21 Renal Replacement Therapy: Dialysis Transplantation

Question 1

End stage renal disease (ESRD)

• Definition
• Incidence & prevalence
• Causes
• Treatment
• Mortality
• Economic costs

Answer 1

• Definition
  
  • Permanent kidney failure requiring dialysis or transplant
• Incidence & prevalence
  
  • > 600,000 ppl in the US
  • ~100,000 new pts per year
  • Rate of new cases: 4x higher in African Americans than whites.
• Causes
  
  • DM
  • HTN
  • Glomerulonephritis
  • Cystic kidney diseases
• Treatment
  
  • Hemodialysis (in-center, home) – 64%
  • Renal transplant– 30%
  • Peritoneal dialysis – 6%
• Mortality
  
  • 7x higher for dialysis pts than general population
  • Transplant pts similar to non-ESRD pts
• Economic costs
  
  • $50 billion/yr
  • Largely covered by Medicare

Question 2

Initiation of dialysis / renal replacement therapy

• Indications
• Goals
• 4 elements of hemodialysis

Answer 2

• Indications
  
  • A – Acidosis
  • E – Electrolyte abnormalities (esp hyperkalemia w/ EKG changes
  • I – Intoxications w/ water soluble drugs
  • O – Overload w/ salt & water that is refractory to diuretics & cardiac drugs & causes pulmonary edema, CHF, & HTN
  • U – Uremic symptoms including pericarditis, uremic bleeding, intractable nausea/vomiting, & anorexia
• Goals
  
  • Remove uremic waste products & correct the secondary effects of uremia
  • Replenish calcium & bicarbonate stores
  • Remove excess water & salt
• 4 elements of hemodialysis
  
  • Vascular access
  • Dialysis filter (dialyzer)
  • Dialysis solution (dialysate)
  • Dialysis machine to power and mechanically monitor the procedure

Question 3

Removal of solute occurs primarily by diffusion

• Diffusion rates are determined by…
• The amount of diffusion that occurs is also dependent on…
• Blood and dialysate flow
• Low MW substances are dependent on…
• High MW substances are dependent on…
• Dialysate is composed of…

Answer 3

• Diffusion rates are determined by…
  
  • Conc gradient of dissolved solutes on either side of the dialyzing membrane
  • Surface area and pore sizes of the dialyzing membrane
• The amount of diffusion that occurs is also dependent on…
  
  • Dialysate delivery rate
    
    • ~500 mL/min of dialysate bathes the dialyzing membrane
  • Rate of blood flow pumped through the dialyzer
    
    • 300-400 mL/min, depending on the type of dialyzer & adequacy of the pt’s access
• Blood and dialysate flow
  
  • Opposite directions (countercurrent) to maintain the conc gradient
• Low MW substances are dependent on…
  
  • Flow rate
• High MW substances are dependent on…
  
  • Surface area and pore size
• Dialysate is composed of…
  
  • Sodium 135-145 mEq/L
  • Potassium 0-4 mEq/L
  • Calcium 2.5-3.5 mEq/L
  • Magnesium 0.5-0.75 mEq/L
  • Chloride 98-124 mEq/L
  • Bicarbonate 30-40 mEq/L
  • Dextrose 11 mEq/L

Question 4

Removal of solvent occurs primarily by ultrafiltration

• Water molecule size
• Water molecule movement
• Convective transport

Answer 4

• Water molecule size
  
  • Small enough that they pass freely between the blood and dialysate compartments
• Water molecule movement
  
  • Driven in one direction by increasing the hydrostatic pressure gradient between compartments
  • Achieved practically by increasing resistance to blood flow as it leaves the dialyzer
• Convective transport
  
  • Any molecules small enough will be carried with solvent (solvent drag)

Question 5

Vascular access for hemodialysis

• Arteriovenous (AV) fistulas
  
  • Primary or “native” AV fistula
  • Use
  • “Fistula first”
• Synthetic AV fistulas (AV grafts)
  
  • Use
  • Construction
  • Adverse effects
• Hemodialysis catheters
  
  • Temporary hemodialysis catetheters
  • Placed in…
  • Tunneled dialysis cathether (TDC)
  • Adverse effects
• Access complications

Answer 5

• Arteriovenous (AV) fistulas
  
  • Primary or “native” AV fistula: anastomosis between an artery and vein
    
    • Transmission of high arterial pressure into a low pressure venous system –> high flow AV fistula
    • Over time the vein “arterializes”: increases diameter & wall thickness
  • Optimal access for hemodialysis
    
    • Require 6 - 8 weeks to mature
    • Should be created 6 - 12 months before dialysis will be needed
  • “Fistula first”
    
    • National vascular access improvement initiative to support AV fistula placement in suitable hemodialysis patients, while reducing central venous catheter use.
• Synthetic AV fistulas (AV grafts)
  
  • For pts w/ poor peripheral vasculature (diabetics) & insufficient venous size to allow the creation of a native AV fistula
  • Constructed of Polytetrafluoroethylene (PTFE)
    
    • Endothelialize in 2-3 weeks
    • This “maturation period” is necessary before they can be used.
  • Adverse effects
    
    • Higher rate of infection & clotting risk
    • Shorter lived than “native” AV fistulas
• Hemodialysis catheters
  
  • Temporary hemodialysis catetheters
    
    • For 30 - 50% of pts w/ advanced chronic renal failure require immediate dialysis
  • Placed in the internal jugular vein (or subclavian vein or femoral vein)
  • Tunneled dialysis cathether (TDC)
    
    • Placed if dialysis is required for > 3 weeks & construction of an AV fistula isn’t possible
    • Reduces the risk of infection
    • Avoid the subclavian site to reduce the risk of central venous stenosis
  • Adverse effects
    
    • Induction of venous stenosis
    • Poor flows
    • Thrombosis
• Access complications
  
  • Thrombosis
    
    • –> obstruction of the access & poor blood flow
    • Outflow obstruction in an AV fistula –> localized extremity swelling
  • Infection
    
    • Local infections
    • Sepsis or septic emboli to bone, heart valves or the lungs
  • Steal syndromes
    
    • AV fistulas can reduce blood flow to the hand distal to the anastomosis –> ischemia, pain, & gangrene.
  • Cardiac overload
    
    • An AV fistula increases CO by 10% –> high output CHF

Question 6

Hemodialysis prescription

Answer 6

• Dialyzer
  
  • Type and size
• Blood and dialysate flow rates
• Duration and frequency
  
  • 3x/week (MWF or TTS) for 4 hrs each treatment
• Dialysate composition
  
  • Typically adjust sodium, potassium, calcium, bicarbonate
• Ultrafiltration
  
  • Can specify the amount of fluid to be removed
• Anticoagulation
  
  • Usually heparin

Question 7

Complications of hemodialysis

• Acute intra-dialytic complications
• Chronic complications
• Dialysis survival rates

Answer 7

• Acute intra-dialytic complications
  
  • May occur during any dialysis session
  • HoTN
    
    • Due to excessive ultrafiltration, autonomic neuropathy or peripheral vasodilation
    • Usually responds to normal or hypertonic saline or administration of colloid in the form of salt poor albumin (SPA) or mannitol
  • Cramps
    
    • Due to HoTN or inappropriately low dialysate Na conc
    • Usually responds to saline, quinidine sulfate, muscle relaxant, or carnitine
  • Nausea & vomiting
    
    • Due to HoTN or the disequilibrium syndrome (too brisk a reduction in uremic waste products, usually seen with initiation of dialysis)
    • Usually responds to correction of HoTN & anti-emetics
  • Access issues
  • To prevent disequilibrium syndrome
    
    • Less rigorous treatments at initiation of dialysis
    • Gradually increase dialysis parameters to most efficient settings
• Chronic complications
  
  • Develop due to CKD & continue after dialysis started
  • Malnutrition
    
    • Best indicator of nutrition is serum albumin
    • Low albumin is a strong predictor of mortality
  • HTN
    
    • Treated w/ water & salt restriction & meds
  • Hyperlipidemia
    
    • Increased triglycerides & LDL w/ decreased HDL
  • Pruritus
    
    • Due to uremic toxins, elevated calcium-phosphorous product (>65), dry skin or allergies to components of the dialyzer or dialysate.
  • Mortality
    
    • Major cause of death is CV disease
  • Access issues
• Dialysis survival rates
  
  • 80% at 1 yr
  • 50% at 3 yrs
  • 33% at 5 yrs
  • 10% at 10 yrs

Question 8

Principles of peritoneal dialysis

• Peritoneal dialysis definition
• Peritoneal dialysis procedure
• Peritoneal “dialysis” membrane
• Water removal
  
  • Ultrafiltration
  • Forces affecting ultrafiltration
    
    • Osmotic gradient
      
      • Water movement
      • Major osmotic driving force in peritoneal dialysis
    • Hydrostatic pressure

Answer 8

• Peritoneal dialysis definition
  
  • Fluid and solute exchange between the peritoneal membrane capillary blood and dialysis solution in the peritoneal cavity
• Peritoneal dialysis procedure
  
  • Peritoneal membrane is used as a dialyzing membrane
  • Dialysate fluid is instilled into the abdomen & left for a period of time (dwell time) to absorb waste & remove fluid, then drained & discarded
  • Cycles / “exchanges” are repeated 4-5x/day
• Peritoneal “dialysis” membrane
  
  • Vascular wall, interstitium, mesothelium & adjacent fluid films that make up the parietal and visceral peritoneal membrane
• Water removal occurs by ultrafiltration
  
  • Ultrafiltration
    
    • Bulk movement of water through a semipermeable membrane
    • Osmosis = this ‘diffusion of water”
    • Due to the interaction of solvent molecules w/ dissolved solute, ultrafiltration –> solute transport via “solvent drag”
  • Forces affecting ultrafiltration
    
    • Osmotic gradient
      
      • Diffs in solute conc across a semipermeable membrane –> water moves from more to less dilute solution
        
        • Water flux will continue until the conc of osmotically active particles is equal on either side of the semipermeable membrane
      • Major osmotic driving force in peritoneal dialysis: supplied by dialysate glucose conc
        
        • Increase glucose conc –> increase ultrafiltration
        • This effect will dissipate as glucose is absorbed and as it is diluted out by water flux
    • Hydrostatic pressure
      
      • Causes some fluid movement
      • Plays a minor role in PD

Question 9

Principles of peritoneal dialysis:
Diffusion rates of solute (electrolytes & uremic waste) removal are affected by…

• Conc gradient of dissolved solutes on either side of the dialyzing membrane
  
  • Greater difference –>
  • Gradients are dependent on…
  • Dialysate conc is similar to hemodialysis sol’n except…
• MW of the solute
• Charge on the solute
• Membrane resistances

Answer 9

• Conc gradient of dissolved solutes on either side of the dialyzing membrane
  
  • Greater difference in solute conc b/n the 2 compartments –> more rapid flux of that solute from high to low conc
  • Gradients are dependent on the delivery rates of dialysate and peritoneal blood flow rate
    
    • Peritoneal blood flow is relatively constant even in shock
  • Dialysate conc is similar to hemodialysis sol’n except…
    
    • Substitution of lactate for bicarbonate
      
      • Ca bicarb will precipitate if bicarb is mixed w/ Ca-containing sol’ns)
    • Large dextrose conc (1.5 – 4.25 %)
• MW of the solute
  
  • Larger MW –> slower it can move through membrane pores
• Charge on the solute
  
  • Charged particles are hindered as they pass through the lipid bilayer
• Membrane resistances
  
  • Peritoneal membrane can be altered by disease states
  • Acute peritonitis –> decreased membrane resistance & increased clearances
  • Repeated episodes of peritonitis –> scarring & slowed transport

Question 10

Peritoneal dialysis:
Advantages & disadvantages

• Advantages
  
  • Hemodynamic effects
  • Location
  • Process
  • Diet
  • Meds
• Disadvantages
  
  • Efficiency
  • Infection
  • Requires…
  • Long-term
  • Can’t be used in pts w/…
  • Can’t be used for…

Answer 10

• Advantages
  
  • Few hemodynamic effects
    
    • Method of choice in pts w/ a tenuous cardiac status
  • Done at home
    
    • Pts have greater freedom & independence for normal activities
    • Travel is easier
      
      • Supplies can be taken w/ the pt or delivered to the pt’s destination.
  • Process is continuous
    
    • Pts are less likely to have disequilibrium syndromes seen in hemodialysis where clearance is efficient but episodic
  • Diet is more liberal
  • Meds (ex. insulin, antibiotics) can be administered in the peritoneal dialysis sol’n
• Disadvantages
  
  • Gentler but less efficient form of dialysis
    
    • Dose may be inadequate in pts > 80 kg, who have lost residual renal function completely, or who are non-adherent with PD
  • Infection
    
    • Peritonitis due to poor technique: most common cause of transfer to hemodialysis
  • Requires compulsiveness & intellect
  • Pts on long-term PD can “burn out” due to the daily grind of doing their exchanges
  • Can’t be used in pts w/ peritoneal fibrosis or adhesions
    
    • Interferes w/ drainage
  • Can’t be used for > 1 week following abdominal surgery
    
    • Increases leaks at catheter site and infection

Question 11

Peritoneal dialysis:
Peritoneal access

• Standard access
• Procedure

Answer 11

• Standard access
  
  • 2 cuff Tenckhoff style catheter
  • Made of silicone (catheter) & Dacron (cuffs)
  • Variety of dif catheters are available
• Procedure
  
  • Catheter is inserted into the peritoneal cavity by a surgeon
  • Internal cuff is anchored in the muscle fascial layer immediately above the parietal peritoneum
  • Catheter is tunneled through the subcutaneous tissues & brought through the epithelium 5 - 10 cm lateral of where the internal cuff was seated
  • External cuff is usually 1 cm deep from the exit wound & causes local fibrosis, which seals the tunnel

Question 12

Types of peritoneal dialysis

• CAPD (Continuous Ambulatory Peritoneal Dialysis)
  
  • Procedure
  • Advantages
  • Disadvantages
• CCPD (Continuous Cycler Peritoneal Dialysis)
  
  • Procedure
  • Advantages
  • Disadvantages
• Less common

Answer 12

• CAPD (Continuous Ambulatory Peritoneal Dialysis)
  
  • Procedure
    
    • Instillation of 2 L of dialysate which dwells for 4 - 8 hours & then is drained
    • Repeated 4x/day
  • Advantages
    
    • Long dwell times–> max solute removal
    • Highest large solute clearances
    • Extremely portable.
  • Disadvantages
    
    • Manual exchanges –> increased risk of infection
    • Constant fluid in the abdomen may worsen gastroparesis
• CCPD (Continuous Cycler Peritoneal Dialysis)
  
  • Procedure
    
    • Pt connects to an automated peritoneal dialysis cycler at bedtime
      
      • Device periodically instills dialysate, allows it to dwell, then drains & replaces it in the pt’s abdomen
      • 3-5 exchanges / nocturnal period
    • Machine instills a fresh aliquot of dialysate before the pt awakens & disconnects
      
      • Exchange dwells during the day
      • Daytime exchange is drained at bedtime when the pt connects to the machine
    • Advantages
      
      • Increased convenience by eliminating daytime exchanges
      • Decreased manual hook-ups–> decreased chance of peritonitis
    • Disadvantages
      
      • Short dwell times –> ineffective large molecule clearance
      • Requires excellent catheter function
        
        • Poorly draining PD catheter may not allow rapid cycling at night
      • Constant fluid in the abdomen may worsen gastroparesis
      • Being attached to a machine at night may interfere with sexual function
• Less common
  
  • Combo of daytime exchanges & nocturnal cycling
  • Periods where the abdomen is “dry” (completely drained of fluid)

Question 13

Complications of peritoneal dialysis

• Mechanical
  
  • Intraluminal catheter occlusion due to fibrin
  • Catheter occlusion due to a full colon (constipation)
  • Catheter malposition or kinks
• Dialysate leaks
• Subcutaneous dialysate leaks
  
  • Past the internal cuff into the subcutaneous tissues
  • Along the processus vaginalis
• Infections
  
  • Can involve…
  • Most torublesome PD infection

Answer 13

• Mechanical
  
  • Intraluminal catheter occlusion due to fibrin
    
    • Occurs due to direct catheter irritation of the peritoneal membrane
    • Treatable w/ intraperitoneal heparin
  • Catheter occlusion due to a full colon (constipation)
    
    • Laxative treatment allows the catheter to reposition in the pelvic basin
    • In refractory cases, catheter replacement may be required
  • Catheter malposition or kinks
    
    • Requires catheter replacement
    • May be able to reposition w/ stiff wire under fluoroscopy
• Dialysate leaks
  
  • Peritoneal-pleural dialysate leaks
    
    • Via large pores in the diaphragm –> pleural effusions
  • May require switch to hemodialysis
• Subcutaneous dialysate leaks
  
  • Past the internal cuff into the subcutaneous tissues
    
    • –> soft tissue swelling
    • Resolves by allowing periods of time with a dry abdomen
    • May require new catheter
  • Along the processus vaginalis
    
    • –> swelling of the scrotum or labia major
    • Seen with inguinal hernias
    • Requires hernia repair or reinforcement of the internal ring of the inguinal canal
• Infections
  
  • Can involve…
    
    • Peritoneal cavity (peritonitis)
    • Catheter tunnel (tunnel infection)
    • Exit site (exit site infection)
  • Most troublesome PD infection: peritonitis

Question 14

Renal transplantation:
Process

• Major problem
• Patients w/ CKD are usually referred for transplant evaluation when…
• Goal
• Pt evaluation
  
  • Cardiac health
  • Malignancy screening
  • Infectious disease
  • HLA-typing or tissue typing
  • Social issues
• Once the patient has successfully fulfilled these requirements…

Answer 14

• Major problem
  
  • Lack of donor organs (17,000 transplants / 90,000 pts)
• Patients w/ CKD are usually referred for transplant evaluation when…
  
  • Creatinine clearance < 20 ml/min
• Goal
  
  • Transplantation before dialysis since post-operative management & graft survival is usually improved
• Pt evaluation
  
  • Cardiac health
    
    • Cardiac disease is common in pts w/ CKD & is the leading cause of death in transplant recipients
    • Usually stress test + echo
  • Malignancy screening (ex.s)
    
    • Mammography for breast cancer
    • Prostate specific antigen for prostate cancer
    • Colonoscopy for colon cancer
  • Infectious disease
    
    • Screening for TB, hepatitis B or C, HIV, syphilis, & gonorrhea
    • Vital since immune suppressive therapy can increase the risk or severity of malignancy or an infectious disease
  • HLA-typing or tissue typing
    
    • To find the best “matched” kidneys for pts
  • Social issues
    
    • Pts w/ poor adherence to meds & current history of drug abuse won’t be listed until they change their behavior
    • Evidence of coercion or financial reward of a potential donor is also grounds for refusing a recipient a transplant
• Once the patient has successfully fulfilled these requirements…
  
  • Their name is entered on the transplant waiting list
  • Avg waiting time at UPMC: 3-5 years

Question 15

Renal transplantation:
Surgery

• Donor organs usually come from…
• Operation

Answer 15

• Donor organs usually come from…
  
  • Living donors (50%)
    
    • Living related donors (blood relatives)
    • Emotionally related donors (most commonly spouses)
    • ABO incompatible, + crossmatch
    • National kidney registry (NKR)
  • Brain dead or “deceased” donor (~7000/year)
    
    • SCD (standard criteria), ECD (expanded criteria), CDC high risk, DCD
• Operation
  
  • Takes 3-4 hours
  • Incision along the inguinal ligament in right or left lower abdominal quadrant
  • Transplanted organ is anastomosed into the common, external or internal iliac artery and vein and the ureter connected to the bladder.
  • Pt is usually hospitalized for 5 days
  • Follow-up afterwards is intensive w/ daily outpatient visits for several weeks
  • If the transplant recipient does well, follow-up intervals progressively increase

Question 16

Renal transplantation:
Outcomes

• Life expectancy for grafts
  
  • Living donor
  • Deceased donor
• % grafts surviving post-transplant
  
  • Living donor
    
    • 1 year
    • 5 years
  • Deceased donor
    
    • 1 year
    • 5 years
• % pts surviving post-transplant
  
  • Living donor
    
    • 1 year
    • 5 years
  • Deceased donor
    
    • 1 year
    • 5 years

Answer 16

• Life expectancy for grafts
  
  • Living donor: 15 years
  • Deceased donor: 10 years
• % grafts surviving post-transplant
  
  • Living donor
    
    • 1 year: 95%
    • 5 years: 80%
  • Deceased donor
    
    • 1 year: 90%
    • 5 years: 66%
• % pts surviving post-transplant
  
  • Living donor
    
    • 1 year: 98%
    • 5 years: 90%
  • Deceased donor
    
    • 1 year: 95%
    • 5 years: 80%

Question 17

Renal transplantation:
Immunosuppressive agents

• Corticosteroids
• Calcineurin Inhibitors (cyclosporine A and tacrolimus)
• Azathioprine
• Mycophenolate
• Sirolimus
• Belatacept

Answer 17

• Corticosteroids
  
  • Generalized suppression of the immune system
  • Prevent IL-1 and IL-6 production by macrophages
• Calcineurin Inhibitors (cyclosporine A and tacrolimus)
  
  • Block interleukin-2 release from T cells
  • Prevent T-cell mediated lymphocyte proliferation
• Azathioprine
  
  • Converts to 6-mercaptopurine
  • Inhibits DNA/RNA synthesis –> decreasing lymphocyte production
• Mycophenolate
  
  • Inhibits inosine monophosphate dehydrogenase (IMPDH)
    
    • Essential rate-limiting enzyme in the purine metabolic pathway
    • Catalyzes the de novo synthesis of guanine nucleotides required for lymphocyte proliferation
  • Decreases B and T lymphocyte production
• Sirolimus
  
  • Inhibits T-lymphocyte activation by suppressing IL-2 and IL-4 mediated proliferation
  • Inhibits B lymphocyte activity
• Belatacept
  
  • Co-stimulatory blockade

Question 18

Renal transplantation:
Post-transplant complications

Answer 18

• Leading cause of death is cardiac
• Second leading cause is infection
• Malignancy, esp skin cancer and lymphoma
• Recurrence of original glomerular disease
• Chronic rejection & eventual graft failure

Question 19

Renal transplantation:
Future directions

• Xenografts
• Stem Cells
• Wearable Artificial Kidney (WAK)
• Implantable Artificial Kidney

Answer 19

• Xenografts
  
  • Transplanted organs from immunologically altered animals
  • Porcine sources are closest to human beings in size
  • Potential risks: introduction of infection or cancer causing agents from the animal source
• Stem Cells
  
  • Could enable production of organs in vivo or in vitro
  • Science fiction at the present time
• Wearable Artificial Kidney (WAK)
  
  • Miniaturized dialysis machine which can be worn like a belt
  • Allows pts to move about freely while undergoing uninterrupted dialysis treatment
  • Weighs 10 pounds & requires a couple of 9V batteries
• Implantable Artificial Kidney
  
  • Thousands of nano-filters remove toxins from the blood
  • A BioCartridge of renal tubule cells mimics the metabolic and water-balance roles of the human kidney
  • Relies on the body’s BP to perform filtration w/o needing pumps or an electrical power supply
  • Not ready for clinical trials for another 5-7 years