anna, and Dr. Alireza Zahirieh,staff editors
Acronyms
Basic Anatomy Review.
Embryology of theKidney
Renal Structure and Function
Renal Hemodynamics
Assessment of RenalFunction
Measurement of Renal Function
Urinalysis
Urine Microscopy
Urine Biochemistry
Electrolyte Disorders
Sodium Homeostasis
Hyponatremia
Hypernatremia
Diabetes Insipidus
Potassium Homeostasis
Hypokalemia
Hyperkalemia
Hyperphosphatemia
Hypophosphatemia
Hypermagnesemia
Hypomagnesemia
Acid-Base Disorders..
Metabolic Acidosis
Metabolic Alkalosis
Polyuria
Acute KidneyInjury.
Parenchymal Kidney Diseases
Glomerular Diseases
Glomerular Syndromes
Tubulointerstitial Disease
Vascular Diseases of the Kidney
Analgesic Nephropathies
Systemic Disease with Renal Manifestation.
Diabetes
Scleroderma
Multiple Myeloma
Malignancy
Chronic Kidney Disease:
Management of Complications of CKD
Hypertension
Hypertensive Nephrosclerosis
Renovascular Hypertension
Renal Parenchymal Hypertension
Cystic Diseases of theKidney
Adult Polycystic Kidney Disease
Autosomal Recessive Polycystic Kidney Disease
Medullary Sponge Kidney
EndStage Renal Disease.
Presentation of End StageRenal Disease
Renal Replacement Therapy
Dialysis
Renal Transplantation
Common Medications
Landmark Nephrology Trials
References
NP2
....NP2
NP5
NP8
NP17
NP20
NP22
NP33
NP36
NP37
NP38
NP39
NP41
.NP42
n . NP43 L J
.... NP44
NP48
+
XP1 Nephrology Toronto Notes 2023
Activate Windows
Go to Settings to activate Windows.
'
NP2 Nephrology Toronto Notes 2023
Acronyms Pronephros
.§
ACEI angiotensin converting enzyme DIC
inhibitor
ACR albumin to creatinine ratio
ADH antidiuretic hormone
AC anion gap
AIN acute interstitial nephritis
AKI acute kidney injury
ANA antinuclear antibody
ARB angiotensin receptor blocker
ASA acetylsalicylic acid
ASOT anti-streptolysin-0titer
ATN acute tubular necrosis
AV atrioventricular
AVM arteriovenous malformation
c-ANCA cytoplasmic antineutrophil
cytoplasmic antibody
C4S culture and sensitivity
CHF congestive heart failure
CKD chronic kidney disease
creatinine
CrCI creatinine clearance
CV cardiovascular
CVVHD continuous veno- venous
hemodialysis
OSW 5% dextrose in water
OCT distal convoluted tubule
DDAVP 1-desamino-8-d-arginine
vasopressin
Dl diabetes insipidus
disseminated intravascular
coagulation
diabetic ketoacidosis
diabetes mellitus
extracellular fluid
estimated glomerular filtration
e> NS normalsaline a
p- ANCA perinuclear anti-neutrophil
cytoplasmic antibody
PCT proximal convoluted tubule
PJP Pneumocystis jiroveci
pneumonia
PKO polycystic kidney disease
parathyroid hormone
R&M routine and microscopy
RAAS renin-angiotensin-aldosterone
system
RBF renal blood flow
RCC renal cell carcinoma
renal plasma flow
RPGN rapidly progressive
glomerulonephritis
RRT renal replacement therapy
RTA renal tubular acidosis
SIADH syndrome of inappropriate
antidiuretic hormone
SLE systemic lupus erythematosus
SLED sustained low efficiency dialysis
TBW total body water
tubulointerstitial nephritis
TIP thrombotic thrombocytopenic
purpura
UAG urine anion gap
urinary tract infection
-
=
DKA
DM ©
ECF
eGFR
rate
ESR erythrocyte sedimentation rate PTH
ESRD end-stage renal disease
FENa fractional excretion of sodium
filtration fraction
FSGS focalsegmental
glomerulosclerosis
GBM glomerular basement
membrane
GFR glomerular filtration rate
glomerulonephritis
KAART highly active antiretroviral
therapy
HBV hepatitis B virus
HCTZ hydrochlorothiazide
HCV hepatitis C virus
HPF high power field
HSP Henoch-Schonlein purpura
HTN hypertension
HUS hemolytic uremic syndrome
IVP intravenous pyelogram
IOC level of consciousness
MDRD modification of diet in renal
disease
FF
RPF
GN
U
Cr Mesonephros
Degenerating
pronephros
TIN
UTI
Basic Anatomy Review
Embryology of the Kidney
• originatesfrom urogenital ridge of the intermediate mesoderm
• pronephros develops at the end of tvk 3, then degenerates along with adjacent pronephric duct,
disappearing completely by end of wk 4
• mesonephros develops caudal to the pronephros in wk 4,degenerates, and the remnants form the
mesonephric (Wolffian) duct of the male reproductive system
• metanephros develops caudal to the mesonephros in wk 5 from the metanephric blastema and the
ureteric bud of the mesonephric duct,forming the definitive kidney
excretory system:metanephric blastema -» nephrons (Le.glomeruli, Bowmans capsule, PCT, loop
of Henle,OCT)
collecting system:ureteric bud > collecting ducts, calyces, renal pelvis, ureters
• kidneys ascend from the pelvis into the retroperitoneum,gaining a blood supply from the
abdominal aorta to form the renal arteries
=CF
V
Metanephros
Degenerating Renal Structure and Function mesonephros
The Nephron
• basic structural and functional unit of the kidney, approximately 1 million per kidney
• 2 main components:glomerulus and attached renal tubule
• direction of blood flow:afferent arteriole -» glomerular capillaries -> efferent arteriole -> vasa recta (the
capillaries surrounding the tubules) -> renal venules
Metanephric
^
, {Ureteric bud
\j\ephric duct
r n
L
Figure 1. Kidney embryology
The pronephros and mesonephros
develop then degenerate in
succession.Ultimately,the
definitive kidney develops from the
metanephric blastema and ureteric
bud of the mesonephric duct
+
Activate Windows
Goto SetringstoacTivateWindows.
NP3 Nephrology Toronto Notes 2023
Table 1. Major Kidney Functions
Function Mechanism Affected Elements
1.Waste Excretion Glomerular filtration Excretion of nitrogenous products of protein
metabolism (urea.Cr)
Excretion of organic acids( urate) and organic
bases(Cr)
Breakdown and excretion ol drugs (antibiotics,
diuretics) and peptide hormones (most
pituitary hormones, insulin, glucagon )
Controls volume status and osmolar balance
Controls potassium concentration
Acid-base balance
Acid -base balance
Alters Ca 1
\Mg!
\ POrHomeostasis
Increase osmolality ol medullary cytoplasm to
match medullary concentration gradient
Red blood cell production
Calcium homeostasis
lubular secretion
Tubular catabolism
2.Electrolyte Balance and Osmoregulation lubular NaCI and water reabsorplion
Tubular K’secretion
Tubular H Secretion
HCOrsynthesis and reabsorplion
TubularCaT*
. Mij'
, POP transport
Osmolytc synthesis
3. HormonalSynthesis Erythropoietin production (cortex)
Vitamin 0 activation: 25|OH|Vitamin 0
converted to1.2S(0H):Vitamin D (proximal
tubule)
Renin production ( juxtaglomerular apparatus) Alters vascular resistance and aldosterone
secretion
Alters ECF volume
Alters vascular resistance
4. Blood Pressure Regulation Na* excretion
Renin production
Gluconeogenesis (Irom lactate, pyruvate, and Glucose supply maintained in prolonged
amino acids) starvation
Clearance and degradation ol circulating Maintains glucose homeostasis
insulin
5. Glucose Homeostasis
The Glomerulus
• site where blood constituents are filtered through to the kidney tubules for excretion or reabsorption
• filtration occurs across the glomerular filtration barrier (endothelium, GBM, podoevtes) into
Bowman’sspace
• there is a filtration barrier to albumin due to its size and negative charge, which is repelled by the
negatively-charged GBM
• consists of following cell types:
I . mesangial cells
structural function:support glomerular capillaries; can alter GI R through contractile
activity
• secretory function: matrix components, pro- and anti-inflammatory cytokines, and
chemokines
secretions are responsible for minimizing the accumulation of macromolecules in the
mesangial space and GBM
2. capillary endothelial cells
part of the glomerular filtration barrier; help form the plasma filtration apparatus due to their
fenestrated nature and glycocalyx; contribute to the production of the GBM
interface with blood - target for antibodies and contact site for neutrophils and lymphocytes
3. visceral cells (podocytes)
part of the glomerular filtration barrier; helps form the plasma filtration apparatus due to
their interdigitated foot process forming slit diaphragms; contribute to the production of
extracellular matrix proteins (collagen and laminin) making up the GBM
4. parietal cells
lines the interior of Bowmans capsule and contains a podocyte progenitor population
5. juxtaglomerular cells
smooth muscle cells in lining of afferent arteriole; produce,store, and secrete renin
r T
i j
+
Activate Windows
Go to Settings to activate Windows.
NPl Nephrology Toronto Notes 2023
Afferent arteriole
Renal Hemodynamic Parameters
RBF - 20% olCO,
-U/mln
RPF - RBF'II-Hct)
GFR --120 tnL/min in healtliy adult
199% ol this volume is reabsorbed)
FF - GFR/RPF (normally 20%)
Prostaglandins -dilation NSAIOs - constriction
Efferent arteriole
ACEI- dilation AngiotensinII- constriction
Afferent arteriole
M
Bowman's space
.
1
'
J 1
Proximal
t. tubule
Juxtaglomerular^- »
cells A •1».
-
,
j
Efferent arteriole
Endothelium -
Mesangial cell 2
8
%
Podocyte
(visceral epithelium) Bowman's capsule S
(parietal epithelium)
Figure 2. The glomerulus
The Renal Tubules
• reabsorption and secretion occur between the renal tubules and vasa recta forming urine for excretion
• each segment of the tubule selectively transports varioussolutes and water and is targeted by specific
diuretics
rg ACTIVE
|requ
*
es ATRI
(B) PARACEILUIAR
QL REGULATED,hormone
^^
(e.g. angiotensin II,aid.ANF)
C) H?0 PERMEABLE segment
^
HjO IMPERMEABLE segment
0 «
^
ang.II
NaVH'
exchange
Na /PO.* co-transport
(PTH a vitamin Dl NaCI S%
Na’
/K- i.r
- n -
-
r
INa* 80%)
K' Na'
i HiO
£
A
Glucose 90V:
Ammo acids 90%
HCO, 90%
— HCOi K'
2 H’ Na' Ca'
- HWU t
O
£ H.O 80%
o
rv ^
aldosterone 2
L
I
PROXIMAL Na*
TUBULE
Osmotic diuretics
DISTAL TUBULE
O Thetide diuretics K- \
ENaC channels <
No' 10% K- - 2CI
(ADH) co-transport
THICK ASCINOINC UMS
(loop olHeal#}
Loop diuretics
e
3 u
^
AOPIbyADH
ADH receptor
'
ADH
=: s &
( Ca1,
- MQ1
,
® \/
a I
$ COLLECTING DUCT %tpifHigdniitbci a.
§
AQP chnnnol i
I
H,0
2 A 2J :* •
DESCENDING THIN LIMB
(loop ol Nonlo)
ASCENDING THIN LIMB
(loop ol Honlol
Loop d/wetict,
syntonises osmolytes.
impermeable to Hi 0
§
6
3
£ B
L.
Figure 3. Tubular segments of the nephron
+
Activate Windows
Go to Settings to activate Windows.
XP5 Nephrology Toronto Notes 2023
Renal Hemodynamics
• GIR
GFR is the rate of fluid transfer between glomerular capillaries and Bowman'
s space, expressed as
9
the sum of the filtration across all nephrons
average GFR of 180 L/d or 125 mL/min/1.73 m of which 99% of the filtrate is reabsorbed
normal urine output is 0.5-2.0 mL/kg/h in adults
• Cil'
R is highest in early adulthood, and decreases thereafter starting around age 40
• renal autoregulation maintains constant Cil'
R over mean arterial pressures of 70- 180 mrnHg
• 2 mechanisms of autoregulation to maintain Cil'
R homeostasis:
myogenic mechanism: release of vasoactive factors in response to changes in perfusion pressure
(e.g. low Cil'
R > decreased perfusion pressure > release of prostaglandin > afferent arteriolar
dilation > increased Gl-
'
R)
tubuloglomerular feedback: changes in Na ' delivery to macula densa lead to changes in afferent
arteriolar tone (e.g. high Cil'
R > increased Na 'delivery > afferent constriction > decreased GFR )
• filtration fraction
• percentage of RPF filtered across the glomeruli
expressed as a ratio: IT'
= GFR/RPF; normal = 0.2 or 20%
• angiotensin If constricts renal efferent arterioles which increases IT, thereby maintaining Cil'
R
• renin is released from juxtaglomerular apparatus in response to low Na 'delivery to the macula densa,
which is an indicator of decreased RPF
renin is an important enzyme in the RAAS pathway, that converts angiotensinogen to
angiotensin 1
Glometular Filtration Rate
GFR Kf|iP- 6(1)
ultrafillration coefficient
hydrostatic pressure difference
between glomerular capillaries
andBowman'sspacc
60 osmotic pressure difference
between glomerular caplllatlcs
and Bowman'
sspace
6P - 411 net outward pressure
XI
6P
Considerable variation in GFR is
observed based on age. biological sex,
ethnicity and BMI
Stimuli for Renin Release
from Kidney:
1.Renal artery
hypotension:1in stretch
of afferent arteriole
2.Sympathetic activation
(via juxtaglomerular cell
Adrenergic receptors)
3. INa delivery to macula
densa in OCT
Angiotensin II Effects:
1.Vasoconstriction
2. T vascular smooth
muscle growth
3.t Na * reabsorption
4. T aldosterone
5. T bicarbonate products
Angiotensinogen
Renin
Angiotensin Angiotensin II I
Adrenal cortex
Stimulation of Na -
retention in the
kidney
Aldosterone Clincically relevant
outcomes:
1. Net T total body water,
sodium
2. t vascular tone
Vasoconstriction
Via angiotensin II receptors 0-»o
1
Thirst
'
t systemic blood Hypothalamus
volume and pressure
t Fluid intake
Postorior pituitary g
—————————I
'Aloxondro Ho 2022 aftor Francos Young 2005. Nicola Clough 2014
ADH release
Figure 4. Renin-angiotensin-aldosterone system
Assessment of Renal Function
Measurement of Renal Function
• most renal functions decline in parallel with a decrease in GFR
• inulin clearance and iothalamate radiotracer are the gold standard for measuring GFR, but very rarely
used clinically
• clinically, GFR is estimated using serum creatinine concentration, [Cr], known as eGFR
Cr filtered = Cr excreted (atsteady state)
Cr reasonably estimates GFR asit isfreely filtered at the glomerulus with little tubular
reabsorption
Crfiltered -Crexcreted
[Cr]plasma x GFR -[Cr]urine x urine flow
rate (mL/min)
GFR ~
Cr'
urme x urine flow rate
[Cr]plasma
r i
L j
+
Activate Windows
Go to Settings to activate Windows.
XP6 Nephrology Toronto Notes 2023
however,Cr is a metabolite of creatine phosphate, and therefore increased muscle mass increases
Cr production. Ihus,one needs to consider body mass, ethnicity, age, and biological sex when
determining eGT'
R
there is also 10% to >50% tubular secretion of Cr, depending on renal function
• newly discovered biomarkers such as Cystatin C, which are not affected by muscle mass, may provide
more accurate eGFR values
At steady state[Cr]serum a1/CrCI
Ways to Estimate GFR Using Serum Creatinine Concentration
1.estimate GFR using CKD-EP1 equation
• the best current and most accurate equation
calculated using serum Cr, age, biological sex, and race
overestimates Gl-R, resulting in lower prevalence of CKD diagnoses when used instead of MDRD
formula or Cockcroft-Gault equation
2. measure CrCl- 24 h urine collection
calculation provides reasonable estimate of GFR
Gl-R/d = (urine|Cr] x 24 h urine volume)/(plasma (Cr])
must use same unitsfor urine [Cr] and plasma [Cr]
3.estimate GFR with new Cr and cystatin C-based equations
serum Cr and cystatin C values used with age and sex to estimate GFR (excludes the race variable)
• more accurate than CKD-EPI with race omitted
CKD-EPI Equation
eGFR (ml/min/1.73 m*) -141*minfSCr/n.
1)a x max(SCr/K.1)
“
<» x 0.993age
x (1.018 if female) x (1.159 for Black
individuals)
(SCr] measured in mg/dl;1mg/dL (Cr]-
88.4 pmol/L
K *0.7 tor females and 0.9 for males
a - 0.329 for females and -0.411 for
males
mln/max indicates the minimum/
maximum of SCr/x or 1
Cystatin C
Cystatin C is a renal biomarker shown
to be potentially superior to scrum Cr
In determining eGFR and delecting
impaired filtration rate . However, its
clinical use remains limited pending
Increased adoption and testing
availability
Limitations of Using Serum Cr Measurements
1. must be in steady state
constant GFR and rate of production of Cr from muscles
sudden injury (e.g. AKI) may reduce GFR substantially, however,serum Cr will not immediately
reflect sudden reduction in Gl'
R until new Cr steady state is reached
2.GFR must fall substantially before plasma [Cr] rises above normal laboratory range
with progressive renal failure, remaining nephrons compensate with hyperfiltration
• GFR is relatively preserved despite significant structural damage
3. plasma [Cr] is influenced by the rate of Cr production
• lower production with smaller muscle mass (e.g. female, elderly, low weight)
• e.g. consider plasma|Cr] of 100 pmol/L in both of these patients
- 20 yr lean man who weighs 100 kg, GFR = 144 mL/rnin
- 80 yr woman who weighs 50 kg, GFR = 30.6 mL/min
clinical correlation:GFR decreases with age but would not be reflected as a rise in serum Cr due to
the age-associated decline in muscle mass
4.tubular secretion of Cr increases as GFR decreases
• serum Cr and CrCl overestimate low GFR
• certain drugs (cimetidine,trimethoprim) interfere with Cr secretion
5.errorsin Cr measurement
• very high bilirubin level causes [Cr] to be falsely low
• acetoacetate (a ketone body) and certain drugs(cefoxitin) create falsely high [Cr]
Clinical Settings in which Urea Level
is Affected Independent of Renal
Function
Disproportionately High Urea
. Volume depletion (prerenal azotemia)
• Gl hemorrhage
• High protein diet
• Sepsis
• Catabolic state with tissue
breakdown
• Corticosteroid or cytotoxic agents
Disproportionately Low Urea
• Low protein diet
Measurement of Urea Concentration • Liver disease
• urea isthe major end-product of protein metabolism
• plasma urea concentration reflects renal function but should not be used alone as it is modified by a
variety of other factors
• urea production reflects dietary intake of protein and catabolic rate;increased protein intake or
catabolism (sepsis, trauma, Gl bleed) causes increase in urea level
• ECF volume depletion causes a rise in urea independent of GFR or plasma [Cr]
• in addition to filtration, a significant amount of urea is reabsorbed along the tubule
• reabsorption isincreased in hypernatremic states
• typical ratio of urea to [Cr] in serum is 1:12 in SI units(using mmol/L for urea and pmol/L for Cr)
Estimating Urine Osmolality
Last 2digits of the specific gravity x 30 -
urine osmolality appro ximately
(e.g.specific gravity of 1.020=600
mOsm)
Urinalysis
•use dipstick in freshly voided urine specimen to assess the following:
1. Specific Gravity
•ratio of the mass of equal volumes of urine/H20
•range is 1.001-1.030
•values <1.010 reflect dilute urine, values >1.020 reflect concentrated urine
•value usually 1.010 (isosthenuria:same specific gravity as plasma) in ESRD
n
u
2. pH
•urine pH is normally between 4.5-7.0; if persistently alkaline, consider
• RTA (types 1-1V)
UT1with urease-producing bacteria (e.g. Proteus)
+
Activate Windows
Go to Settingsto'
activate'
Window*
NP7 Nephrology Toronto Notes 2023
3.Glucose
• freely filtered at glomerulus and reabsorbed in proximal tubule
• causes of glycosuria include:
1.hyperglycemia >9-11.1 mmol/L leadsto filtration that exceeds tubular resorption capacity
2.increased GT'
R (e.g. pregnancy: the proximal convoluted tubule is unable to reabsorb the glucose
and amino acids)
3.proximal tubule dysfunction (e.g. laneoni
’ssyndrome)
4.sodium-glucose cotransporter 2 (SGLT2) inhibitors (i.e.-flozin drugs) which are prescribed for
DM2;lower the threshold for glucosuria by preventing glucose reabsorption from the filtrate
4. Protein
• dipstick only detects albumin; other proteins (e.g. Bence-|ones, Ig,Tamm-Horsfall) maybe missed
• microalbuminuria (morning ACR of 2.0 - 20 mg/mmol) is not detected by standard dipstick; greater
than these ranges would be macroalbuminuria
• gold standard: 24 h timed urine collection for total protein
24 h Urine Collection
• Discard first morning specimen
• Collect allsu bsequent urine for the
next 24 h
• Refrigerate between voids
• Collect second morning specimen
5. Leukocyte Esterase
• enzyme found in VVBC and detected by dipstick
• presence of W BGs indicates infection (e.g. U IT) or inflammation along the urinary tract including
prostate, bladder, ureter, pelvis, and interstitium (e.g. AIN)
Positive dipstick for leukocyte esterase
and nitritesis highly specific for
diagnosing a UTI
6. Nitrites
• endogenous nitrates in urine are converted to nitrites by some bacteria (most commonly £. coli)
• high specificity but low sensitivity for UTI
7. Ketones
• positive in alcoholic/diabetic ketoacidosis, prolonged starvation, fasting
8. Hemoglobin
• positive in hemoglobinuria (hemolysis), myoglobinuria (rhabdomyolysis), and true hematuria ( KBCs
seen on microscopy)
Nitrite Negative Bacteria
Enterococci
Staphylococci
Nitrite Positive Bacteria
Enterobacterioceoe (e.g.f. coli)
Urine Microscopy
Table 2. Comparison of Urinary Sediment Findings
Active Sediment - Suggestive of
Parenchymal Kidney Disease
Bland Sediment * Less Likely
Parenchymal Kidney Disease
Any one or more of the
following seenon microscopy
Red cell casts
White cell casts
Only hyaline casts
Small quantities ol crystals
Muddy-brown granular or epithelial ceil casts Small amount olbacteria
<2 red cells per HPF
<4 white cells per HPF
>2red cells per HPF
»4 while cells per HPF
1. CELLS
Erythrocytes
. hematuria >2 RBCs per HPT
• dysmorphic RBCs and/or RBC castssuggest glomerular bleeding (e.g. proliferative GN)
• isomorphic RBCs or no castssuggest extraglomerular bleeding (e.g. bladder cancer)
Leukocytes
• pyuria = greater than upper limit of normal:>4 WBCs per HPT
• indicatesinflammation or infection
• if persistentsterile pyuria present (i.e.negative culture), consider: chronic urethritis, prostatitis,
interstitial nephritis, calculi, allergic cystitis,interstitial cystitis, papillary necrosis, renal
tuberculosis, viral infections, N. gonorrhoeae,C. trachomatis infection
Eosinophils
• detected using Wright’s or Hansel’s stain (not affected by urine pH)
• consider AIN, atheroembolic disease
n
L J
Oval Fat Bodies
• renal tubular cells filled with lipid droplets
• seen in heavy proteinuria (e.g. nephrotic syndrome)
2. CASTS +
• cylindrical structuresformed by intratubular precipitation of Tamm-Horsfall mucoprotein; cells may
be trapped within the matrix of protein
Activate Windows
Goto Settrngrto activate Wii
NP8 Nephrology Toronto Notes 2023
Table 3. Interpretation of Casts
Casts Interpretation
Hyaline Costs
RBC Costs
WBC Casts
Physiologic (concontialotl urine,lever,exercise)
Glomerular bleeding (prolilerative GH,vasculitis)
Inlection (pyelonephritis)
Inflammation (interstitial nephritis)
Pigmented GranularCasts (heme granular casts,muddy brown) AIN
Acute proliferative GN
Fatty Casts Nephrotic syndrome (proteinuria >3.5 g/d)
3. CRYSTALS
• uric acid:consider acidic urine, hyperuricosuria,tumour lysissyndrome
• calcium phosphate:alkaline urine
• calcium oxalate:consider hyperoxaluria,ethylene glycol poisoning, nephrolithiasis
• sulfur:sulfa-containing antibiotics
Urine Biochemistry
• commonly measure: Na 1 , K\C1-, osmolality, and pH
• spot urine more useful to assess renal physiology, 24 h urine collection more reflective of mineral
balance
• no “normal ” values; electrolyte excretion depends on intake and current physiological state
• results must he interpreted in the context of a patient'
s current state, for example:
1.ECF volume depletion: expect low urine ( Na* ) (kidneys should be retaining Na *)
urine [Na 1
) >20 mmol/L suggests a renal problem or the action of a diuretic
urine [ Na 1 j <20 mmol/L suggests a prerenal problem
2.daily urinary potassium excretion rate should be decreased (<20 mmol/d) in hypokalemia
if higher than 20 mmol/d,suggests renal contribution to hypokalemia
• osmolality is useful to estimate the kidney’
s concentrating ability
• FENa refers to the fractional excretion of Na+ (Na excreted in urine/Na filtered through kidney)
l-
'
ENa <1% suggests the pathology is prerenal
• urine pH is useful to grossly assess renal acidification
low pH (<5.5) in the presence of low serum pH is an appropriate renal response
• a high pH in thissetting might indicate a renal acidification defect (e.g. RTA Type I)
Fractional Excretion of Sodium
FENa *
[Na
*
] urine X [Ct]plasmn
[Na plasma X [Cr]urine X 100 *
]
Electrolyte Disorders
Sodium Homeostasis
• hyponatremia and hypernatremia are disorders of water balance
hyponatremia usually suggests too much
hypernatremia usually suggests too little water in the ECF relative to Na < content
• solutes (such as N a ' , K , glucose) that cannot freely traverse the plasma membrane contribute to
effective osmolality and induce transcellularshifts of water
water moves out of cells in response to increased ECF osmolality
water moves into cells in response to decreased ECF osmolality
• ECF volume is determined by Na+content rather than concentration
Na deficiency leadsto ECF volume contraction
Na +excessleads to ECF volume expansion
• clinical signs and symptoms of hyponatremia and hypernatremia are secondary to cells (especially
brain cells) shrinking (hypernatremia) orswelling (hyponatremia)
water in the ECF relative to Na 'content
r
c
+
Activate Windows
Go to Settings to activate Windows.
XP9 Nephrology Toronto Notes 2023
Table 4. Clinical Assessment of ECF Volume- (Total Body Na-)
Fluid Compartment Hypovolemic Hypervolemic
Intravascular
Increased
Normal lo increased
JVP Decreased
Orlhostalic drop
Tachycardia
Normal
8lood pressure
Auscultation ol heart
Auscultation ol lungs
Interstitial
Shin turgor
Edema (dependent)
Other
Urine output
8ody weight
Hematocrit,serum protein
Urine sodium
IVC sire
IVC collapse oninspiration
S3
Inspiratory crackles
Decreased
Absent
Normal/increased
Present
Decreased"
Decreased
Increased
IncreasedlDecreased'"
<2.1cm
>50%
Variable
Increased
Decreased
Decreased
>2.1cm
<50%
'Refers to effective circulating volume (ECV). which is the ECF volumeadequately perfusing tissues
"It there is arenal abnormality (e.g.osmotic diuresis),the urineoutput may beincreased despite the presenceot hypovolemia
'"Inhypovolemia,urine sodium can beIncreased due torenallosses,or decreased due to extra-renal losses
'"’IVC ultrasound during respiration assesses central venous pressure/right atrial pressure;lung ultrasound lor B-liries can alsobe used lor
assessment ot pulmonary congestion
Hyponatremia
Definition
• serum [Na +
J <135 mmol/L
• can be associated with hypo-osmolality (most common), iso-osmolality, or hyperosmolality
• consider if it is associated with “appropriate” (hypovolemia) vs. “inappropriate” (euvolemia) ADH
secretion
• if appropriate ADH secretion, is it real vs. effective volume loss?
If the urine osmolality is unknown,
assume the urine is hypo-osmolar/dilute
[ Hyponatremia )
Iso-Osmolar
1280-295 mOsm/kg)
• Retenbon inECF ol large volumes
ol isotonic fluids that do not
contain sodium (e g. mannitol)
• Pseudohyponatremia -lab artifact
seen wtUi severe hyperlipidemia
or paraproteinemia (e g. multiple
myeloma)
Hypo-Osmolar (dilutional)
(<280 mOsnVkg)
• Most common cause of
hyponatremia
• Excess water in relation lo
sodium stores which can be
decreased,normal, or increased
• Categorized by volume status
as determined by clinical
assessment
Hyper-Osmolar (Iranslocalional)
(>295 mOsm/kg)
•Extra osmoles in ECF draw
water out ot cells diluting die
Na 'in ECF
•Usually glucose (rarely
hypertonic mannitol)
•Every 10 mmol/Lincrease in
blood glucose results in
3 mmol/L decrease inNa '
i T
Euvolemic
U„,„>100
• SIADH (normal UNa)
• Adrenal insufficiency
• Hypothyroidism
Hypovolemic
Uu >20
• Diuretics (especially thiazides)
• Salt-wasting nephropathy
Hypervolemic
U„<20 and Feu<1% (renal losses)
• CHF
• Cirrhosis and ascites
• Nephrotic syndrome
• Pregnancy Hi,
<10 and Feu <1% (extra-renal losses)
• Diarrhea
• Excessive sweating
• Third spacing (e.g. peritonitis,
pancreatitis,burnsl
Uo,
*
<100
•Psychogenic polydipsia
•Low solute -
"
tea & toast"
l
)„>20 and Fe
-
,,>1% (renal losses)
• AKI.CKD
Figure 5. Approach to hyponatremia
Signs and Symptoms
• depend on degree of hyponatremia and. more importantly, velocity of progression from onset
• hyponatremia = swollen cells
• acute hyponatremia (<24-48 h) more likely to be symptomatic
• chronic hyponatremia (>24- 48 h ) less likely to be symptomatic due to adaptation
• adaptation: normalization of brain volume through loss of cellular electrolytes (within hours) and
organic osmolytes (within days)
• neurologic symptoms predominate (secondary to cerebral edema ): headache, nausea,malaise,
lethargy, weakness, muscle cramps, anorexia,somnolence, disorientation, personality changes,
depressed reflexes, decreased LOC
Symptoms of Central Pontine
Myelinolysis
• Cranial nerve palsies
• Ouadriplegia
. Decreased LOC
ri
+
Complications
• cerebral edema and increased intracranial pressure resulting in nausea, headaches, decreased LOC,
seizures,coma, brain herniation, and death
Activate Windows
Go to Settings to activate Windows.
NP10 Nephrology Toronto Notes 2023
•risk of brain cell shrinkage with rapid correction of hyponatremia
• can develop osmotic demyelination of pontine and extrapontine neurons; may be irreversible (e.g.
central pontine inyelinolysis)
symptom onset may be delayed 2-6 d; begins as dysarthria, dysphagia, paresis, movement
disorders -> later on seizures,lethargy, confusion, disorientation, obtundation, coma
Risk Factorsfor Osmotic Demyelination
« low serum [Na '
] of <115 mmol/L at presentation and/or duration of hyponatremia >2 d
•associated hypokalemia,malnutrition, liver disease, alcoholism
•overly rapid correction of|Na '
), i.e. rise in|Na *|>8 mmol/L/24 h if chronic hyponatremia,e.g.:
inappropriate sodium replacement
suppression of ADH by restoring euvolemia with isotonic fluid, or by stopping a reversible
stimulus of SIADH (organic disorders; medications e.g. SSKIs; limbic system activation e.g.
nausea, pain,surgical stress;see 'Table 5, N P I I )
discontinuation of thiazides; depriving water in patient with psychogenic polydipsia
Investigations for Hyponatremia
• EC1-
'
volume status assessment (see Table 4, NP9)
• serum electrolytes,glucose, Cr
• serum osmolality, urine osmolality
• urine Na +(urine Na +<10-20 mmol/L suggests volume depletion asthe cause of hyponatremia)
• assess for causes of S1ADH (see Table 5)
• TSH, free T4, and cortisol levels
• consider CXR and possibly CT chest ifsuspect pulmonary cause of SIADH (e.g. paraneoplastic
syndrome by small cell lung cancer)
• consider CT head ifsuspect CNS cause of SIADH (i.e.subarachnoid hemorrhage)
Treatment of Hyponatremia
• general measures for all patients
1.treat underlying cause (e.g. restore ECE volume if volume depleted, remove offending drug, treat
pain, nausea,etc.)
2.restrict free water intake in S1ADH (<1000 mL/d)
3.promote free water loss
4.carefully monitorserum Na+, urine volume,and urine tonicity
5.monitor frequently that correction is not too rapid
• monitor urine output frequently:high output of dilute urine is the first sign of dangerously rapid
correction of hyponatremia as the stimulus for ADH is diminished with the correction of hypovolemia
A. Known Acute (known to have developed over <24-48 h)
• commonly occurs in hospital (dilute IV fluid, postoperative increased ADH)
• less risk from rapid correction since adaptation has not fully occurred
• if symptomatic
correct rapidly with 3% NaCl at 1-2 cc/kg/h up to serum|Na t
| 125-130 mmol/L
may need furosemide to address volume overload
• if asymptomatic, treatment depends on presence of risk factorsfor ODS
goal is to promote a negative balance of free water
restrict free water intake
promote free water loss by administration of furosemide with salt tablets, oral urea, or
vasopressin receptor 2 antagonists (e.g. tolvaptan)
if ODS risk factors present, aim to correctserum sodium more slowly
do not give 3% NaCl if hyponatremia is autocorrecting due to water diuresis
B.Chronic or Unknown
1.ifsevere symptoms(seizures or decreased LOC)
must partially correct acutely
aim for increase of Na 1by 0.5-1 mmol/L/h for 4-6 h
limit total rise to 8 mmol/L in 24 h
• IV 3% NaCl at 1 -2 cc/kg/h
may need furosemide
2.ifasymptomatic
water restrict to <1 L/d fluid intake
• consider IV 0.9% NS + furosemide (reduces urine osmolality, augments excretion of H’
O)
consider NaCl tablets as a source of Na +
3.refractory
furosemide and oral salt tablets
oral urea (osmotic aquaresis)
vasopressin receptor 2 antagonists (e.g. tolvaptan)
4.always pay attention to patient’s ECE volume status-if already volume-expanded, usually don't give
NaCl (tablet or IV); if already volume-depleted, almost never appropriate to give furosemide
C.Options for Treatment of Ovcrly-Rapid Correction
• give water (IV D5W)
• give ADH to stop water diuresis(DDAVP 1-2 pg IV )
<8>
Beware of Rapid Correction of
Hyponatremia
• Rapid correction of hyponatremia
can occur inadvertently, commonly
after stopping a reversible secondary
cause of SIADH.e.g.:
• Patient with SIADH secondary to
nausea is given an anti
-emetic
• Resolution of nausea causes a rapid
cessation of SIADH. leading to renal
excretion of excess water and rapid
increase in serum [Na+]
• Patient at risk of osmotic
demyelination
• High output dilute urine (>100 cc/h.
<100 mOsm/L) in the setting of
hyponatremia is usually the first sign
of dangerously rapid correction of
serum sodium
Correction of Na in hyponatremia
should not exceed 8mmol/L/24 h
unless definitely known to be <24-48 h
duration:frequent monitoring of serum
Na+ and urine output is essential
0
Concentration of|Na •) in Common
Infusates
. (Na ) in 0.45% NaCl- 77 mmol/L
. [Na 1
] in 0.9% NaCl
-154 mmol/L
. [Na '
] in 3% NaCl- 513 mmol/L
. [Na ] in 5% NaCl-855 mmol/L
. [Na *
] in Ringer'
slactate
-130 mmol/L
. [Na *]inD5W- 0
Impact of IV'Solution on Serum|Na '] +
• formula to estimate the change in serum [Na+] caused by retention of 1 L of any infusate
• [TBW = (for men) 0.6 x weight(kg);(for women) 0.5 x weight(kg)]
Activate Windows
Go to Settii a activate Windows:
XPl 1 Nephrology Toronto Notes 2023
SYNDROME OF INAPPROPRIATE ANTIDIURETIC HORMONE SECRETION
1. urine that is inappropriately concentrated for the serum osmolality
2. urine sodium >20-40 mmol/L -likely reflecting euvolemia
3. I
'
ENI >1%
Table 5. Disorders Associated with SIADH
Cancer Pulmonary CNS Drugs Miscellaneous
Small cell cancer
Bronchogenic carcinoma
Pancreatic
adenocarcinoma
Hodgkin'
s lymphoma
thymoma
leukemia
Pneumonia
Lung abscess
tuberculosis
Acute respiratory failure
Asthma
COPD
Positive pressure
ventilation
Hass lesion Postoperative state
Encephalitis
Subarachnoid hemorrhage SSBIs
Stroke
Head trauma
Acute psychosis
Acute intermittent
porphyria
Antidepressants
ICAs Pam
Severe nausea
Antineoplastics
Vincristine
HIV
Cyclophosphamide
Anti-epileptics
Carbamacepme
Barbiturates
Chlorpropamide
ACll
Other
DDAV7
Oxytocin
Nicotine H2O Deficit and TBW Equations
TBW - 0.6 x wt (kg) men
TBW - 0.5 *
wt (kg) women
Hypernatremia HiO deficit- TBW x ffNar]plasma140) / 140
Definition
• serum [Na +
] >145 mmol/L
• too little water relative to total body Na always a hyperosmolar state
• usually due to NL I water loss or insufficient intake, rarely due to hypertonic Na '
gain
• less common than hyponatremia because patients are protected against hypernatremia by thirst and
release of ADH
Correction of serum [Nr] in
hypernatremia should not exceed 12
mmol/L/24 h
Hypernatremia
I
1 L D5W approximately equals 1L of
free water
1 L 0.45% NS approximately equals 500
mL of free water Reduced Intake
1
• Elderly (dementia, swallowing
difficulty, stroke,bed-bound)
• Infant
• Coma
Surgical
Increased Losses
(without adequate intake)
Outcomes in Severe Hyponatremia Treated With
and Without Desmopressin
Am J Med 2018;131:1-317
Purpose:Rapid overcorrection of plasma Na
- in severe hyponatremia can lead to osmotic
demyelinabiM syndrome.IhisStudyseekstocom pare
outcomesin hyponatremia based on OOAVP usage
in treatment.
Methods: Retrospective study including all
admissions to internal medicine with hyponatremia
(plasma Na
-
<123 m£q/|L from 2004 to 2014 at 2
Toronto hospitals. Ihe primary outcome wassafe
Na
-
correction («12 mfq/lin any 24 h period and
<18 mlqJl in any 48 h periodl,lime lo reach Na-
>130 mEgflor hospital discharge. 0D4VP uses
were excluded lor 01 and for bleeding prevention in
thrpmbocytopenra.
Results: Among 1450 admissiors of 1274 patients(or
hyponatremia over the10 yr period, desmopressin
was administered in 284 admissions(17.5%).
fewer patientsreceiving OOAVP achieved safe Na -
correction within Ihe 24 h lime frame (70.0% vs.
85%:P<0.001). Ihe proportion of cases with sale
Na
-
correction was highest in Ihe proactive -DDAVP
treatment group,followed by reactive then rescue
treatment(78.6% for proactive vs. 29.3% for
reactive|.According loclinical or radiographic
findings.4 of 1450 admissions had suspected osmotic
demyelrnaban syndrome,two of which occurred
during DDAVP administration (0.79% incidence.95%
Cl 0.22-2.82],
Conclusions:Ihe rescue strategy of DDAVP
administration is not an idealstrategy, while the
proactive strategy was effective a!slowing Na*
rate of change.In patientsat nsk for osmotic
demyelinabon syndrome,a pcoactive DDAVP strategy
more often achieved a more stringent correction limit.
Extra-renal Losses
* Gl loss (diarrhea,fistulas)
• Insensible loss (exercise,
seizures)
Renal Losses
• Central Dl
• Nephrogenic Dl
• Osmetic diuresis (hyperglycemia,
mannitol,urea. NS. polyethylene glycol)
Figure 6. Approach to hypernatremia
Signs and Symptoms
• hypernatremia = shrunken cells
• acute hypernatremia (<24-48 h)
• chronic hypernatremia (>24-48 h), cells will have achieved adaptive mechanism: can import and
generate new osmotically active particles to normalize cell size
• nearly all cases of hypernatremia will be due to chronic hypernatremia
• acute hypernatremia primarily presents in patients with diabetes insipidus
• symptoms due to brain cell shrinkage: altered mental status,weakness, neuromuscular
irritability, focal neurologic deficits,seizures, coma, death
• ± polyuria, thirst, signs of hypovolemia
Complications
• increased risk of vascular rupture resulting in intracranial hemorrhage
• rapid correction may lead to cerebral edema
Treatment of Hypernatremia
• general measures for all patients
• give free water (oral or IV)
treat underlying cause
monitor serum Na frequently (q4h) to ensure correction is not occurring too rapidly
• if evidence of hemodynamic instability,then must first correct volume depletion with NS bolus
• loss of water is often accompanied by loss of Na * ,but a proportionately larger water loss
ri
u J
+
Activate Windows
Go to Settings to activate Windows.
XPI2 Xcphiology Toronto Xotcs 2023
• encourage patient to drink pure water, as PO is preferred for fluid administration
• if unable to replace PO or NG,correct H:0deficit with hypotonic IV solution (IV D5W, 0.45% NS [half
normal salinej,or 3.3% dextrose with 0.3% NaCl [“2/3 and 1/3”])
• chronic hypernatremia:aim to lower serum sodium by 8-10 mEq/L in 24 h (often achieved by giving
free water at 1.35 mL/kg/h)
• acute hypernatremia: use formula to calculate water deficit. Replace entire water deficit within 24 h
(hourly infusion rate = water deficit in mL/24 h)
• infusion rate may need to be increased in order to account for ongoing losses in addition to initial
deficit
Diabetes Insipidus
Definition
•collecting tubule is impermeable to water due to absence of ADH or impaired response to ADH
•defect in central release of ADH (central Dl) or renal response to ADH (nephrogenic Dl)
Etiology
•central Dl: neurosurgery, granulomatous diseases, trauma, vascular events, and malignancy
•nephrogenic Dl
usually acquired - drugs(e.g. lithium),secondary to amyloidosis,sickle cell disease,Sjogren
syndrome, polycystic kidney disease, electrolyte imbalances (i.e. hypercalcemia)
congenital/hereditary
Diagnosis
•urine osmolality inappropriately low in patient with hypernatremia (U <>»m <300 mOsm/kg)
•serum vasopressin concentration may be absent/low (central), or elevated (nephrogenic)
•dehydration test: H:0 deprivation until loss of 3% of body weight or until urine osmolality rises above
plasma osmolality; if urine osmolality remains <300 (fails to concentrate urine), most likely Dl
A Copeptin-Based Approach to the Diagnosis ol
DiabetesInsipidus
NiJU 2018:379:428 3S
Purpose: Compansoo of the indirect water
deprivation test,a techaicaly cumbersome test with
direct detection of plasma copeptu.a precursorderived surrogate of arginine vasopressin.
Methods: from 2013 to 200, ISO patients with
hypotonic polyuria underwent both indirect
water-deprivation testing and hypertonic saline
infusion tests.In the biter lest, plasma copeptin
levels were measured when plasma Ka > increased
to >130 mmoifl after saine mfesion.foe primary
outcome was overal diagnostic accuracy of each
test compared with hnal reference diagnosis,as
determined by clinical history,test results and
treatment response, with copeptin levels masked.
lesulU: Among the141 patients included in final
analysis, the Indirect water-deprivation test showed
diagnostic accuracy in 108 patnnts(7C.fiV83%
Cl (8.9 lo 83.2)and the hypertonic saknc infusion
(copeptin cutoff >4.9 mmotil)showed diagnostic
accuracy in 136 patients(94.3%:93% Cl 92.1to
98.6. P‘
0.001). Ihe water-deprivation test correctly
distinguished primary polydipsia from partial central
Dl in 77 of 105 patients(23.3%:95% Cl 63.9 to 81.2)
while the hyperton itsaline test distinguished in 99 of
104 patieMs|95.2%;95% Cl 89.4 to 98.1.M.001).
Conclusion la pit a tswtl bypoMl cpOfiyaH l
direct measurement of hypertomc-salme stimulated
plasma copeptin levelsshowed greater diagnostic
accuracy than the water-deprivation test.
Management
•central Dl: administer exogenous ADH (e.g. DDAVP) 10 pg intranasally or 2 pig SC or IV
•nephrogenic Dl: patients may have partial or complete ADH resistance, and DDAVP is generally
ineffective
• maintain fluid intake to match losses, e.g. PO water, IV D5W, IV 0.45% NS
• treat underlying cause of nephrogenic Dl
thiazides can help by paradoxically reducing urine output: thiazides induce hypovolemia ->
stimulate proximal tubular reabsorption of sodium and water -> less delivery of glomerular
filtrate to the collecting duct -> lower urine volume
Potassium Homeostasis
•-98% of total body K 'stores are intracellular
•normal serum K '
ranges from 3.5-5.0 mEq/L
•in response to K '
rise,rapid removal from ECP is necessary to prevent life-threatening hyperkalemia
(K+ >6.5 mEq/L)
•insulin, catecholamines, and acid-base status influence K '
movement into cells
aldosterone has a minor effect
•potassium excretion is regulated at the DCT and collecting ducts
K’
excretion = urine flow rate x urine [K '
)
Factors which Increase Renal K+Loss
•hyperkalemia
•increased distal tubular urine flow rate and Na ^ delivery (thiazides and loop diuretics)
•increased aldosterone activates epithelial sodium channels in cortical collecting duct, causing Na +
reabsorption and K+excretion
•metabolic alkalosis (increases K + secretion)
•hypomagnesemia
•increased non-resorbable anions in tubule lumen: HCO 3
"
, penicillin,salicylate (increased tubular flow
rate increases K+secretion)
Hypokalemia s n
i j
Definition
. serum [K+ ] <3.5 mEq/L
Signs and Symptoms
• usually asymptomatic,particularly when mild (3.0-3.5 mmol/L)
• nausea/vomiting,fatigue,generalized weakness,myalgia,muscle cramps, and constipation
• ifsevere:arrhythmias,rhabdomyolysis, myoglobinuria, and rarely paralysis with eventual respiratory
impairment
+
Activate Windows
-
Gcrto Settings to activate Windows.
XP13 Nephrology Toronto Notes 2023
• arrhythmias occur at variable levels of K * ; more likely if digoxin use, hypomagnesemia, or CAD
• ECG changes are more predictive of clinical picture than serum|K '
|
• U waves most important (low amplitude wave following a T wave)
• flattened or inverted T waves
• depressed ST segment
• prolongation of Q-T interval
• sinus bradycardia
• with severe hypokalemia:P-K prolongation, wide QRS, arrhythmias; increases risk of digitalis
toxicity
• common arrhythmiasseen with hypokalemia: ventricular fibrillation, ventricular tachycardia
1 2 34 s
r
s
—
Normal Uwave U wave Progression <
Figure 7. ECG changes in hypokalemia
Hypokalemia is often accompanied by
metabolic alkalosis:
• K ^shifts from cells to ECF;H- shifts
into cells in response
• Plasma [HCOJ-]increases,while
intracellular pH decreases
• In response to low pH.renal tubular
cells secrete H'into lumen,and
increase renal ammoniagenesis and
excretion
• Resultant addition of more [HC03-]
into plasma •metabolic alkalosis
Approach to Hypokalemia
1. emergency measures if K+ <2.5 mEq/L:obtain ECG;if potentially life threatening, begin treatment
immediately
2. rule out transcellular shifts of K+ as cause of hypokalemia
3. assess contribution of dietary K+ intake
4.spot urine K:Cr
if <1.5 mEq/mmol consider G1 loss
if >1.5 mEq/mmol consider a renal loss
5. consider 24 h K'excretion
6. if renal Moss, check BP and acid-base status
7. may also assess plasma renin and aldosterone levels,serum|Mg- 11
[ Hypokalemia ]
t T
Redistribution into Cells (transcellular shills)
• Metabolic alkalosis (K'/H' exchange across cell membranel
• Insulin(stimulates Na/K'ATPase)
• Catecholamines,pt-agonists Isalbutamol),theophylline
(stimulates Na' /KATPasel
• Tocolytic agents
• Uptake into newly forming cells
-Vitamin B injections in pernicious anemia
-Colony stimulating factors T WBC production
Decreased Intake
•Limited dietary intake
•Clay ingestion
Increased Loss
i
Spot urine ICCr^
I i
Spot urine K:Cr
<1.5mEq/mmol
Spot urine ICCr
>1.5mEq/mmol
; r
•
GlLosses
Diarrhea 1 C
•Laxatives
•Villous adenoma
Renal losses
T
Check BP
T 1
[Hypo- or normotensive ] Hypertensive
•1°hyperaldosteronism (e g. Conn's syndrome)
•2°hyperaldosteronism (renovascular disease,renin tumour)
[ Check acid base status) •Non-aldosterone mrneralocorbcoid (Cushing's,exogenous)
T V
Acideinic
•DKA
•RTA
Variable
•HypoMg
•Vomibng/NG
Alkalemic
•Diurebcs (furosemide,HCT2Imanifest as renal losses due to
hyperaldosteronism,metabolic alkalosis, and increased flow to collecting duct
•Inherited renal tubular lesions
-Banter's (loop of Henle dysfunction:furosemide-like effect)
-Gitelman'
s (DCT dysfunction: thiazide-like)
Figure 8.Approach tohypokalemia r n
c.
Treatment
•treat underlying cause
•if true K 1 deficit, potassium repletion
oral sources:food, tablets (K-Dur‘
), KC1liquid solutions (preferable route if the patient tolerates
PO medications)
IV: usually KC1 in saline solutions, avoid dextrose solutions(may exacerbate hypokalemia via
insulin release)
+
Activate Windows
Go to Settings to activate Windows.
XP14 Nephrology Toronto Notes 2023
• max 40 mmol/L via peripheral vein, 60 mmol/L via central vein, max infusion 20 mmol/h
• K’-sparing diuretics(triamterene, amiloride, spironolactone) can prevent renal Kioss
• restore Mg-’
before correcting K *
• if urine output and renal function are impaired, correct with extreme caution
• risk of hyperkalemia with potassium replacement especially high in elderly, diabetics, and patients
with decreased renal function
• use ACE inhibitor or ARB for CHI (reduces angiotensin 11 action and therefore reduces aldosterone
production)
• beware of excessive potassium repletion, especially if hypokalemia secondary to transcellular shift
Hyperkalemia
Definition
• serum [K*
|>5.0 mEq/E
Signs and Symptoms
• usually asymptomatic but may develop nausea, palpitations, muscle weakness, muscle stiffness,
paresthesias, aretlexia, ascending paralysis, and hypoventilation
• impaired renal ammoniagenesis and excretion and metabolic acidosis
• ECG changes and cardiotoxicitv (do not correlate well with serum [k
’
])
• peaked and narrow T waves
• decreased amplitude and eventual loss of P waves
• prolonged PR interval
• widening of QRS and eventual merging with T wave (sine-wave pattern)
• AV block
• ventricular fibrillation, asystole
1 2 3 4 5 .1
2-
—1
Peaking
Twave
Normal Peaked
Twave V
Figure 9.ECG changes in hyperkalemia
Table 6. Causes of Hyperkalemia
Pseudohyperkalemia Increased Intake Transcellular Shift Decreased Excretion
Sample hemolysis*
Sample taken from vein
whereIV KCI is running
Prolonged use ol tourniguet
leukocytosis (eilremel
thrombocytosis"(eitreme)
O.et Intravascular hemolysis
Rhabdomyolysis
tumour lysis syndrome
Insulin deficiency
Metabolic Acidosis
Drugs
(1-blockers
Digitalis overdose (blocks
Na /K-AlPase)
Succinylcholine
Decreased GFR
Renal failure
Low effective circulating volume
NSAlDs inrenal insufficiency
Normal GFR but
hypoaldosteronism (table 7)
KCItabs
IV KCI
Salt substitute
’Most common
"Usually when blood specimen has been sitting out long beloie being analyzed
Table 7. Causes of Hyperkalemia with Normal GFR Secondary to
Hypoaldosteronism
Decreased Aldosterone Stimulus (low Decreased Aldosterone Production
renin,low aldosterone)
Aldosterone Resistance (decreased
(normalrenin, low aldosterone) tubular response)
Associated with diabeticnephropathy.NSAlDs. Adrenal Insufficiency (e.g.Addison’s disease.
AIDS,metastatic cancer)
K- sparing diuretics:
Spironolactone
Amiloride
Triamterene
Renal tubulointerstitial disease
chronic interstitial nephritis.HIV
ACEI
Angiotensin IIreceptor blockers
Heparin
Congenital adrenal hyperplasia with
21-hydroxylase deficiency
Approach to Hyperkalemia
1.emergency measures:obtain ECG; if life threatening, begin treatment immediately
2.rule out pseudohyperkalemia; repeat blood test
3. hold exogenous K’ ( HO and IV ) and any medications that are K ’retaining
e.g.RAAS inhibitors(ACEI, ARBs), aldosterone antagonists, non-selective|
}-blockers ( propranolol/
labetalol) or affect K‘
excretion (i.e. NSAlDs)
4. assess potential causes of transcellular shift
5. determine eGlR
In patients with DM and increased [K*]
and hyperglycemia, often just ghnng
insulin to restote euglycemia is sufficient
to correct the hyperkalemia
+
Activate Windows
Go to Settingsto activate Windows,
NP15 Nephrology Toronto Notes 2023
Treatment
• acute therapy is warranted if E(Xi changes are present or if patient is symptomatic regardless of|K '
|
• tailor therapy to severity of increase in|K '
|and EC(i changes
|K 11 <6.5 and normal E(Xi
treat underlying cause,stop K '
intake, increase the loss of K '
via urine and/or (il tract
• |K 11 between 6,5 and 7.0, no IXXi changes: add insulin to above regimen
• |K 1 j >7.0 and/or IXXi changes: first priority is to protect the heart, add calcium gluconate to above
<§;
Treatment of Hyperkalemia
C BIG K DROP
C Calcium gluconate
BIG pagonlst.Insulin. Glucose
K Kayexalatc'
DROP Diuretics. Dialysis
1. Stabilize Myocardium
• calcium gluconate 1-2 amps (10 rnL of 10% solution) IV
• antagonizes hyperkalemia induced membrane depolarization, protects cardiac conduction system, no
effect on serum [K +
J
No comments:
Post a Comment
اكتب تعليق حول الموضوع