Chapter Fourteen, part 1. Hypovolemic States
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OutlineChapter 14- Hypovolemic States- Etiology - True volume depletion occurs when fluid is lost from from the extracellular fluid at a rate exceeding intake - Can come the GI tract - Lungs - Urine - Sequestration in the body in a “third space” that is not in equilibrium with the extracellular fluid. - When losses occur two responses ameliorate them - Our intake of Na and fluid is way above basal needs - This is not the case with anorexia or vomiting - The kidney responds by minimizing further urinary losses - This adaptive response is why diuretics do not cause progressive volume depletion - Initial volume loss stimulates RAAS, and possibly other compensatory mechanisms, resulting increased proximal and collecting tubule Na reabsorption. - This balances the diuretic effect resulting in a new steady state in 1-2weeks - New steady state means Na in = Na out - GI Losses - Stomach, pancreas, GB, and intestines secretes 3-6 liters a day. - Almost all is reabsorbed with only loss of 100-200 ml in stool a day - Volume depletion can result from surgical drainage or failure of reabsorption - Acid base disturbances with GI losses - Stomach losses cause metabolic alkalosis - Intestinal, pancreatic and biliary secretions are alkalotic so losing them causes metabolic acidosis - Fistulas, laxative abuse, diarrhea, ostomies, tube drainage - High content of potassium so associated with hypokalemia - [This is a mistake for stomach losses] - Bleeding from the GI tract can also cause volume depletion - No electrolyte disorders from this unless lactic acidosis - Renal losses - 130-180 liters filtered every day - 98-99% reabsorbed - Urine output of 1-2 liters - A small 1-2% decrease in reabsorption can lead to 2-4 liter increase in Na and Water excretion - 4 liters of urine output is the goal of therapeutic diuresis which means a reduction of fluid reabsorption of only 2% - Diuretics - Osmotic diuretics - Severe hyperglycemia can contribute to a fluid deficit of 8-10 Iiters - CKD with GFR < 25 are poor Na conservers - Obligate sodium losses of 10 to 40 mEq/day - Normal people can reduce obligate Na losses down to 5 mEq/day - Usually not a problem because most people eat way more than 10-40 mEq of Na a day. - Salt wasting nephropathies - Water losses of 2 liters a day - 100 mEq of Na a day - Tubular and interstitial diseases - Medullary cystic kidney - Mechanism - Increased urea can be an osmotic diuretic - Damage to tubular epithelium can make it aldo resistant - Inability to shut off natriuretic hormone (ANP?) - The decreased nephro number means they need to be able to decrease sodium reabsorption per nephron. This may not be able to be shut down acutely. - Experiment, salt wasters can stay in balance if sodium intake is slowly decreased. (Think weeks) - Talks about post obstruction diuresis - Says it is usually appropriate rather than inappropriate physiology. - Usually catch up solute and water clearance after releasing obstruction - Recommends 50-75/hr of half normal saline - Talks briefly about DI - Skin and respiratory losses - 700-1000 ml of water lost daily by evaporation, insensible losses (not sweat) - Can rise to 1-2 liters per hour in dry hot climate - 30-50 mEq/L Na - Thirst is primary compensation for this - Sweat sodium losses can result in hypovolemia - Burns and exudative skin losses changes the nature of fluid losses resulting in fluid losses more similar to plasma with a variable amount of protein - Bronchorrhea - Sequestration into a third space - Volume Deficiency produced by the loss of interstitial and intravascular fluid into a third space that is not in equilibrium with the extracellular fluid. - Hip fracture 1500-2000 into tissues adjacent to fxr - Intestinal obstruction, severe pancreatitis, crush injury, bleeding, peritonitis, obstruction of a major venous system - Difference between 3rd space and cirrhosis ascities - Rate of accumulation, if the rate is slow enough there is time for renal sodium and water compensation to maintain balance. - So cirrhotics get edema from salt retension and do not act as hypovolemia - Hemodynamic response to volume depletion - Initial volume deficit reduced venous return to heart - Detected by cardiopulmonary receptors in atria and pulmonary veins leading to sympathetic vasoconstriction in skin and skeletal muscle. - More marked depletion will result in decreased cardiac output and decrease in BP - This drop in BP is now detected by carotid and aortic arch baroreceptors resulting in splanchnic and renal circulation vasoconstriction - This maintains cardiac and cerebral circulation - Returns BP toward normal - Increase in BP due to increased venous return - Increased cardiac contractility and heart rate - Increased vascular resistance - Sympathetic tone - Renin leading to Ang2 - These can compensate for 500 ml of blood loss (10%) - Unless there is autonomic dysfunction - With 16-25% loss this will not compensate for BP when patient upright - Postural dizziness - Symptoms - Three sets of symptoms can occur in hypovolemic patients - Those related to the manner in which the fluid loss occurs - Vomiting - Diarrhea - Polyuria - Those due to volume depletion - Those due to the electrode and acid base disorders that can accompany volume depletion - The symptoms of volume depletion are primarily related to the decrease in tissue perfusion - Early symptoms - Lassitude - Fatiguability - Thirst - Muscle cramps - Postural dizziness - As it gets more severe - Abdominal pain - Chest pain - Lethargy - Confusion - Symptomatic hypovolemia is most common with isosmotic Na and water depletion - In contrast pure water loss, causes hypernatremia, which results in movement of water from the intracellular compartment to the extracellular compartment, so that 2/3s of volume loss comes from the intracellular compartment, which minimizes the decrease in perfusion - Electrolyte disorders and symptoms - Muscle weakness from hypokalemia - Polyuria/poly dips is from hyperglycemia and hypokalemia - Lethargy, confusion, Seizures, coma from hyponatremia, hypernatremia, hyperglycemia - Extreme salt craving is unique to adrenal insufficiency - Eating salt off hands ref 18 - Evaluation of the hypovolemic patient - Know that if the losses are insensible then the sodium should rise - Volume depletion refers to extracellular volume depletion of any cause, while dehydration refers to the presence of hypernatremia due to pure water loss. Such patients are also hypovolemic. - Physical exam is insensitive and nonspecific - Finding most sensitive and specific finding for bleeding is postural changes in blood pressure - I don’t find this very specific at all! - Recommends laboratory confirmation regardless of physical exam - Skin and mucous membranes - Should return too shape quickly - Elastic property is called Turgur - Not reliable is patients older than 55 to 60 - Dry axilla - Dry mucus membranes - Dark skin in Addison’s disease Frim increased ACTH - Arterial BP - As volume goes down so does arterial BP - Marked fluid loss leads to quiet korotkoff signs - Interpret BP in terms of the patients “normal BP” - Venous pressure - Best done by looking at the JVP - Right atrial and left atrial pressure - LV EDP is RAP + 5 mmHg - Be careful if valvular disease, right heart failure, cor pulmonare, - Figure 14-2 - Shock - 30% blood loss - Lab Data - Urine Na concentration - Should be less than 25 mmol/L, can go as low as 1 mmol/L - Metabolic alkalosis can throw this off - Look to the urine chloride - Figure 14-3 - Renal artery stenosis can throw this off - FENa - Mentions that it doesn’t work so well at high GFR - Urine osmolality - Indicates ADH - Volume depletion often associated with urine osm > 450 - Impaired by - Renal disease - Osmotic diuretic - Diuretics - DI - Mentions that severe volume depletion and hypokalemia impairs urea retension in renal medulla - Points out that isotonic urine does not rule out hypovolemia - Mentions specific gravity - BUN and Cr concentration - Normal ratio is 10:1 - Volume depletion this goes to 20:1 - Serum Na - Talks about diarrhea - Difference between secretory diarrhea which is isotonic and just causes hypovolemia - And osmotic which results in a lower electrolyte content and development of hypernatremia - Talks about hyperglycemia - Also can cause the sodium to rise from the low electrolyte content of the urine - But the pseudohyponatraemia can protect against this - Plasma potassium - Treatment - Both oral and IV treatment can be used for volume replacement - The goal of therapy are to restore normovolemia - And to correct associated acid-base and electrolyte disorders - Oral Therapy - Usually can be accomplished with increased water and dietary sodium - May use salt tablets - Glucose often added to resuscitation fluids - Provides calories - Promotes intestinal Na reabsorption since there is coupled Na and Glucose similar to that seen in the proximal tubule - Rice based solutions provide more calories and amino acids which also promote sodium reabsorption - 80g/L of glucose with rice vs 20 g/L with glucose alone - IV therapy - Dextrose solutions - Physiologically equivalent to water - For correcting hypernatremia - For covering insensible losses - Watch for hyperglycemia - Footnote warns against giving sterile water - Saline solutions - Most hypovolemic patients have a water and a sodium deficit - Isotonic saline has a Na concentration of 154, similar to that of plasma see page 000 - Half-isotonic saline is equivalent to 550 ml of isotonic saline and 500 of free water. Is that a typo? - 3% is a liter of hypertonic saline and 359 extra mEq of Na - Dextrose in saline solutions - Give a small amount of calories, otherwise useless - Alkalinizing solutions - 7.5% NaHCO3 in 50 ml ampules 44 mEq of Na and 44 mEq of HCO3 - Treat metabolic acidosis or hyperkalemia - Why 44 mEq and not 50? - Do not give with calcium will form insoluble CaCO3 - Polyionic solutions - Ringers contains physiologic K and Ca - Lactated Ringers adds 28 mEq of lactate - Spreads myth of LR in lactic acidosis - Potassium chloride - Available as 2 mEq/mL - Do not give as a bolus as it can cause fatal hyperkalemia - Plasma volume expanders - Albumin, polygelastins, hetastarch are restricted to vascular space - 25% albumin can pull fluid into the vascular space - 25% albumin is an albumin concentration of 25 g/dL compare to physiologic 4 g/dL - Says it pulls in several times its own volume - 5% albumin is like giving plasma - Blood - Which fluid? - Look at osmolality, give hypotonic fluids to people with high osmolality - Must include all electrolytes - Example of adding 77 mEw of K to 0.45 NS and making it isotonic - DI can be replaced with dextrose solutions, pure water deficit - Case 14-3 - Diarrhea with metabolic acidosis - He chooses 0.25 NS with 44 mEq of NaCl and 44 NaHCO3 - Talks about blood and trauma - Some studies advocate delaying saline until penetrating trauma is corrected APR about to. Keep BP low to prevent bleeding. Worry about diluting coagulation factors - Only do this if the OR is quickly available - Volume deficit - Provides formula for water deficit and sodium deficit - Do not work for isotonic losses - Provides a table to adjust fluid loss based on changes in Hgb or HCTZ - Says difficult to estimate it from lab findings and calculations - Follow serial exams - Serial urine Na - Rate of replacement - Goal is not to give fluid but to induce a positive balance - Suggests 50-100 ml/hr over what is coming out of the body - Urine - Insensibles 30-50 - Diarrhea - Tubes - Hypovolemic shock - Due to bleeding - Sequesting in third space - Why shock? - Progressive volume depletion leads to - Increased sympathetic NS - Increased Ang 2 - Initially this maintains BP, cerebral and coronary circulation - But this can decrease splanchnic, renal and mucocutaneous perfusion - This leads to lactic acicosis - This can result in intracellular contents moving into circulation or translocation of gut bacteria - Early therapy to prevent irreversible shock - In dogs need to treat with in 2 hours - In humans may need more than 4 hours - Irreversible shock associated with pooling of blood in capillaries - Vasomotor paralysis - Hyperpolarization of vascular smooth muscle as depletion of ATP allows K to flowing out from K channels opening. Ca flows out too leading to vasodilation - Glyburide is an K-ATP channel inhibitor (?) caused increased vasoconstriction and BP - Pluggin of capillaries by neutrophils - Cerebral ischemia - Increased NO generation - Which Fluids? - Think of what is lost and replace that. - Bleeding think blood - Raise the hct but not above 35 - Acellular blood substitutes, looked bad at the time of this writing - Di aspirin cross linked hemoglobin had increased 2 and 28 day mortality vs saline - Colloids sound great but they fail in RCTs - SAFE - FEAST - Points out that saline replaces the interstitial losses why do we think those losses are unimportant - Pulmonary circulation issue - Pulmonary circulation is more leaky so oncotic pressure less effective there - Talks about the lungs be naturally protected from pulmonary edema - Rate of fluid - 1-2 liters in first hour - Suggests CVP or capillary wedge pressure during resuscitation - No refs in the rate of fluid administration section - Lactic acidosis - Points out that HCO can impair lactate utilization - Also states that arterial pH does not point out what is happening at the tissue level. Suggests mixed-venous sample.ReferencesJCI - Phenotypic and pharmacogenetic evaluation of patients with thiazide-induced hyponatremia and a nice review of this topic: Altered Prostaglandin Signaling as a Cause of Thiazide-Induced HyponatremiaThe electrolyte concentration of human gastric secretion. https://physoc.onlinelibrary.wiley.com/doi/10.1113/expphysiol.1960.sp001428A classic by Danovitch and Bricker: Reversibility of the “Salt-Losing” Tendency of Chronic Renal Failure | NEJMOsmotic Diuresis Due to Retained Urea after Release of Obstructive Uropathy | NEJMIs This Patient Hypovolemic? | Cardiology | JAMAAnd by the same author, a textbook: Steven McGee. 5th edition. Evidence-Based Physical Diagnosis Elsevier Philadelphia 2022. ISBN-13: 978-0323754835The clinical course and pathophysiological investigation of adolescent gestational diabetes insipidus: a case report | BMC Endocrine DisordersSensitivity and specificity of clinical signs for assessment of dehydration in endurance athletes | British Journal of Sports MedicineDiagnostic performance of serum blood urea nitrogen to creatinine ratio for distinguishing prerenal from intrinsic acute kidney injury in the emergency department | BMC NephrologyThe meaning of the blood urea nitrogen/creatinine ratio in acute kidney injury - PMCLanguage guiding therapy: the case for dehydration vs volume depletion https://www.acpjournals.org/doi/10.7326/0003-4819-127-9-199711010-00020?url_ver=Z39.88-2003&rfr_id=ori:rid:crossref.org&rfr_dat=cr_pub%20%200pubmedValidation of a noninvasive monitor to continuously trend individual responses to hypovolemiaReferences for Anna’s voice of God on Third Spacing : Shires Paper from 1964 (The ‘third space’ – fact or fiction? )References for melanie’s VOG:1. Appraising the Preclinical Evidence of the Role of the Renin-Angiotensin-Aldosterone System in Antenatal Programming of Maternal and Offspring Cardiovascular Health Across the Life Course: Moving the Field Forward: A Scientific Statement From the American Heart Association2. excellent review of RAAS in pregnancy: The enigma of continual plasma volume expansion in pregnancy: critical role of the renin-angiotensin-aldosterone systemhttps://journals-physiology-org.ezp-prod1.hul.harvard.edu/doi/full/10.1152/ajprenal.00129.20163. 10.1172/JCI107462- classic study in JCI of AngII responsiveness during pregnancy4. William’s Obstetrics 26th edition!5. Feto-maternal osmotic balance at term. A prospective observational study