Download - FLUID AND ELECTROLYTE DISTURBANCES
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FLUID AND ELECTROLYTE DISTURBANCES
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AGENDA• Physiology and pathophysiology of body fluid composition
• Disorders of the internal environment associated with normalECF effective tonicity
Isotonic hypohydrationThird spacingIsotonic hyperhydration
• Disorders of the internal environment associated with abnormalECF effective tonicity
Free water deficitFree water excess
• Differetial diagnosis of hyponatremia
• Differential diagnosis and treatment of hypokalemia
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Composition of the body
solids 40%Transcelularcompartment P
LASMA
• Pericardialspace
• Pleural space
• Peritonealspace
• Intestinallumen
• Subcutaneoustissue (edema)
• Muscles
• Skin
Na-K-ATPase
Na+
K+
ECF
IFC ≈ 15%≈ 5%
ICF ≈ 40%Kg- Na≈ 2-3%- K≈97-98%
↓Oncoticpressure
↑Hydrostaticpressure
energy supply
Effectivetonicity
H2O
Concentrationof effective activemulecules
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The basic requirement of the physiologicalcomposition of the internal environment
Isovolemia
Isotonicity
Electroneutrality
Maintanance of :
Preservation of blood pressureand circulation
Is determined by the amount of osmoles which are able to cause water transport between ICF a ECF
Electroneutrality is a balanced amount of positively and negatively charged solutes in body fluids. Disorders ofelectroneutrality influencedacid - base balance
Isovolemia is the superior law, becausemaintaining an effective circulating volume, so also functional blood circulation, allows in stress conditions fight or run away, so survive!!!
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Na+ + K+ + Ca2+ + Mg2+ + H+ = OH- + Cl- + HCO3- + albumin- + Pi-
Electroneutrality is a balanced amount of positively and negatively charged solutes in body fluids
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Osmolality- Osmolarity-TonicityOSMOLARITY (mmol/L),
OSMOLALITY (mmol/Kg)
is the concentration of all solutes
regardless of their ability to cause
water transport between ICF a ECF
Effective tonicity (mmol/L)
is determined by the amount of
osmoles which are able to cause water
transport between ICF a ECF
Natrium
Glukóza
Manitol
Glycin
Urea
Methanol
Ethanol
Ethylenglycol
OSMOLES
ENDOGENOUS EXOGENOUS
effective uneffective
Plasma osmolality and percentage portionof osmotic active particles
other
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Osmolal gap
Effective tonicity = 2 x (Na+ + K+) + Sglucose
Osmolality = laboratory cryoscopic measurement of all
osmotic particles in ECF (plasma)
Osmolal gap = defference between measured
osmolality and calculated effective tonicity < 10
mosm/Kg. Effective tonicity determines water
trnasport between ECF and ICF.
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Under conditions of hypotonichyponatremia(POsm<280 mOsm/kg H2O ), Uosm >100 mOsm/kg H2O confirms , that ADH plays an active role
Verbalis JG. Disorders of body water homeostasis. Clin Endocrin Metab 2003
Osmotic regulation of ADH releasedepends on the effective osmolality
Under conditions of effective osmolality < 280 mOsm/kg H2O release of ADH is totallysuppressed (Uosm je < 100 mOsm/kg H2O)
The main determinant of effective tonicity i ECF serum natrium concentration (S Na+)
Uosm is easy decetable laboratory marker of theADH activity under conditions of hyponatremie
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ADH function in homeostasis of the internal environment
↑↑↑ADH
↑T ECF tonicity
Osmoreceptors Baroreceptors
EBV
Appropriaterelease
Inappropriaterelease
↑ADH
• ↑ADH release from
pituitry gland
• Ectopic ADH production
• ↑ ADH activity on
aquaporin-2-R
↑↑↑ADH
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AGENDA• Physiology and pathophysiology of body fluid composition
• Disorders of the internal environment associated with normalECF effective tonicity
Isotonic hypohydrationThird spacingIsotonic hyperhydration
• Disorders of the internal environment associated with abnormalECF effective tonicity
Free water deficitFree water excess
• Differetial diagnosis of hyponatremia
• Differential diagnosis of hypokalemia
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Isotonic hypohydration
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Isotonic dehydration: deficit of water and solutes in isotonic ratio (ECF volumedepletion)
ICF
IVC
• Plasma and ECF Na+ concentrationis unchanged
• No water transport betweenECF a ICF
• Plasma and ECF concentration K+
can be changed depending on thecause od dehydratation and acid-base disturbances
• Plasma and ECF Cl- concentrationdepends on causes and consequences of isotonic fluid loss
• ABB depends on causes and consequences of isotonic fluid loss
IFC
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Causes of isotonic dehydration
• GI losses (vomiting, diarrhea, nasogastricsuction, fistula drenage, short bowel)
• Renal losses (salt lossing nephropathy, impairment of renal tubular function, primaryendocrinologic disorders)
• Sequestration of fluid (ileus, burns, peritonitis, pancreatitis)
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Isotonic dehydration: etiology
GI losses:
Ethiopathogenesis
Primary loss of H+ a Cl-, retention HCO3- → matabolic alcalosis →renal
compensation → ↑NaHCO3 renal excretion→ Na+ loss → activation RAAS →
↑ aldosteron → ENAC: ↑Na+ tubular resorption and ↑ K+ and H+ secretion
vomiting,
nasogatric suction
H+ is neutralized by HCO3-
in equimolar ratio (1:1)
HCl
Isotonic dehydrataion + hypochloremia + hypokalemia + metabolic alkalosis
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Isotonic dehydration: etiology
GI loss: small bowel fistula, surgical resection of the
small intestine: jejunostomy, ileostomy, ….
Ethiopathogenesis
Diet containing fatty acids → Diarrhea → primari GI loss of HCO3-
acompanied with Na+ →activation RAAS →
↑ aldosteron → ENAC: ↑Na+ tubular resorption and ↑ K+ and H+ secretion
Primary GI K+ loss
small bowel syndrome
jejunostomy Jejuno-colic an. jejun-ileo an.
Isotonic dehydratation, hyperchloremic metabolic acidosis, severe hypokalemia
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Isotonic dehydration: etiology
GI Loss:
Ethiopathogesis
Diarrhea → primari GI loss of HCO3- acompanied with Na+ →activation RAAS
→ ↑ aldosteron → ENAC: ↑Na+ tubular resorption and ↑ K+ and H+ secretion
Primary GI K+ loss
Infection
Diverticulitis
Dysmicrobia
IBD
Ischemia
Malabsorption
Diarrhea
Izotonic dehydratation, hyperchloremic metabolic acidosis, hypokalemia
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Isotonic dehydration: renal etiology
Urinary loss caused by „salt losin nephropathy“
DM complicated by ketoacidosis: loss of Na+ a K+ ketoacids salts
CSWS: Hyperproduction natriuretic peptides (brain trauma, brain tumor,
subarachnoid hemorrhage, apoplex)
Adrenal insufficiency
AIN, Chronic TIN, medullary kidney disease, ADPKD, SLE associated with
Sjoegren syndrome, ESRD)
Polyuric phase of ATN, post-obstructive natrium polyuria, secondary nephropathies
associated with hyporenin hypoaldosteronism, diuretics
Urinary loss caused by impairment of renal tubular function
Urinary loss caused by endocrinological disorders
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Isotonic dehydration (clinical manifestation is
not apparent until 3-6 l isotonic fluid has been lost !)
Main symptoms ( ECF→hemodynamic : )1. Hypotension (ortostaticá hypotension !)
2. Invisible filling of jugular vein in horizontal position
3. HTC, serum protein, albumin, UA, PUREA (trends !)
4. Central blood pressure
5. BW (BW befor dehydratation has to be known !)
Unspecific symptoms1. Poor skin turgor
2. Sunken eyes
3. Oliguria
4. Absence of axillary sweat
5. Muscle cramps
6. thirst, anorexia
7. apathy, weaknes, confusion
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Differencial diagnosisextrarenal vs renal losses
↓UNa+ < 30 mmol/L
↓EF Na+ < 0.4%
↓EFOsm < 2%
EFH2O < 1%
ABB metabolic acidosismetabolic alcalosis
UK+ > 20 mmol/L
↓EFK+
↑UNa+ > 30 mmol/L
↑EFNa+ > 1.2%
↑EF Osm > 3.5%
↑EF H2O > 2%
ABBmetabolic acidosismetabolic alcalosis
↑↓UK+
↓↑EFK+
Extrarenal (GI) loss Renal loss
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Therapy od isotonic dehydration
1. i.v. substitution of isotonic volume
2. Choice of solute preparation depends on ABB (acidifying solution in pts. withalkalemia; alkalizing solutin in acidemia)
3. Amount of substituted solution and infusionrate depend on clinical status and underlying diseases
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Na+
mmol/lCl-
mmol/lK+
mmol/lCH3COO-
ACETÁTC6H1107GLUKONÁT
C3H5O3LAKTÁT
Plasmalyte 140 98 5 27 23 0
Isolyte 137 110 4 34 0 0
Hartmann 131 111 5 0 0 29
F1/1 154 154 0 0 0 0
Ringer 147 156 4 0 0 0
Solute prepations for for therapyof izotonic dehydratation
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AGENDA• Physiology and pathophysiology of body fluid composition
• Disorders of the internal environment associated with normalECF effective tonicity
Isotonic hypohydrationThird spacingIsotonic hyperhydration
• Disorders of the internal environment associated with abnormalECF effective tonicity
Free water deficitFree water excess
• Differetial diagnosis of hyponatremia
• Differential diagnosis of hypokalemia
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Third spacing
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Isotonic dehydration: sequetration of waterand solutes into the transcelularcompartment
Na + H2O
• Plasma and ECF Na+ concetration isunchanged
• No water transport between ECF a ICF
etiology• Intestinal lumen
• Sepsis: Subcutaneous tissue (edema)
• Muscles (rhabdomyolysis)
• Skin (burns)
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Sequestration of water and solutes into the transcelular compartment(clinical manifestation is not apparent until 2-4 l
isotonic fluid has been retained !)
Clinical manifestation• BW gain• Edema• Dyspnea• Tachycardia• Clinical signes of pulmonary congestion
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Diagnosis and treatment
• Diferencial diagnosis of edematous status
• Treatment of underlying disease
• Volum expansion volume expansion even though the patient is hyperhydratated
• CVVH
• artificial lung ventilation
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AGENDA• Physiology and pathophysiology of body fluid composition
• Disorders of the internal environment associated with normalECF effective tonicity
Isotonic hypohydrationThird spacingIsotonic hyperhydration
• Disorders of the internal environment associated with abnormalECF effective tonicity
Free water deficitFree water excess
• Differetial diagnosis of hyponatremia
• Differential diagnosis of hypokalemia
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Isotonic hyperhydration
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Isotonic hyperhydration : excess of ECF
Na + H2O
• Plasma and ECF Na+ concetration isunchanged
• No water transport between ECF a ICF
etiology• Congestive hard failure
• Anuric renal failure
• Decompensated liver cirhosis
• Nephrotic syndrome
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Isotonic hyperhydration
Clinical manifestation• BW gain• Edema• Dyspnea• Tachycardia• Jugular venous distention• Hepatojugular reflux • Clinical signes of pulmonary congestion
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Diagnosis and treatment
• Diferencial diagnosis of hyperhydration status
• Treatment of underlying disease
• Diuretics (renal excretion = refill)
• CVVH
• Hemodialysis + ultrafiltration
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AGENDA• Physiology and pathophysiology of body fluid composition
• Disorders of the internal environment associated with normalECF effective tonicity
Isotonic hypohydrationThird spacingIsotonic hyperhydration
• Disorders of the internal environment associated with abnormalECF effective tonicity
Free water deficitFree water excess
• Differetial diagnosis of hyponatremia
• Differential diagnosis of hypokalemia
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Free water deficit =
hypertonic dehydration
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Hypertonic dehydration : depletion of free water
H2OH2O
H2O
• Plasma and ECF Na+ concentrationincreasis
• water is transported into ECF • Plasma and ECF K+ concentration
remain stable• Plasma and ECF Cl- concentration
increasis• ABB remain stable
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Hypertonic dehydration: Pathophysiology
• Insufficient oral intake of water (consciousness impairment )
• Decreased reactivity of osmoreceptor
in BG in very old patients
= loss of thirst
• insufficient home care
Auxiliary factors
Fever
Profuse perspiration
Diabetes insipidus
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Hypertonic dehydrationClinical manifestation
• Tremulousnes
• Irritability
• Ataxia
• Spasticity
• Confusion
• Seizures
• Coma
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Hypertonic dehydrationTreatment
• Intravenous 5% glucose infusion until SNa+ has been normalised
• Excesively rapid correction is dangerous !
• Infusion rate has to be so slow that SNa+
decrease das not exceed 0,5 mmol/L per 1 h
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AGENDA• Physiology and pathophysiology of body fluid composition
• Disorders of the internal environment associated with normalECF effective tonicity
Isotonic hypohydrationThird spacingIsotonic hyperhydration
• Disorders of the internal environment associated with abnormalECF effective tonicity
Free water deficitFree water excess
• Differetial diagnosis of hyponatremia
• Differential diagnosis of hypokalemia
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Relative free water excess=
hypotonic dehydration
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Hypotonic dehydration : depletion ofsolutes < depletion of water
ADH
H2O
Free oral water inatake
H2O
PNa+ = ↓Na+
H2O
• Plasma and ECF Na+ concentrationdecreases
• water is transported into ICF • Plasma and ECF concentration K+
can be changed depending on thecause od dehydratation and acid-base disturbances
• Plasma and ECF Cl- concentrationdepends on causes and consequences of isotonic fluid loss
• ABB depends on causes and consequences of isotonic fluid loss
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Patophysiology
Critical ECF volume depletion → ↑ baroreceptor-inducedactivation of ADH in order to maintaine isovolemia →thetonicity decreases
Auxiliary factors
• Free oral water intake
• GI loss of hypotonic fluid
• Farmacologic activation of ADH
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Hypotonic dehydrationClinical manifestation
+
HYPONATREMIA
Main symptoms ( ECF→hemodynamic : )1. Hypotension (ortostaticá hypotension !)
2. Invisible filling of jugular vein in horizontal position
3. HTC, serum protein, albumin (trends !)
4. Central blood pressure
5. BW (BW befor dehydratation has to be known !)
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Hypotonic dehydrationTreatment
• Re-expansion of ECF with isotonic saline
• Infusion rate has to be so slow that plasma Na rise das not exceed 10 mmol/L in 24 h (18 mmol/L in 18 h)
• Correction of underlyiing disorder
• Potassium deficit correction (it contributes to hyponatremia)
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Isolated (absolute)excess of free water
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Euvolemic hyponatremia: absolute excess offree water
↑↑↑ ADH releaze or activity
H2O
H2O
PNa+ = Na+
↑H2O
• Plasma and ECF Na+ concentrationdecreases
• water is transported into ICF
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Euvolemic hyponatremia = absolute free water exces – clinical manifestation
+HYPONATREMIA
Symptoms of brain edema
Severity Symptom
Moderately severe Nausea witout vomitingConfusionHeadache
Sever VomitingCardiorespiratory distressAbnormal and deep somnolenceSeizuresComa (Glasgow Coma Scale ≤ 8)
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Euvolemic hyponatremia = absolutefree water exces – treatment
• Correction of underlyiing disorder
• Infusion of 3% solution NaCl (150 mL/20-20 min)
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AGENDA• Physiology and pathophysiology body fluid composition
• Disorders of the internal environment associated with normalECF effective tonicity
Isotonic hypohydrationThird spacingIsotonic hyperhydration
• Disorders of the internal environment associated with abnormalECF effective tonicity
Free water deficitFree water excess
• Differetial diagnosis of hyponatremia
• Differential diagnosis and treatment of hypokalemia
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AGENDA• Physiology and pathophysiology body fluid composition
• Disorders of the internal environment associated with normalECF effective tonicity
Isotonic hypohydrationThird spacingIsotonic hyperhydration
• Disorders of the internal environment associated with abnormalECF effective tonicity
Free water deficitFree water excess
• Differetial diagnosis of hyponatremia
• Differential diagnosis of hypokalemia
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Disturbances of kalemia
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Kalemia
Internal balance
External balance
ECF ICF
↑pH
pH↓
Intake Excretion
GI Renal
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Hypokalemia (PK+ < 3.8 mmol/L)
Clinical manifestation (PK+ <2.5 mmol/L)• Malaise (nausea)
• Fatigue
• Neuromuscular disturbances (weakness, hyporeflexia, paresthesia, cramps, restless legs syndrome, paralysis, respiratory failure)
• GI symptoms (constipation, ileus, vomiting
• Cardiovascular abnormalities (arrhytmias, ECG changes – T wave flattening, prominent U waves, decreased QRS voltage, ST segment depression)
• Renal abnormalities (urinary concentrating defects, polyuria)
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Hypokalemia
Causes
• Transcelular shift in alkalemia, insulin excess, hypothermia, anabolic states
• Inadequate intake over prolonged period
• Extrarenal losses
• Renal losses
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Hypokalemia
Treatment
Oral therapy (KCl tablet = 13,5 /27 mmol)
Spironolacton
IV administration
7,45% KCl preparation ( 1 mL = 1 mmol)
Periferal vein: Maximal dose 40 mmol in 1000 mLsaline /1 h
Central vein: infusion dispenser 50 mL : 50 mL
7,45 %KCl (1 mL = 1 mmol)
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Hyperkalemia (PK+ >5,3 mmol/L)
Clinical maifestation (PK+ >, mmol/L)
• Neuromuscular manifestation: weakness, paresthesias, areflexia, ascending paralysis
• Cardiac arrhytmias (bradycardia, asystol, prolongation of A-V conduction, A-V block, ventricular fibrilation
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Hyperkalemia
Causes• Redistribution of K+ from ICF to ECF (acidosis, insulin
deficiency, hyperglycemia)• Decreased renal excretion
Acute and chronic oliguric failureImpairment of RAAS (hyporeninemichypoaldosteronism)Decreased aldosteron production (secondary to primary adrenal insufficiency)Impaired response to aldosteron (spironolacton)Inhibition of tubular secretion (Potassium sparing medicaments- amilorid, triamteren; distal renal tubularacidosis
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Hyperkalemia
TreatmentAcute: calcium administration (protect the heart by
antagonizing the K+ effect on A-V conduction)
NaHCO3, insulin, glucose (to shift K+ from ECF to the ICF)
Cation exchange resisns
Hemodialysis
Chronic: treatment od underlying disorder