sympathetic NS, Na retention directly or block RAAS explains why they don’t cause Na retention

      • NSAIDS

      • Fludrocortisone

      • Pregnancy

        • Normal pregnancy is associated with retention of 900 to 1000 mEq of Na

        • And! 6-8 liters of water

      • Refeeding edema

      • Insulin stimulate Na retention