1. Caroline Straatmann, MD
Renal Emergencies

2. Outline
Potassium
Sodium
Calcium
Magnesium
Hypertension

3. Total Body Water We will start with some basic concepts.
0.6 x weight
1/3 ECF
(Intravascular)
¼ Plasma
¾ Interstitial Fluid
2/3 ICF
We will start with some basic concepts.
Water is distributed between 2 main components: inside the cells and outside the cells
ECF space is about 20% of body’s weight
Interstitial fluid surrounds the cells and has the same components of plasma, but with less protein
Difference between plasma and interstitial fluid is oncotic pressure- the oncotic pressure (proteins) maintains intravascular volume
Plasma UF can accumulate in a “third” space and result in edema, ascites, or pleural effusions.

4. Composition of Electrolytes: ICF and ECF
Intracellular (mEq/L)
Extracellular (mEq/L) Na 20 K
150
3-5 Cl
____
98-110
HCO₃ 10
20-25
PO₄ 5
Protein 75
Electrolytes inside the cell and outside the cell are different.
Sodium and chloride are the predominant ECF electrolytes and are responsible for maintaining ECF volume as opposed to potassium
Potassium and phosphate are principal components of ICF- potassium is primarily intracellular so it is very difficult to estimate total body potassium.

5. Hyperkalemia

6. Case
A 12 year old boy with chronic renal insufficiency secondary to obstructive uropathy is admitted for pancreatitis. He cannot tolerate enteral feeds and is on TPN. He complains of his legs feeling weak. Labs show

7. Case What do you do first? EKG EKG shows peaked T waves
What do you do next?
Give calcium gluconate
Stop his TPN, which has K in it!

8. Case
In addition to this treatment, which one of the following would be the most effective therapy for his hyperkalemia?
Subcutaneous insulin and slow infusion of glucose
Intravenous beta – 2 agonist
Intravenous insulin
Intravenous sodium bicarbonate
Oral sodium polystyrene sulfonate

9. Potassium Growing child requires 1-2 mEq/kg/day
Avoid potassium deficiency
Cellular growth
Serum potassium concentration does not reflect total body potassium content
Ex: Diabetic ketoacidosis
Disturbance in serum K⁺ can affect cell membrane resting potential
Muscle paralysis
Ventricular arrhythmias
Difference between intracellular and extracellular potassium concentrations determines the resting membrane potential of a cell

10. Hyperkalemia Serum K >5 mmol/L (5 meq/L)
Kidney failure is the leading cause
Can be life-threatening due to risk of ventricular arrhythmias
Normal renal response to hyperkalemia
Stimulate aldosterone secretion which then stimulates urinary potassium excretion

11. Hyperkalemia Symptoms Skeletal muscle weakness Paralysis Parasthesias
Respiratory failure

12. Hyperkalemia Decreased renal excretion Common Drugs Increased intake
Reduced GFR
Reduced tubular secretion
Increased intake
Transcellular shifts
Metabolic acidosis
Tumor Lysis Syndrome
Rhabdomyolysis
Aldosterone deficiency or resistance
Common Drugs
Amiloride
Spironolactone
Cyclosporine/Tacrolimus
Heparin
ACE inhibitors/ARBs
Pentamidine
Trimethoprim-Sulfamethoxazole
Rare in individuals with normal renal function
Reduced GFR: Acute/Chronic renal failure
Reduced tubular secretion: Addison’s disease, hypoaldosteronism, potassium sparing diuretics, ACE Inhib, Trimethoprim, Renal tubular acidosis
Increased intake: transfusions, KCl supplementation, sports beverages, IVFs and TPN
Transcellular shifts: Cell destruction-trauma, burns, rhabdomyolysis, hemolysis, tumor lysis, catabolism
Metabolic acidosis- H shifts inside of cell, K shifts out of cells
Aldosterone deficiency: CAH

13. Cells 3 Na 2 K ECF ICF Na= 10 mmol/L K=140 mmol/L Na= 150 mmol/L

14. Hyperkalemia Reason for K to have shifted outside the cells?
K shift to outside the cell after the blood was collected?
Hemolysis
Tissue hypoxia distal to tourniquet
Heel stick
Are the kidneys excreting K appropriately?
GFR
Drugs
Aldosterone
Excessive dietary K intake contributing to the problem?
IVFs and TPN!!!
High potassium foods
Figs, molasses, seaweed, dried fruit, nuts, avacodoes, lima beans, spinach, tomatoes, broccoli, carrots, potatoes, cauliflower, bananas, canteloupe, kiwi, oranges, mangoes, ground beef, steak, pork, veal, lamb

15. Treatment Repeat serum K EKG stat
If EKG shows changes, start treatment immediately
Progression of changes
Peaked T waves-Prolonged PR interval-ST depression-Widened QRS-Ventricular fibrillation

16. Hyperkalemia EKG Changes
Peaked T waves
Loss of P wave
Widening of QRS
ST depression
Prolonged PR interval
Ventricular dysrhythmias
Cardiac arrest
Associated with weakness, parasthesias, tetany
Order of progression although not always dependent on potassium level

17. Treatment 1. Stop K intake 2. Protect myocardium (any EKG changes)
IVFs, TPN
2. Protect myocardium (any EKG changes)
10 % Calcium gluconate infusion
1 ml/kg/dose
3. Shift K into the cells (K>7)
Insulin 0.1 unit/kg/hr with D25W 1-2 mL/kg/hr (15 min)
High dose inhaled beta agonists (albuterol) (30 min)
Na Bicarbonate 1-2 meq/kg IV over 5-10 min (3-4hour)

18. Hyperkalemia Treatment
Eliminate source of potassium intake or offending drugs
K⁺ < 6 mEq/L
Low potassium diet
Diuretics
K⁺ > 6 mEq/L
Cation exchange resin: SPS
TPN and IVF
Kayexalate- exchange resin that binds K in gut
Oral is superior to rectal- takes several hours to work
Dose 1 gram/kg q 4-6 hours

19. Hyperkalemia Treatment
EKG changes = EMERGENCY
Stabilize myocardium
IV calcium chloride or calcium gluconate (10%)
Shift potassium into cells
Beta agonists, insulin/glucose, sodium bicarbonate
Remove excess potassium from the body
Sodium polystyrene sulfonate (SPS)
Furosemide
Hemodialysis
Regardless of potassium value
EKG changes occur individually and cannot be correlated with serum K level
Loop diuretics (only work if good renal function)
Kayexalate- exchange resin that binds K in gut
Oral is superior to rectal- takes several hours to work
Dose 1 gram/kg q 4-6 hours

20. Hypokalemia

21. Hypokalemia Weakness or paralysis Ileus Cardiac dysrhythmias
Delayed depolarization
Flat/absent T waves
U waves

22. Hypokalemia U waves BMP Renin Aldosterone Cortisol Hypernatremia
Alkalosis
Bartter’s
Renin
Aldosterone
Cortisol
Hypernatremia-suggests endocrine cause (increased aldosterone)
Alkalosis-consistent with primary alkalosis or tubular disorder (Bartter’s)
TTKG- Urine/serum potassium divided by urine/serum osmolality
Values range from 1-15
<5: suggestive of low urine losses-not likely the cause of the hypokalemia
>9: suggestive of high urine losses-consistent with a renal origin

23. Hypokalemia Treatment
If > 2.0 mEq/L and no EKG changes, treat orally with KCl, minimum 2 mEq/kg/day
If < 2.0 and/or EKG changes, treat intravenously, with KCl 40 mEq/L into IV fluids
“Potassium runs”: not recommended unless cardiac/ICU patient
Monitor potassium values until normal value is established

24. Hyponatremia

25. Case
A 7 yo male with cystic fibrosis and obstructive lung disease is admitted for a 2 week h/o progressive lethargy. He is obtunded.
Labs: Na=105, K=4, Cl=72, HCO3=21
Plasma osmolality= 222mOsm/kg H20
Urine osmolality= 604 mOsm/kg H20
Urine Na= 78 mEq/L

26. Case What is the most likely diagnosis?
Pseudohyponatremia
SIADH
Psychogenic polydipsia
Hypoaldosteronism
How would you raise the plasma sodium concentration?

27. Osmolality of Body Fluids
Normal= mOsm/kg
Osmotic equilibrium tightly regulated between ECF and ICF compartments
Water moves between compartments in response to alterations in osmolality of either compartment
2 [Na⁺] + [BUN] + [Glucose]
Osmolality is a measure of solute concentration
Kidney produces concentrated or dilute urine in response to changes in osmolality
Estimate plasma osmolality from this equation: 2 times Na represents Na + Cl
90% of your serum osmolality is determined by sodium and chloride
2.8 18

28. Serum osmolality is tightly regulated
Sodium
Serum osmolality is tightly regulated
Sodium is the major determinant of serum osmolality
Sodium balance is regulated by the kidney
Serum sodium does not reflect total body sodium content
Na requirements in growing child
2-3 mEq/kg/day
Since sodium is the main cation of ECF and primary determinant of osmolality, changes in sodium are linked to changes in ECF volume and associated with disorders of water balance
Kidneys defend against changes in ECF volume by modulating sodium reabsportion.
In neonates and growing child, need a positive sodium balance. Otherwise sodium intake equals sodium excretion in a normal kidney at steady state.
Na requirements in growing child with normal renal function- required for growth- more in infants

29. Factitious Hyponatremia
Drawn from an indwelling catheter
Hyperlipidemia
Normal plasma Osm
Hyperglycemia
Drives water into extracellular space, diluting the Na concentration
Plasma osm will be high
Na decreases 1.6 mEq/L for each 100 mg/dL rise in glucose
“Dilutional” effect of glucose: Hyperglycemia increases extracellular osmolality and provides an osmotic force for water to leave the intracellular space for the extracellular space. This results in a decrease in the serum sodium concentration.

30. Hyponatremia Serum Na < 130 mEq/L Loss of sodium Gain of water
Most common cause is intravascular volume depletion from gastroenteritis
After volume expansion, will be able to regulate free water excretion
Loss of sodium in excess of water
Gain of water in excess of sodium
IVVD from dehydration/AGE or decreased effective circulating volume
Cause a decrease in GFR, Proximal tubule increase Na and water reabsorption
Diminished fluid delivery to distal portion of diluting segment and decreased free water excretion
Most common electrolyte disturbance in children

31. Hyponatremia Loss of Sodium
Lose more salt relative to water but still hypovolemic
Hyponatremic dehydration
GI losses (prolonged AGE/hypotonic intake)
Renal losses
Chronic diuretic therapy
Salt wasting nephropathy
Adrenal insufficiency
Skin losses
Cystic fibrosis (hyponatremic/hypochloremic)
Relative water excess
Hypovolemia= loss of salt AND water from ECF

32. Hyponatremia Gain of Water
Hypervolemia
Fluid overload
Congestive heart failure
Water intoxication
Diluted formula
Hypotonic fluids
SIADH
Volume overload- dilutional hyponatremia
Hyponatremia in majority of cases is a reflection of relative water excess
Volume overload and dilutional hyponatremia
Water intoxication: radio contest winner in a water drinking contest who died of cerebral edema

33. Hyponatremia Evaluation
History and Physical
Determine volume status
Estimate sodium intake and output
If hypovolemic:
Renal or Extrarenal losses?
Urine Na⁺
Does kidney respond appropriately to hypovolemia?
Urine specific gravity
Urine osmolality
Physical exam is critical – first step is to determine volume status- hyper or hypovolemic
Urine Na <20mEq/L , <40 in neonate: Extrarenal losses
Urine Na >20 mEq/L, >40 in neonate: Renal losses
High urine sodium: Renal losses: Salt wasting nephropathy, diuretics, adrenal insufficiency
Have to check urine Na NOT on diuretics
If the problem is with the kidney (Na losing nephritis, diuretics, adrenal insufficiency) then the kidney does NOT respond approp to the hypovolemia and instead of a concentrated urine with high SG and osm, it is INAPPROPRIATELY LOW.

34. Treatment Correct underlying cause
Hyponatremic dehydration
SIADH
Fluid restriction (insensible water losses) until Na levels normalize
Rate of correction depends on how quickly it developed
Acute hyponatremia is more dangerous
Increased risk of herniation or apnea from increased ICP from rapid, unbalanced water movement into brain cells
In general, correction with hypertonic saline in unnecessary unless there are neurological manifestations of hyponatremia

35. Treatment Symptomatic Actively seizing or impending resp failure
CNS manifestations, encephalopathic
Use 3% NaCl (513 mEq/L) via infusion pump
1 mL/kg/hr of 3%NaCl will raise serum Na by 1 mEq/L/hr
Continue until patient is alert and seizure free
Na has increased by 20 meq/L or to mEq/L
Actively seizing or impending resp failure
Increase t0 4-8 mL/kg/hr

36. Hyponatremic Dehydration
Sodium deficit (mEq) = Fluid deficit (L) X
0.6 X [Na⁺] in ECF (mEq/L) PLUS
Excess sodium deficit =
(Desired Na⁺ - Actual Na⁺) X (0.6 L/kg) X Wt (kg)
Desired Na⁺ is 135 mEq/L
Maintenance and ongoing losses
Replace over 24 hours
0.6 L/kg= distribution factor as a fraction of body weight
Give one-half replacement over first 8 hours and second half over next 16 hours

37. Hyponatremia
As sOsm falls, water moves into cells, and risk of cerebral edema
If severe (<120 mEq/L), may observe seizures, altered mental status, vomiting
For Na⁺ < 120 mEq/L, raise Na⁺ to 125 mEq/L by giving 3% saline
Rapid correction of hyponatremia : central pontine myelinolysis
Think osmolality- think sodium
Treatment of symptomatic hyponatremia with 2cc/kg bolus of 3% saline over 10 min. Max 100 cc. Repeat 1-2 times as needs until symptoms improve
Rapid correction of hyponatremia- central pontine myelinolysis (rehydration leads to brain dehydration)

38. Hyponatremic Encephalopathy
Early
ADVANCED
Headache
Nausea and vomiting
Lethargy
Weakness
Confusion
Altered consciousness
Agitation
Gait disturbances
Seizures
Coma
Apnea
Pulmonary edema
Decorticate posturing
Dilated pupils
Anisocoria
Papilledema
Cardiac arrhythmias
Central diabetes insipidus
More than 50% of children with serum Na <125 mEq/L will develop hyponatremic encephalopathy due to children’s larger brain to intracranial volume ratio. Children has less room available in their rigid skulls for brain expansion and are likely to develop brain herniation at higher sNa concentration than adults

39. Hyponatremic Encephalopathy
2 ml/kg bolus of 3% NaCl, max 100 ml over 10 min
Repeat 1-2 times until symptoms improve
Goal of correction is 5-6 mEq/L in first 1-2 hours
Recheck sNa q 2 hours
Moritz et al. Pediatr Nephrol (2010) 25:
Stop further therapy when awake, alert, responding to commands, resolution of headache and nausea or acute rise in Na of 10 mEq/L if in first 5 hours
Correction in first 48 hours should not excees mEq/L and should avoid normo- or hypernatremia

40. Acute hyponatremia=Most dangerous
Insufficient Correction
Too aggressive Correction
Cerebral Edema
Demyelination
Acute hyponatremia=Most dangerous
Symptomatic hyponatremia = Medical Emergency

41. Hypernatremia

42. Question
A 9 yr old boy who has cerebral palsy is admitted to CHNOLA following 4 days of diarrhea. His initial serum Na level is 174mEq/L. Once circulatory volume is restored, the primary focus of the fluid management must be to provide appropriate amounts of:
Chloride
Free water
Glucose
Phosphate
Potassium

43. Hypernatremia Serum sodium >150 mEq/L
Always abnormal and should be evaluated
Free water deficit
Increased sodium intake/retention
Increased serum Osm
Does not imply total body sodium overload
As opposed to hyponatremia which can sometimes be normal in certain physiologic states

44. Hypernatremia Rarely develops in those who have access to free water
Most often from inability to access free water
At risk
Ineffective breastfeeding
Critically ill patients
Infants
Neurologically impaired
Body has two defenses to protect against developing hyperNa: ability to prod a concentrated urine (ADH release) and powerful thirst mechanism
Hyperosmolar-induced thirst sensation kicks in and people drink! Returns sOsm to normal

45. Question
Children who have hypernatremic dehydration often appear minimally dehydrated on exam. This is due to maintenance of:
Extracellular fluid volume
Intracellular fluid volume
Total body glucose
Total body sodium concentration
Total body water balance

46. Hypernatremia Water Deficit Renal loss Extrarenal loss Diuretic use
Nephropathy with renal concentrating defect
Diabetes insipidus
Extrarenal loss
Vomiting/Diarrhea
Skin losses
Water deficit=hypernatremic dehydration
Diuresis: osmotic, diuretics, post-obstructive, diuretic phase of ATN
Nephropathy: inability to concentrate the urine in renal dysplasia, obst uropathy, interstitial disease- leads to excess free water loss
GI losses, skin losses

47. Increased Sodium Intake/Retention
Hypernatremia
Increased Sodium Intake/Retention
Salt poisoning
Exogenous sodium
Hypertonic feeding/saline
NaHCO3 administration
Mineralcorticoid excess
Hyperaldosteronism
Very rare
With insufficient free water intake
Salt poisoning

48. Hypernatremia Evaluation
Determine volume status
Blood pressure
Renal water loss
Kidney does not appropriately respond to hypovolemia
Low urine s.g and osmolality
High urine Na⁺
Extrarenal water loss
Kidney responds appropriately to hypovolemia
High urine s.g.
Low urine Na⁺
Compare urine volume with fluid intake
Weight loss: diarrhea
Weight gain: Increased Na retention- hyperaldosteronism
HTN- Hyperaldosteronism
CNS- lethargy, weakness, irritability, seizures, anxiety
Remember skin turgor is well preserved bc it is intracellular water loss
If hypovolemic and most often will be:
Identify cause of water deficit and asses kidney’s response by eval renal conc ability
Urine Osm <800 mOsm/kg in hyperNa is a sign of concentrating defect

49. Hypernatremia Treatment
Treat cause
Correct volume disturbance if present
Replace free water deficit
4mL/kg x (desired change in serum Na (mEq/L))
Risk of cerebral edema from rapid correction
Replace urine volume with hypotonic fluids in addition to deficit
Normal saline first if signs of circulatory collapse
Measure electrolytes q 2 hours until neurologically stable
Oral therapy has less risk of seizures and can tolerate a more rapid rate of correction
Correction rate not to exceed 1mEq/h unless encephalopathic
Do not correct >15mEq/24hr

50. Hypercalcemia

51. Case
A 19yo female with renal failure in in the ER. She c/o polyuria x 6 months and HA and constipation x 6 weeks. She is on HCTZ for HTN. BP is 140/92, P 86
BUN/Cr=61/3
Na=140
Ca=13.8, Ph=3.9, Mg=1.9, Alb=4.2
What do you do next?
Calcitonin
IV saline
Loop diuretics
Surgical consult
Bisphosphonates

52. Hypercalcemia Stones Bones Moans Groans Renal calculi Bone pain
Depression
Groans
Constipation

53. Hypercalcemia Symptoms Differential diagnosis
Weakness, irritability, abdominal cramping, n/v, polyuria, polydipsia, renal stones, pancreatitis, shortened QT interval
Differential diagnosis
Hyperparathyroidism, excessive calcium intake, malignancy, thiazides, prolonged immobilization, sarcoidosis
Polyuria from nephrogenic DI

54. Treatment Most hypercalcemic patients are also volume depleted
Hydration to increase UOP and Ca excretion
NS with potassium at 2-3x maintenance if renal function and BP allow
Forced diuresis
Furosemide
Calcitonin
Bisphosphonates
Dialysis

55. Hypermagnesemia
A 18 month old with ESRD secondary to renal dysplasia on chronic peritoneal dialysis has a serum Mg of He is asymptomatic. All other values are normal except his BUN/Cr.
What is your next step in management?
Change to hemodialysis
Increase phosphate binders
Increase vitamin D
Continue peritoneal dialysis

56. Hypermagnesemia Etiologies Renal failure
Common in CKD due to decreased excretion
Levels in AKI parallel potassium and are derived from the intracellular pool
Rapid cell lysis
Excessive administration

57. Hypermagnesemia Symptoms Rarely of clinical significance Treatment
Decreased DTRs, lethargy, confusion
Hypocalcemia (hypermagnesemia suppresses PTH)
Rarely of clinical significance
Treatment
Stop supplemental Mg
Diuresis
Dialysis

58. Hypertensive Emergencies

59. Case
You are called to the floor at 2 am to see a 16 yo orthopedic post-op patient because his BP is 160/100
What do you do?
A 5 yo boy is brought to the ER because of new-onset generalized seizure which has subsided by the time he arrives. He is postictal with BP of 160/100.
Is this HTN urgency or emergency?

60. Hypertensive Emergency
HTN Emergency is elevated SBP and DBP with acute end-organ damage
Stroke (ischemic/hemorrhagic)
Pulmonary edema
HTN encephalopathy
HTN urgency does not have end organ damage.
HA, Nausea, Blurred vision

61. Hypertensive Emergency
In children, 75% of cases of HTN emergency will be secondary to renal or renovascular causes
What do you need to do before treatment?
Rule out increased ICP as etiology of HTN
Get plasma renin activity level
If the patient is bleeding or coagulopathic, treat the elevated BP urgently
Worry about hemorrhagic stroke

62. Treatment of HTN Emergency
ICU
Don’t lower BP too rapidly
Lower no more than 20-25% in 1st 8 hours
Preserve cerebral perfusion
Acute goal is a mildly elevated BP

63. Case
A 5 yo boy is brought to the ER because of new-onset generalized seizure which has subsided by the time he arrives. He is postictal with BP of 160/100.
What would you start?
What would be your immediate BP goal?
Goal around 130/85 (20% reduction)

64. Treatment of HTN Emergency
Nitroprusside
Arterial and venous vasodilator
Very short-acting
Easily titrated
Cyanide toxicity
Don’t use in renal or liver failure
IV Calcium channel blockers
Nicardipine
Can cause increased ICP

65. HTN Emergency IV Labetalol IV Enalapril (Enalaprilat) IV hydralazine
Alpha and beta blocker: decreases peripheral vascular resistance
Continuous or intermittent dosing
Do not use in asthmatics, lung disease, CHF, diabetics
IV Enalapril (Enalaprilat)
IV hydralazine
Potent arterial vasodilator
Infants

66. On call
You are called to the floor for a 8 yo child with PIGN who is seizing. His BP is 155/98
What do you do for immediate treatment?
IV labetalol bolus dose
Transfer to PICU for nicardipine or labetalol infusion
Goal is to decrease his BP by 20-25% in first 8 hours
What other therapy might be helpful?
Lasix- PIGN is assoc with volume overload

67. HTN Urgency Severe asymptomatic HTN
May have headache
Most commonly due to non-adherence or ingestion of large amounts of salt
Reduce BP over several hours to days
Oral medications

68. HTN Urgency Oral medications Nifedipine Isradipine Labetalol
Short-acting- see effects in min
0.25 mg/kg initial dose
10 mg capsules
Isradipine
Short-acting: effects within one hour
mg/kg/dose
Labetalol
Heart rate is dose limiting factor

69. Thank You