18 Chronic Kidney Disease

Question 1

Definitions

• Kidney damage
• Chronic kidney disease (CKD)
• End stage renal disease (ESRD) or kidney failure
• Uremia

Answer 1

• Kidney damage
  
  • Structural or functional abnormalities of the kidney > 3 months
    
    • Initially: w/o decreaed GFR
    • Over time: decreased GFR
  • Markers of kidney damage
    
    • Ex. proteinuria, polycystic kidneys, hx of kidney transplant, etc.
    • Abnormalities in the composition of the blood or urine
    • Abnormalities in imaging tests of the kidney
• Chronic kidney disease (CKD)
  
  • Decreased GFR or kidney damage
• End stage renal disease (ESRD) or kidney failure
  
  • Severely decreased renal function (GFR < 15 ml/min/1.73m²)
  • Requires renal replacement therapy (i.e. hemodialysis / peritoneal dialysis or transplant)
• Uremia
  
  • Signs & symptoms attributable to advanced reanl failure or ESRD

Question 2

Stages of CKD

• Stage 1
• Stage 2
• Stage 3
• Stage 4
• Stage 5
• CKD
• Very significant independent risk factor for mortality & morbidity
• How we define/stage CKD

Answer 2

• Stage 1
  
  • Kidney damage (structural or functional) with normal or ↑ GFR
  • GFR > 90
• Stage 2
  
  • Kidney damage (structural or functional) with mild ↓ GFR
  • GFR = 60-89
• Stage 3
  
  • Moderate ↓ GFR
  • GFR = 30-59
• Stage 4
  
  • Severe ↓ GFR
  • GFR = 15-29
• Stage 5
  
  • Kidney failure
  • GFR < 15 or dialysis
• CKD
  
  • Stages 3-5
• Very significant independent risk factor for mortality & morbidity
  
  • Proteinuria
• How we define/stage CKD
  
  • Albuminuria
  • Reduced eGFR (< 60 ml/min/1.73m²)

Question 3

Measurement & assessment of GFR

• Commonly used indicators of GFR in clinical practice
• Plasma creatinine vs. GFR
• Creatinine production varies with…& is influenced by…
• Take home

Answer 3

• Commonly used indicators of GFR in clinical practice
  
  • Serum creatinine and blood urea nitrogen (BUN) concs
  • Lab measurement of creatinine and urea is accurate and reliable, but normal values may vary from lab to lab
• Plasma creatinine vs. GFR
  
  • Semi-logarithmic relationship
  • Small values (steep part of the curve): a relatively small change in creatinine indicates a large change in GFR
  • Large values: a large change in creatinine reflects only a small change in GFR
• Creatinine production varies with…& is influenced by…
  
  • Muscle mass
    
    • Changes in lean body weight over time influence the serum creatinine level
  • Age, sex, race influence muscle mass
• Take home
  
  • All of these are reasons why an eGFR is preferred in estimating renal function

Question 4

Etiology & natural history of CKD

• Most chronic nephropathies
• Rate of decline
• Electrolyte homeostasis, causes of progressive decline in function, and manifestations of kidney failure

Answer 4

• Most chronic nephropathies demonstrate inexorable progression to kidney failure
• The rate of decline ≈ 7-12 ml/min/year in those with untreated chronic nephropathies such as diabetic nephropathy
• Electrolyte homeostasis, causes of progressive decline in function, and manifestations of kidney failure
  
  • Similar enough across the dif pathologies
  • –> common underlying routes to progression, symptoms, and (hopefully) amelioration of CKD

Question 5

Prevalence of CKD, risk factors for development, & progression

• Prevalence of CKD
• Risk factors
  
  • CKD is largely a disease of…
  • Comorbidities
• Majority of pts with CKD
• Prevalence of ESRD

Answer 5

• Prevalence of CKD
  
  • ~14.7% of the US adult population has some form of CKD
  • 30x as many pts have CKD than ESRD
  • >75 million have an increased risk of developing CKD
• Risk factors
  
  • CKD is largely a disease of older adults
    
    • Higher rates of comorbidities + age related decline in GFR
    • GFR decline of ~8ml/min for each decade after 40
  • Comorbidities
    
    • DM
    • HTN
    • Dyslipidemia
    • Obesity
• Majority of pts with CKD
  
  • Not aware, even those with an eGFR of 15-30 ml/min/1.73m²
  • No clear, early, identifiable signs
  • Increae in creatinine is often subtle
• Prevalence of ESRD
  
  • Increasing rapidly
  • Will continue for the next few decades
• Mortality
  
  • After ESRD is reached (dialysis), mortality rate is very high
• Cost
  
  • > $20 billion
• Qualtiy of life
  
  • Burden on pt & families comparable to other devastating illnesses

Question 6

Risk factors for CKD

• Non-modifiable
• Modifiable

Answer 6

• Non-modifiable
  
  • Older age
  • Black race
    
    • Black > native americans > hispanics > asians / pacific islanders
  • Genetic predisposition
  • Prematurity
  • Important for screening purposes & for studying CKD progression
• Modifiable
  
  • HTN
  • Diabetes
  • Obesity
  • Dyslipidemia
  • Hyperuricemia
  • Smoking
  • Heavy consumption of analgesics
  • Improtant for understanding the pathophysiology of CKD & possible options for intervention & therapy

Question 7

Pathophysiology of progression of renal disease

• CKD is characterized by…
• Renal adaptation –> maladaptive processes
  
  • 2 major consequences
  • Short term –>
  • Long term –>
• Remnant kidney animal model
• Glomerular capillary HTN is mediated by…
• RAAS primary mediators

Answer 7

• CKD is characterized by…
  
  • Loss of functioning nephrons (not decreased output/function of the same number of nephrons)
• Renal adaptation –> maladaptive processes
  
  • 2 major consequences
    
    • Elevated glomerular pressure –> hyperfiltration by remaining nephrons
    • Glomerular / tubular growth –> increased wall stress/inflammation –> hypertrophy
  • Short term –> increased single nephron GFR –> hyperfiltration
  • Long term –> increased glomerulosclerosis & tubular atrophy
• Remnant kidney animal model
  
  • Remove one kidney & large fraction of other kidney –> decreased nephron mass
  • –> increased RPF & GFR in remaining nephrons
  • –> glomeruli: increased blood flow, filtration rate, & size
• Glomerular capillary HTN is mediated by AII
  
  • ACE-Is or ARBs –> AII blockade –> prevents glomerular HTN
  • Increase renin mRNA synt –> increase DNA synth –> mesangial cells multiply, epithelial cells hypertrophy, epithelial foot processes increase in #, & glomerular capillary length increases
• RAAS primary mediators
  
  • AII, IGF-1, PDGF, prostaglandins, RANTES, endothelin, & AVP
  • Modulate renal cell growht in culture &/or circulating blood levels after nephrectomy

Question 8

Glomerulosclerosis

• Most pts have progressiv ekidney disease due to…
• First stage
• Second stage
• Third stage

Answer 8

• Most pts have progressiv ekidney disease due to…
  
  • HTN
  • Diabetes
  • Other chronic glomerulonephropathy
• First stage: e__ndothelial injury & inflammation
  
  • Damaged endothelium loses its anticoagulation, anti-inflammatoyr property
  • Endothelium becomes primed for the proliferative stage
• Second stage: proliferation
  
  • Kidney damage is characterized by stretched epithelial cells & proliferated/dedifferentiated mesangial cells
• Third stage: fibrosis
  
  • Hyaline material accumulates int he mesangium & subendothelial regions of the glomerulus
  • Hyaline material eventually –> collapse of capillaries (glomerulosclerosis)

Question 9

CKD pathophysiology take home points

• 2 major processes important for CKD progression
• These events eventually lead to…
• RAAS inhibition

Answer 9

• 2 major processes important for CKD progression
  
  • GLomerular hyperfiltratoin
  • Glomerulra hypertrophy
• These events eventually lead to…
  
  • Fiborsis & sclerosis of glomeruli
• RAAS inhibition
  
  • Prevent development of glomerular HTN & subsequent CKD progression

Question 10

Strategies to slow CKD progression

• Early diagnosis & treatment
• (1) Treat underlying causes
• (2) Control BP
  
  • BP goals
    
    • Urine albumin < 30 mg/ 24 hrs
    • Urine albumin > 30 mg / 24 hr
  • Risk of progression of CKD is modified by…
  • Antihypertensives
• (3) Protein intake
• (4) Smoking cessation
  
  • Nicotine
  • Tubuloxic effect
  • Vascular effects
  • Bottom line
• (5) Nephrotoxins
  
  • Most concerning
  • Others
  • AKI vs. CKD

Answer 10

• Early diagnosis & treatment
  
  • Interventions slow progression of, but don’t reverse, kidney disease
    
    • May help pt avoid dialysis, transplant & kidney failure complications
  • Optimal treatment can slow rate of progression from 10 to 2-4 ml/min/year
• (1) Treat underlying causes
  
  • Identify reversible factors
  • Ex. volume depletion, uncontrolled HTN, obstructive uropahty, nephrotoxins
• (2) Control BP
  
  • BP goals
    
    • Urine albumin < 30 mg/ 24 hrs: < 140/80
    • Urine albumin > 30 mg / 24 hrs: < 130/80
  • Risk of progression of CKD is modified by proteinuria
  • Antihypertensives: ACE-Is & ARBs
    
    • Block AII –> decrease glomerular capillary HTN –> decrease proteinuria –> decrease AII fibrosing effects
    • Delay progression + cardiovascular benefits
    • Don’t ever discontinue
    • Side effects: increased creatinine, increased K, angioedema, & cough (ACE-I only)
• (3) Dietary protein restriction
  
  • Decreased protein intake –> decreased hyperfiltration –> slowed progression
• (4) Smoking cessation
  
  • Nicotine
    
    • Increases GFR, urine flow, & Na excretion
    • Increases catecholamines, cortisol, & aldo
  • Tubuloxic effect
    
    • Increased excretion of NAG & impaired cation transport
  • Vascular effects
    
    • Increased platelet aggregation & vasoconstrictor prostaglandins
    • Decreased vasodilatory prostaglandins
    • Endothelial cel linjury & impaired endothelial cell-dependent vasodilation
  • Bottom line
    
    • Tobacco potentiates GFR loss & can cause/worsen proteinuria
• (5) Avoid nephrotoxins
  
  • Most concerning: NSAIDs & herbal meds
  • Others: tacrolimus/prograf/cyclosporine, aminoglycosides, amphotericin, colistin, & IV contrast
  • AKI –> CKD & CKD –> AKI

Question 11

Cardiovascular disease (CVD)

• Cause of disparity b/n # of pts receiving renal replacement & # w/ CKD
• CKD vs. CVD
• Traditional risk factors
• Non-traditional risk factors
• Both traditional & non-traditional factors
• Treatment

Answer 11

• Cause of disparity b/n # of pts receiving renal replacement & # w/ CKD
  
  • Most pts w/ CKD die from CVD prior to requiring dialysis or transplantation
  • Even on dialysis, risk of death from CVD is higher than in general population
• CKD vs. CVD
  
  • Pts w/ CKD are high-risk pts for CVD
  • CKD = coronary equivalent
  • Pts w/ lower GFRs & microalbuminuria/proteinuria carry a high risk of CVD (equivalent to a prior hx of coronray disease
• Traditional risk factors
  
  • Ex. age, diabetes, lipids, HTN, smoking, etc.
  • Account for only a portion of the CVD risk associated w/ CKD
• Non-traditional risk factors
  
  • Ex. anemia, volume overload, hyperparathyroidism, Ca/phosphate disturbances, uremia, & malnutrition/inflammation
  • Play a role in increasing CVD risk in CKD
• Both traditional & non-traditional factors
  
  • –> cardiomyopathy & ischemic heart disease
• Treatment
  
  • Optimize management of known CVD risk factors
  • Focus on BP, exercise, aspirin, & statins
  • High suspicion b/c CKD pts often presnet w/ atypical CVD symptoms

Question 12

Early identification treatment plan / model of care for pts w/ CKD

• Screen
• Diagnose
• Treat
• Prepare

Answer 12

• Screen for CKD
  
  • Older pts
  • Hx of kidney problems
  • Family hx
  • African-american
  • HTN
  • Diabetics
• Diagnose CKD
  
  • Serum creatinine –> eGFR, urine ablumin, or protein
• Treat kidney disease & CVD
  
  • Manage BP
  • Reno-protective meds (ACE-Is, ARBs)
  • Smoking cessation
  • Treat complications
• Prepare for renal replacement therapy
  
  • Dialysis
  • Transplant

Question 13

Uremia

• General
• Basic abnormality
• Symptoms vs. GFR
• Uremic symptoms result from…
• Uremia is related to…
• Variability in measuring kidney function
• Usual physical signs can be rapidly assessed by…
• Indication for initiation of dialysis
• Presence of uremic symptoms in a chronic dialysis pt often reflects…

Answer 13

• General
  
  • Pathologic manifestation of kidney disease in its most severe untreated form
  • Clinical expression of symptoms/signs of decreased GFR (renal failure)
• Basic abnormality
  
  • Presence of waste products that the kidney is no longer removing form the body
  • Retained products of metabolism
• Symptoms vs. GFR
  
  • CKD pts may be asymptomatic until GFR < 15-20 ml/min –> uremia
• Uremic symptoms result from…
  
  • Renal excretory failure
    
    • Retention of urea, hormones, polyamines, trace elements, serum proteases (“middle molecules”), pyridine derivatives, beta2-microglobulin, etc.
  • Loss of normal metabolic & endocrine functions
• Uremia is related to protein intake
  
  • Low protein diet –> decreased symptoms
• Multisystem disorder: manifestations include…
  
  • GI: nausea, vomiting, diarrhea, dysguesia, changes in appetitie
  • CVS: dyspnea, edema, chest pain
  • Neuro: restless legs, twitching, confusion, sleep & memory problems
  • Skin: pruritus, bruising, uremic frost
  • MSK: bone pain (endocrine), arthritis
  • Hematologic
• Variability in measuring kidney function
  
  • CKD pts develop complications s& symptoms at dif thresholds
  • Makes it difficult t ouse GFR as the only factor in decision making
• Usual physical signs can be rapidly assessed by…
  
  • BP, pericardial rub, rales, etc.
• Indication for initiation of dialysis
  
  • Development of & failure to alleviate uremic manifestations w/ conservative/pharmacologic therapy
• Presence of uremic symptoms in a chronic dialysis pt often reflects…
  
  • Inadequate treatment
  • Need to increase dialysis dose

Question 14

Uremia

• Common signs
• Multisystem disorder: manifestations include…
  
  • Cardiovascular
  • Endocrine disorders
  • Hematologic
  • GI
  • Neuropsychiatric
  • Immunologic
  • Musculoskeletal
  • Dermatologic

Answer 14

• Common signs
  
  • Sallow pallor, bruising
  • Uremic fetor
  • Hypertension
  • Pericardial rub
  • Alteration of consciousness
  • Neuropathy
  • Malnourished state
• Manifestations
  
  • Cardiovascular
    
    • HTN
    • Ischemic cardiac disease
    • Pericardial disease (pericarditis)
    • CHF
    • Dyspnea
    • Edema
    • Chest pain
  • Endocrine disorders
    
    • Secondary hyperparathyroidism
    • Glucose intolerance (uremic diabetes)
    • Hyperlipidemia
    • Sexual dysfunction / infertility
  • Hematologic
    
    • Anemia
    • Bleeding diathesis
  • GI
    
    • Anorexia
    • Nausea
    • Vomiting
    • Gastritis
    • Duodenitis
    • Dysgeusia
    • Changes in appetite
  • Neuropsychiatric
    
    • Peripheral neuropathy
    • CNS disturbances
    • Seizures
    • Sleep disorders
    • Restless leg
    • Twitching
    • Confusion
    • Memory problems
  • Immunologic
    
    • Leukopenia, lymphocytopenia
    • Decreased antibody responses
    • Decreased cell-mediated immune respones
    • Increased susceptibility to infection
  • Musculoskeletal
    
    • Mineral & bone disease
    • Myopathies
    • Carpal tunnel syndrome
    • Bone pain
    • Arthritis
  • Dermatologic
    
    • Pruritus
    • Uremic pigmentation
    • Uremic frost
    • Calciphylaxis
    • Nail changes
    • Bruising

Question 15

Renal adaptation

• Pt awareness of their kidney disease
• Asymptomatic CKD
• Basis of adaption

Answer 15

• Pt awareness of their kidney disease
  
  • >10-12 million adults in the US have CKD w/ GFR < 60 ml/min
  • Majority aren’t aware
• Asymptomatic CKD
  
  • CKD is often asymptomatic until late in the disease course
  • Renal reserve allows remaining nephrons to hyperfilter/increase their level of function
  • Additional compensatory processes maintain adequate homeostasis
• Basis of adaption
  
  • Adaptations in glomerular & tubular function & extra-renal systems maintain electrolyte balance but may contribute to adverse consequences
  • Adaptation –> increased solute excretion per remaining functional nephron
  • Fractional excretion increases as GFR decreases

Question 16

Mechanisms that help explain the diseased kidney’s ability to function

• Intact nephron hypothesis
• Functional reserve
• Hyperfiltration
• Osmotic diuresis

Answer 16

• Intact nephron hypothesis
  
  • Diseased kidney continues to regulate appropriately by responding to varying intake of solutes & water in an organized fashion
  • Diseased kidney behaves as a reduced # of nephrons that are each functioning normally or above normally
  • Abnormalities that occur are generally explained by the overall reduction in renal mass rather than by the general loss of glomerular or tubular functions
• Functional reserve
  
  • Ability of kidneys to increase their function/work
  • Severely diseased kidney is functioning at or near its max capacity to maintain homeostasis
    
    • Extreme variations in itake are poorly tolerated
    • Upper & lower limits for solute & water excretion converge in advanced CKD
      
      • Dietary indiscretions or inappropriate meds may not be well tolerated
• Hyperfiltration
  
  • Abnormal increase in filtration rate of functioning glomeruli
  • Decrease renal mass –> hyperfiltraiton in remaining nephrons –> glomerular sclerosis & proteinuria
  • Seconary change in remaining nephrons + increased filtered load –> CKD progression
• Osmotic diuresis
  
  • Decrease renal mass –> each remaining nephron handles increased solute
  • Increased solute excretion per nephron –> osmotic diuresis (associated increased water loss)
  • Reduced ability to produce max concentrated urine
  • –> nocturia & polyuria in moderate to advanced CKD

Question 17

Impact of declining kidney function on fluid/electrolyte balance

• Nephron loss vs. solute regulation
  
  • Creatinine, urea nitrogen, & additional nitrogenous waste products
  • Bicarb, Ca, & organic phosphate
  • Water, Na, & K
• Plasma concs of creatinine & BUN
• Plasma concs of phosphorus & bicarb
• Plasma concs of Na & K
• Plasma H conc
• Additional physiologic stressors in advanced CKD

Answer 17

• Continued solute regulation despite progressive nephron loss
  
  • Little regulation of creatinine, urea nitrogen, & addiitonal nitrogenous waste products (+ other uremic toxins)
  • Partial regulation of bicarb, Ca, & organic phosphate is maintained until there’s significant nephron loss (GFR < 30-45 ml/min)
  • Near complete regultaion of water, Na, & K are maintained until ~9/10 nephrons are lost (GFR < 10-15 ml/min)
• Plasma concs of creatinine & BUN
  
  • Readily increase as GFR deteriorates
• Plasma concs of phosphorus & bicarb
  
  • Change to a lesser degree as GFR deteriorates
• Plasma concs of Na & K
  
  • Relatively stable until there’s severe decrement in GFR
• Plasma H conc
  
  • Tightly regulated
• Additional physiologic stressors in advanced CKD
  
  • Although most homeostatic mechs are robust, in advanced CKD the kidney has a very limited ability to cope w/ additional physiologic stressors
  • Adaptation is limited due to decreased GFR

Question 18

Renal handling of specific fluid/electrolytes:
Creatinine & nitrogenous compounds

• Cr & urea when GFR decreases
• Cr vs. GFR
• Urea vs. GFR

Answer 18

• Cr & urea when GFR decreases
  
  • Excretion of Cr & urea is maintained by increasing serum levels
  • At a higher serum Cr level, the diseased kidney is able to filter and excrete the usual daily production of Cr (i.e., re-establish steady state)
  • There are minimal adaptive mechs to maitnain “normal” serum levels of Cr/urea
• Cr vs. GFR
  
  • Increased serum Cr is directly proportional to decreased GFR
  • Good measure of GFR
• Urea vs. GFR
  
  • Increased serum urea is directly proportional to decreased GFR
  • Urea is also affected by other factors like urine flow, dietary protein, catabolic state, & drugs (ex. steroids & tetracycline)

Question 19

Renal handling of specific fluid/electrolytes:
Na excretion

• Challenge for the kidney in Na homeostasis
• FE_Na in healthy patients
• Most CKD patients are able to excrete the daily Na load in the setting of a reasonable dietary Na+ intake
  
  • Due to…
  • Mechs
• FE_Na in CKD pts
• Excretory range in CKD
• Na homeostasis in CKD pts is maintained by…
  
  • Input sol’n
  • Output sol’n
• Marked Na retention occurs if…
• Clinical manifestations of Na imbalance in CKD
  
  • Common
  • Less common

Answer 19

• Challenge for the kidney in Na homeostasis
  
  • Large variations in daily dietary Na intake from 10 - 500 mEq/day (0.2-11g/day)
• FE_Na in healthy patients
  
  • Varies depending on intake
  • <1% w/ intake b/n 2-5g
• Most CKD patients are able to excrete the daily Na load in the setting of a reasonable dietary Na+ intake
  
  • Due to increased fractional excretion by tubules
    
    • Tubules are filtering less Na due to decreased GFR
    • –> higher fractional excretion is adaptive
  • Mechs
    
    • Decrease Na/K/2Cl (loop) & Na/Cl (thiazide) transporters
    • Increase natriuretic factors (ex. atrial natriuretic peptide)
    • Adaptive natriuresis
      
      • Modest hypervolemic status –> pressure natriuresis
      • –> further Na excretion –> establish a new steady tate
• FE_Na in CKD pts
  
  • Increased FE_Na –> decreased fractoinal reabsorption via…
    
    • Decreased N/K/2Cl & Na/Cl transporters
    • Increased ANP
    • Increased adaptive natriuresis
      
      • Initial + Na balance –> increased EC volume –> increased BP –> pressure natriuresis –> re-establishes steady state
• Excretory range in CKD: narrowed
  
  • Dietary Na intake increases (decreases) –> volume overload (depletion)
• Na homeostasis in CKD pts is maintained by…
  
  • Input sol’n: dietary Na restriction in proportion to decreased GFR
  • Output sol’n: increased Na excretion
• Marked Na retention occurs if…
  
  • Intake >>> max ecretion level or GFR is very low (<10%)
  • To prevent this: dietary Na restriction of 2g/day
• Clinical manifestations of Na imbalance in CKD
  
  • Common: weight gain, peripheral edema, pulm edema
  • Less common (GI illness, etc.): weight loss, tachycardia, systemic HoTN

Question 20

Renal handling of specific fluid/electrolytes:
Water excretion

• Water balance is maintained in advanced CKD via…
• Changes are due to…
• What limits kidney’s concentrating ability
• Fractional reabsorption of water per nephron
• Urine osmolality
• Inability to concentrate urine –>
• Inability to dilute urine –>

Answer 20

• Water balance is maintained in advanced CKD via…
  
  • Normal thirst mech
  • Free access to water
• Changes are due to…
  
  • Decreased GFR –> limited ability to clear water (limited diluting capacity)
• What limits kidney’s concentrating ability
  
  • Structural damage in the medulla & tubulointerstitium
  • FUnctional defects affecting ADH receptors & AQP channels
  • Osmotic diuresis
• Fractional reabsorption of water per nephron: decreased
  
  • Adaptive to maintain adequate water excretion in the setting of reduced filtration
  • Limtis kidney’s concentrating ability
  • Limits kidney’s ability to tolerate water deprivation
• Urine osmolality: isosthenuria (~300 mOsm/L)
  
  • Sudden water load or deprivatoin is poorly tolerated
  • Kidney can’t dilute or concentrate urine
• Inability to concentrate urine –>
  
  • Nocturia
  • Modest polyuria
  • Hypernatremia (if water intake is limited)
• Inability to dilute urine –>
  
  • Hyponatremia (if water intake is excessive)

Question 21

Renal handling of specific fluid/electrolytes:
K excretion

• Filtered load of K vs. distal K secretion
• K excretion is increased by…
• Distal K secretion vs. GFR
• Hyperkalemia (in most pts w/ CKD)
• Hyperkalemia (in some pts w/ CKD)

Answer 21

• Filtered load of K vs. distal K secretion
  
  • Decreased filtered load of K –> increased distal K secretion –> increased FE_K
• K excretion is increased by…
  
  • Increased aldo
  • Increased EC K
  • Increased distal tubular flow due to…
    
    • Adaptive natiuresis (Decreased fractional reabsorption of Na)
    • Osmotic diuresis per nephron
    • Pressure natriuresis
• Distal K secretion vs. GFR
  
  • Increase distal K secretion –> decrease GFR (proportionally)
• Hyperkalemia is uncommon in most pts w/ CKD on a normal diet until GFR < 15 ml/min or oliguria develops due to…
  
  • Increased GI losses
  • Increased secretion by distal nephrons
• Some pts w/ moderate CKD will develop hyperkalemia
  
  • Inadequate aldo
    
    • Idiopathic (diabetes w/ type IV renal tubular acidosis, RTA)
    • ACE-Is, ARBs, K sparing drugs
  • Distal flow-related
    
    • Volum edepletion
    • CHF w/o diuretics (decreased ECV)
  • Lack of insulin
    
    • DM
    • Fasting
  • Dietary indiscretion/meds
    
    • ACE-Is
    • K sparing drugs

Question 22

Renal handling of specific fluid/electrolytes:
Acid-base balance

• NH4
• Metabolic acidosis in CKD
• Mechs
  
  • Major
  • Minor
  • Very late CKD
  • Net result
• Adaptation of proton retention in CKD
• 2 patterns of acidosis
  
  • Early
  • Late

Answer 22

• NH4
  
  • Most important urinary buffer
  • Urinary excretion is dependent on NH4 generation/excretion
• Metabolic acidosis in CKD
  
  • Serum HCO3 decreases to 15-20 mEq/L
  • GFR < 25-30 ml/min
• Mechs
  
  • Major: decreased # of functioning nephrons –> decreased NH4 excretion
  • Minor: increased K or ECFV –> proximal bicarb wasting
  • Very late CKD: decreased sulfate/phosphate excretion
  • Net result: positive H balance
    
    • Despite an adaptive increase in fractional NH4 excretion
    • Retained acid is buffered in bone
• Adaptation of proton retention in CKD
  
  • Increased fractional excretion of NH4
  • Increased fractional excretion of phosphate
  • Bone buffering –> osteoporosis
• 2 patterns of acidosis
  
  • Early hyperchloremic non-AG acidosis
    
    • Mild to moderate CKD (GFR < 30 ml/min)
    • Primarily due to decreased NH4+ excretion
  • Late hyperchloremic AG acidosis
    
    • Due to retained sulfates, phosphates, etc.
    • Seen w/ severely reduced GFR (< 10 ml/min) (ex. uremia / ESRD)

Question 23

Example: ability to cope w/ stressors

• A healthy medical student on a surgical rotation spends all day/night in the OR. Ignoring insensible losses and assuming he needs to excrete 600mosms of waste/day, how much fluid would she need to drink today to excrete her daily waste?
  
  • What is the ~ maximum concentrating ability?
  • Assuming he maximally concentrates, how much water will it take to excrete 600mosm (i.e., 1 d of waste)?
• A medical student was mysteriously kidnapped and drugged one night. He awakes in a bathtub full of ice with bilateral flank pain. A note on the floor says: We just removed 1 and 9/10 of your kidneys, find a good nephrologist. Ignoring insensible losses and assuming he needs to excrete 600mosms of waste/day, how much fluid should he drink each day?
  
  • What is the ~ maximum concentrating ability?
  • Assuming he maximally concentrates, how much water will it take to excrete 600mosm (i.e., 1 d of waste)?

Answer 23

• A healthy medical student on a surgical rotation spends all day/night in the OR. Ignoring insensible losses and assuming he needs to excrete 600mosms of waste/day, how much fluid would she need to drink today to excrete her daily waste?
  
  • What is the ~ maximum concentrating ability?
    
    • 1200 mOsm/L
  • Assuming he maximally concentrates, how much water will it take to excrete 600mosm (i.e., 1 d of waste)?
    
    • 0.5 L
• A medical student was mysteriously kidnapped and drugged one night. He awakes in a bathtub full of ice with bilateral flank pain. A note on the floor says: We just removed 1 and 9/10 of your kidneys, find a good nephrologist. Ignoring insensible losses and assuming he needs to excrete 600mosms of waste/day, how much fluid should he drink each day?
  
  • What is the ~ maximum concentrating ability?
    
    • 300 mOsm/L
  • Assuming he maximally concentrates, how much water will it take to excrete 600mosm (i.e., 1 d of waste)?
    
    • 2 L

Question 24

Common complications of CKD:
Hematological Disorders

• Anema
  
  • General
  • Characteristics
  • Primary cause of anemia in CKD
  • Secondary causes of anemia in CKD
  • Management
  • Adverse effects w/ meds
• Platelet dysfunctio

Answer 24

• Anemia
  
  • General
    
    • Decrease in hematorcit correlates w/ severity of disease
    • Prevalence of anemia increases as GFR decreases < 45 ml/min
    • Most pts w/ GFR < 30 ml/min –> at least mildly anemic
  • Characteristics
    
    • Hypoproliferative (normal) bone marrow + normal red cell indices –> normochromic, normocytic anemia
    • Low reticulocyte count
    • Serum erythropoieitin level low to normal (not usually checked)
    • Normal bone marrow (not usually needed to diagnose)
    • Lack of an alternative diagnosis (e.g., vitamin deficiency, iron deficiency, etc)
  • Primary cause of anemia in CKD: decreased erythropoietin production
    
    • Erythropoietin is produced in the kidney
    • CKD –> decreased erythropoietin –> deprives bone marrow of stimulus to produce RBC
  • Secondary causes of anemia in CKD
    
    • Uremic inhibitors of erythropoietin (limiting its efficacy)
    • Decreased RBC half-life
    • Functional or absolute iron deficiency due to occult/overt GI bleeding from gastritis, duodenitis, or angiodysplasia
  • Management
    
    • Synthetic erythropoietin treats anemia in CKD
    • Erythropoiesis-stimulating agents (ESAs): additioanl recombinant forms
      
      • Treat anemia, improve quality of life, & decrease need for transfusions & hospitalizations
  • Adverse effects w/ ESAs in CKD
    
    • Iron deficiency
      
      • RBC production outstrips iron stores
      • Address w/ supplement iron
    • HTN
      
      • Rarely –> severe hypertensive encephalopathy & seizures
    • Increased risk of CV events
      
      • Using ESAs to achieve near normal HgB in pts w/ anemia & CKD carries greater risks than benefits
• Platelet dysfunction
  
  • CKD pts have a bleeding diathesis due to an acquired defect of platelet function
  • Cause: retention of a uremic toxin
  • Responsible for prolonged bleeding & easy bruising

Question 25

Common complications of CKD:
Mineral & bone disease

• CKD is associated w/…
• Management

Answer 25

• CKD is associated w/…
  
  • Abnormalities of divalent ions (Ca, Phos) and of the hormones that regulate the conc of these minerals in body fluids
  • Dysregulation of these divalent ions is a possible source of CV disease
    
    • CKD –> increased vascular Ca depositoin & calcificaiton of heart valves
• Management
  
  • Low phosphorus diet
  • Phosphate binders w/ meals
    
    • Prevents hyperphosphatemia by blocking GI absorption
  • Calcitriol (1,25 Vit D) or analogues
    
    • If/when PTH is elevated
    • Directly suppresses PTH
  • Maintain Ca * Phos product < 55mg²/dl²
    
    • Decreases extra-skeletal calcifications
  • Careful monitoring of Ca, phosphate, PTH
  • Avoid aluminum

Question 26

Common complications of CKD:
Mineral & bone disease:
Phosphorus

• Phosphorus levels as GFR decreases
• Phosphorus levels w/ further decreases in GFR
• As GFR declines further…

Answer 26

• Phosphorus levels are initially unchanged as GFR falls, due to decreased reabsorption
  
  • Fibroblast growth factor 23 (FGF-23) increases as GFR decreases
    
    • FGF-23 increases phosphaturia
  • Elevations in PTH also enhance phosphaturia
• With further decreases in GFR (<30ml/min), phosphate levels increase
  
  • Hyperphosphatemia stimulates the secretion of parathyroid hormone (PTH) and FGF-23
• As GFR declines further, these progressive elevations increase renal phosphate excretion (but not back to normal)

Question 27

Common complications of CKD:
Mineral & bone disease:
Vitamin D metabolism

• 1-alpha-hydroxylase enzyme
• Calcitriol
• When GFR < ~30 ml/min…

Answer 27

• 1-alpha-hydroxylase enzyme
  
  • Catalyzes the conversion of 25-hydroxyvitamin D into its active form, 1,25 dihydroxyvitamin D (i.e., calcitriol)
• Calcitriol
  
  • Enhances GI absorption of calcium and phosphorus
• When GFR < ~30 ml/min, low circulatory levels of calcitriol are found
  
  • Low calcitriol levels contribute to the hypocalcemia seen in advanced CKD
  • Worsened renal function (less 1-alpha-hydroxylase enzyme), 25-hydroxyvitamin D deficiency, and increased FGF-23/phosphorus levels all play a role in decreasing calcitriol levels

Question 28

Common complications of CKD:
Mineral & bone disease:
Calcium

• Elevated serum phosphorus
• Intestinal absorption of Ca…
• When GFR < 30%…

Answer 28

• Elevated serum phosphorus
  
  • Causes Ca-Phos deposits
  • Decreases serum Ca
• Intestinal absorption of Ca progressively decreases with advancing renal disease, in part due to a lack of 1,25 (OH)2D3
  
  • Relatively low Ca state stimulates PTH release
  • Elevated PTH helps maintain normocalcemia
• When GFR < 30%, serum Ca may fall
  
  • Frank hypocalcemia is relatively uncommon until advanced CKD (GFR < 10-15 ml/min)
  • This homeostasis comes at the cost of elevated PTH levels

Question 29

Common complications of CKD:
Mineral & bone disease:
Parathyroid hormone (PTH)

• Among the earliest detectable abnormalities in CKD
• 2 main inhibitors of PTH
• Reactive elevation in PTH
• PTH normally stimulates…
• CKD skeletal resistance
• CKD also…
• Secondary hyperparathyroidism

Answer 29

• Among the earliest detectable abnormalities in CKD
  
  • Increased PTH
  • Can occur at a GFR = ~45-60 ml/min or earlier
• 2 main inhibitors of PTH
  
  • (1) Ionized Ca
  • (2) 1,25 (OH)2D3 (calcitriol)
  • Both are reduced in CKD
• Reactive elevation in PTH
  
  • Due to elevated phosphorus, decreased calcium, and low 1, 25 (OH)2D3 levels
  • Partially adaptive in the setting of CKD
• PTH normally stimulates…
  
  • Renal phosphorus excretion
    
    • Brings phosphorus levels down towards normal
  • Renal tubular Ca reabsorption
    
    • Increases serum Ca
  • Bone resorption
    
    • Increases serum Ca
  • Increased synthesis of 1 alpha hydroxylase in the kidney
    
    • Enhances renal conversion of 25OH-VitD to calcitriol
    • Augments GI Ca absorption
• CKD pts demonstrate skeletal resistance to PTH action
  
  • Higher levels are required to induce a given amount of Ca resorption from bone
  • Due to reduction in the number of PTH receptors on bone
• CKD also…
  
  • Decreases efficient production of calcitriol
    
    • Limits possible GI augmentation of Ca absorption
  • Llimits Vit D negative feedback on PTH
• Secondary hyperparathyroidism
  
  • Skeletal resistance to PTH + decreased production of calcitriol + progressive phosphate retention (as GFR worsens) + the decreased Ca levels –> further elevations in PTH
  • Maintains normocalcemia despite reduced calcitriol levels
  • Increases phosphorus excretion by the kidney by reducing reabsorption
  • Does this at the cost of increased PTH & bone resporption

Question 30

Mineral & bone disease summary

Answer 30

• Hyperphosphatemia
• 1,25 (OH)2 D deficiency (calcitriol)
• Hypoclacemia
• Secondary hyperpraathyroidism
• Results of these disturbacnes
  
  • Renal osteodystrophy (includes osteitis fibrosa)
  • Rickets / osteomalacia
  • Adynamic bone disease

Question 31

Common complications of CKD:
Osteodystrophy:
Osteitis fibrosa

• Occurs in…
• Driven by…
• Bone turnover
• Clinical manifestations

Answer 31

• Occurs in ~40% of ESRD pts
• Driven by secondary hyperparathyroidism
• Bone turnover is increased with increased osteoblast and osteoclast activity
  
  • –> weakened bones
    
    • –> increased osteoid (unmineralized bone)
    • –> increased peritrabecular fibrosis
• Clinical manifestations
  
  • Joint aches, bony pain, pruritus, increased risk of fractures
  • Extraskeletal calcifications (e.g., vascular)
  • Infrequent but dreaded, calciphylaxis (medial calcification of the arterioles leading to ischemia and subcutaneous necrosis)

Question 32

Common complications of CKD:
Osteodystrophy:
Adynamic bone disease

• Occurs
• General
• Due to…
• Risk factors
• Over suppression of PTH –>
• Decreased bone activity –>

Answer 32

• Occurs in ~40% of ESRD pts
• Bone turnover is decreased and fracture risk is elevated
• Due to…
  
  • Calcitriol deficiency
  • PTH resistance
  • Excessive suppression of parathyroid glands while trying to prevent/treat osteitis fibrosa
• Risk factors
  
  • DM
  • Advanced age
  • Peritoneal dialysis
• Over suppression of PTH –> reduced osteoblastic and osteoclastic activity
  
  • Decreased bone formation & bone mass
• Decreased bone activity –>
  
  • Increased extraskeletal calcifications (bone not available to take up Ca, Phos)
  • Fracture risk (higher than osteitis fibrosa)

Question 33

Common complications of CKD:
Osteodystrophy:
Rickets & osteomalacia

• Children
• Adults
• Occurs in…
• General
• Due to…

Answer 33

• Children: rickets
• Adults: osteomalacia
• Occurs in <5% of ESRD (uncommon)
• General
  
  • Defective mineralization of osteoid
  • Bone turnover is decreased
• Due to Vitamin D deficiency or aluminum deposition
  
  • When aluminum based phosphate binders were used in the past, they are now avoided

Question 34

Common complications of CKD:
Osteodystrophy:
Mixed renal osteodystrophy

• Mix of…
• Pts can also develop…

Answer 34

• Mix of…
  
  • Osteitis fibrosa
  • Adynamic bone disease
  • Rickets / osteomalacia
• Pts can also develop soft tissue calcifications from deposition of calcium phosphorus in the skin
  
  • Calcification in the small blood vessels in skin –> necrosis of skin and fatty tissue –> rare, but excruciatingly painful and life-threatening calciphylaxis
  • Pprimary cause of death in calciphylaxis: secondary infection of the ulcers, and sepsis