OoCities
DISEASE EXAM II NOTES
Objectives
• Describe mechanisms involved in sodium and water homeostasis
• Discuss signs and symptoms of hyponatremia and hypernatremia
• Describe intracellular and extracellular potassium balance
• Discuss signs and symptoms of hypokalemia and hyperkalemia
• List common causes of chloride abnormalities
• Discuss briefly conditions causing magnesium abnormalities
• Discuss the relationship of vitamin D, parathyroid hormone in regulating
calcium and phosphorus balance.
Total body Water (TBW)
• Males – 60% or approximately 42 kg for a 70 kg man (more muscle mass)
•Females – 50% or approximately 35 kg for 70 kg female
- As you age, total body water decreases slightly
Fluid Compartments
• Intracellular (ICF)–66% of TBW
• Extracellular(ECF)-33% of TBW—moves freely
– Interstitial –80% of ECF
– Intravenous-20% of ECF
Fluid Compartments for 80 kg male
• TBW for 80 kg male = (80 kg) X (0.6) = 48 kg of water
• ICF = (48 kg) X (.66) = ≈32 kg
• ECF = (48 kg) X (0.33) = ≈16 kg
• Intravascular = (16 kg) X (0.2) = 3.2 kg or 3 L
• Interstitial = 16 kg X 0.8 = 12.8 kg or 13 L
• Whole blood – 5 liters
• Plasma – 3 liters
• Erythrocytes – 2 liters
- Can lose ~10% of blood volume (~ ½ liter) without significant effects
- 50%: not a survivable condition (duh!)
Fluid Requirements
• ≤10 kg = 100ml/kg/day
• 11-20 kg = 1000 ml + 50 ml/kg/day for every kg over 10 kg
• >20 kg = 1500 ml + 20 ml/kg for every kg over 20 kg
• Adults usually 30 ml/kg/day
- This is maintenance—will be more with fluid loss
**Note** In the revised slides he posted, several slides from the original lecture were omitted. Since he said his test questions come from the revised lecture, I did not include the slides he omitted.
Electrolyte Composition of Replacement Fluids
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Sodium
• Normal Range 135-145 mEq/Liter (we only measure the concentration)
• Functions
–Regulates serum osmolality
– Acid/base balance
– Transmembrane electrical balance
Sodium and Water Balance
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Changes in Water & Sodium in Hypernatremia & Hyponatremia
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Sodium Regulation
• Antidiuretic Hormone (ADH)
– Released from posterior pituitary in response to stimulus by the hypothalamus which responds to blood osmolality of the brain when osmolality is high. (High serum sodium or low serum water)
•Antidiuretic Hormone (ADH)
– Baroreceptors in left atrium and carotid sinuses will block ADH release if blood volume is normal preventing hypervolemia
•ADH secretion
–decreases urine output and sodium loss
–Increases collecting tubule permeability to water
–Concentrates urine
- Normal adult urine output is 0.5 ml/kg/hr
Aldosterone
• Released from the adrenal cortex in response to various dietary and
neurohormonal factors such as:
– Low serum sodium
– Low blood volume
– Angiotensin II
• Affects the distal tubule
• Increases the reabsorption of sodium and the secretion of potassium
Osmolality Effects
• Equilibrium maintained between intravascular, interstitial, and intracellular
compartments
• Water moves from areas of low osmolality to areas of high osmolality
Calculation of Osmolality (mOsm/Liter)
•Serum Osmolality (mOsm/L) = (2 X Serum Sodium) + (Serum Glucose/18) +
(Blood Urea Nitrogen/2.8)
•Normal Range = 280-300 mOsm/L
Chloride
• Normal Range 95-105 mEq/Liter
• Functions
– Predominate extracellular anion
– Acid-base balance (proximal tubule
bicarbonate production and exchange
with chloride)
– Passively follows sodium to maintain
electrical balance
Potassium
• Normal Range 3.5-5.0 mEq/Liter
• 4000 mEq total/50 mEq (~1%) extracellular( most K+ is inside cell
• Functions
– Muscle/nerve excitability
– Protein synthesis, carbohydrate metabolism
• Regulation of potassium
–pH
–Aldosterone
– Insulin/glucagon
–Distal and collecting tubule secretion
– Colon secretion
Magnesium
•Normal Range 1.5-2.2 mEq/Liter
•2000 mEq total, 50% bone(this Mg is not available for physiologic use), 45%
intracellular, 5% extracellular (1/3 protein bound)
• Functions
–Neuron/Muscle function
– Enzyme cofactor for phosphate transfer (ATP-dependent)
• Regulation not known
• Competition with calcium
- they counteract each other
Phosphorus
• Normal Range 2.6-4.5 mg/dl
• Major intracellular anion
• 85% in bone, 15% in ECF, cell membranes, and collagen
- the phosphorus in bone is relatively inactive
• Functions
– Intracellular protein, fat, and carbohydrate metabolism
– Major component of phospholipid membrane, RNA, NADP, and ADP production
– Buffer for acid-base balance
• Regulation
– Vitamin D
• ↑ calcium and phosphorus GI absorption, PTH-induced mobilization of calcium and phosphorus, calcium and phosphorus reabsorption in proximal tubule
– Parathyroid Hormone
• Maintain adequate ionized calcium, reabsorption of calcium and phosphorus from distal nephron, osteoclast activity
– pH
• Shifts phosphorus to balance pH
Calcium
• Normal Range 8.5-10.8 mg/dl
• 1000 g total, 0.5% extracellular fluid
– 6% complex bound
– 40% protein bound (albumin)
– 54% ionized
• Adjusted Ca+2 =Measured Ca+2 + [0.8 X (4.0 – Serum Albumin)]
• Functions
– Neuromuscular activity
– Regulation of endocrine function
• Pancreatic insulin release
• Gastric acid secretion
– Coagulation
– Platelet aggregation
– Bone and tooth metabolism
• Regulation of Calcium
– Vitamin D
• ↑ calcium GI absorption, PTH-induced mobilization of calcium, calcium reabsorption in proximal tubule
– Parathyroid Hormone
• Maintain adequate ionized calcium, reabsorption of calcium and phosphorus from distal nephron, osteoclast activity
– Calcitonin
• Inhibits osteoclasts activity ( inhibits breakdown of bone
Compartmental Electrolyte Composition
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Hyponatremia (Serum Sodium 20 mEq/L, urine osmolality >100 mOsm/kg H20
• Usual causes-
– Hypotonic fluid loss (diarrhea, sweating), excessive diuresis (loops), burns over large area of body
• Treatment – replace free water deficit, correct underlying cause, reduce or
discontinue diuretics
• Free water deficit (L) = [1- (140/current Na)] x TBW (L)
Hypernatremia (Serum Sodium >145 mEq/L); Correction of Free Water Deficit
• Free water deficit (L) = [1 - (140/current Na)] X TBW (L)
•100 kg male with Sodium –150 mEq/L
• Free water deficit (L) = [1- (140/150)] X 60 (L) = 4 liters
- He also needs normal maintenance of 30 ml/kg/day ( 3000 ml + 4 L = 7 L
- usually give 1-2 liters very fast, then look at urine output and make up blance over 24 to 48 hours
(Refer as needed to Electrolyte Composition of Replacement Fluids in table above to apply to these different states)
Hypernatremia (Serum Sodium >145 mEq/L)
• Hypervolemic, Hypernatremia
– BP and urine output are normal
– Mucous membranes normal, skin turgor normal to “translucent ”, edema present
– Serum sodium, osmolality are high
– Urine sodium >20 mEq/L, urine osmolality >100 mOsm/kg H20 (body trying to get rid of Na+)
• Usual causes-
– Excessive intake of sodium
• Treatment – salt & water restriction ± diuretics (usually don’t have to use
diuretics)
• Isovolemic, Hypernatremia
– BP normal, urine output increased
– Mucous membranes normal, skin turgor normal
– Serum sodium, osmolality are high
– Urine sodium 10 mEq/L)
- Calcium and magnesium compete for same sites—not really lowering Mg level,
except for forcing body to excrete Mg
ACID BASE DISORDERS
I. Definition
Acid/Base disorders are marked by H+ ion disturbances in homeostasis which is
normally maintained by:
1) Extracellular Buffering
2) Renal Regulation of H+ ion and HCO3-
3) Ventilatory regulation of CO2 loss
II. General Pathophysiology
Buffering refers to the ability of solution to resist pH change with addition of strong
acid or base. In humans, principle ECF buffer system is H2CO3/HCO3- (Carbonic
acid/Bicarbonate)
- electroconductivity is altered ( can cause patient to go into cardiac arrest
Four Primary Acid/Base Disturbances
Those associated with gain or loss of H+ or HCO3- are:
1. Metabolic Acidosis
2. Metabolic Alkalosis
Those associated with the rise or fall of arterial CO2 tension (PaCO2) are:
3. Respiratory Acidosis
4. Respiratory Alkalosis
- Arterial blood is harder to draw, but is fresher and is therefore more accurate
Acid /Base disturbances may occur:
1. Independently (e.g., Overdose of ASA)
or
2. In a complementary compensatory response – e.g., acidic in kidneys ( blow
off CO2
Diagnosis of ABG’s
Refer to Article: “Turn ABGs into Child’s Play”
- pH of the blood is an indication of the [H+] what is this formula???
pH = pKa – log [HA]/[A-]
Remember These Ranges
pH of normal arterial blood is: 7.35 - 7.45 (homeostasis)
pH of < 7.35 indicates acidosis
pH of >7.45 indicates alkalosis
Acidosis
- pH of < 7.35 indicates acidosis with two possible causes:
1. Increase in amount of Acidic Substances (DKA)
2. Decrease in amount of Basic Substances (bicarb)
Alkalosis
- A pH of > 7.45 indicates alkalosis with two possible causes:
1. Increase in the amount of alkaline substances
or
2. Decrease in the amount of acid substances
- increased tidal volume ( blowing off CO2
- Since CO2 combines with H2O in the blood to form carbonic acid (H2CO3)
it is considered an acid.
- Therefore, CO2 is a respiratory parameter affecting pH.
Remember These Ranges
- Normal partial pressure of CO2 in blood (PaCO2) ranges from 35-45 mm of Hg
- When PaCO2 is high (>45) as seen in COPD the pH drops resulting in respiratory
acidosis (can’t breathe well)
- When PaCO2 is low ( 7.45 |
|PaCO2 |> 45 |35 – 45 |< 35 |
|HCO3- |< 22 |22 – 26 |> 26 |
- The body strives to maintain a normal pH. When diseases or other conditions
upset homeostasis, healthy lungs or kidney may work to offset fluctuations in pH.
- In COPD, a patient may hypoventilate and cause CO2 to rise. The result will be a respiratory acidosis. The kidneys may compensate by excreting H+ and absorb more HCO3
Questions That Require Answers
To diagnose an acid/base balance disorder 3 questions need to be answered:
1) Does the pH indicate acidosis or alkalosis?
2) Is the cause of the pH imbalance respiratory is it of metabolic origin?
3) Is there compensation for the acid/base imbalance?
Apply Grid Technique to Find Answers
Consider the following patient:
60 yo wm with uncontrolled DM Type 1 has the following ABGs:
pH = 7.26
PaCO2 = 42 mm Hg
HCO3 = 17 mEq
- If pH and PaCO2 fall into the same column (other than normal) the disorder may be categorized as Respiratory Acid Normal Alkaline
|Acid |Normal |Alkaline |
|pH (7.26) |PaCO2 (42) | |
|HCO3- (17) | | |
- However, if as in the example above, pH and HCO3 fall in the same column (other than normal) the disorder is termed Metabolic
(Case Continued)
- Next, look at the parameter not associated with pH. In this patient’s case it is PaCO2.
- It is in the normal range, therefore there is no evidence of compensation.
- Therefore the condition is: Acute Metabolic Acidosis without Compensation
Case to Analyze for Next Class
- Patient Mr. Cough is a 54 yo bm with COPD, has had SOB for two days and
currently smokes 2.5 packs per day. His ABGs are as follows:
pH = 7.26, PaCO2 = 52, and HCO3 is 34
- What type of acid/base disorder does Mr. Cough suffer from and is
compensation present?
|Acid |Normal |Alkaline |
|pH (7.26) | |HCO3 (34) |
|PaCO2 (52) | | |
Respiratory Acidosis with Compensation
- Readings from pages 998 – 1011
Acid/Base Balance (review only) pages 995 – 996
We Completed Diagnosis of Acid/Base Disorders, now on to Primary Conditions causing these Disorders
I. Respiratory Alkalosis
A. Pathophysiology -- low PaCO2 (hypocapnia) occurs when ventilation excretion exceeds production because of hyperventilation
- capnia = smoke
B. Causes: Hyperpnea, Fever, Anxiety, Cerebral Disease (Tumor or Vascular Accident)
Symptoms and Treatment of Respiratory Alkalosis
C. Symptoms: Numbness, Tingling, Nausea/Vomiting, Light headedness
D. Treatment:
1) Direct measures to treat underlying cause: Fever/Pain/OD
2) Rebreathing CO2 - Paper Bag
II. Respiratory Acidosis
A. Pathophysiology: initially caused by primary retention of CO2 therefore lower blood pH results in a compensatory response of increase in HCO3
B. Results from disorders that restrict or decrease ventilation or increase CO2 production or perfusion abnormalities (pulmonary embolism or cardiac arrest)
-Other Abnormalities Likely to Cause Respiratory Acidosis:
- COPD
- Pulmonary Edema
- Pneumonia
- Neuromuscular Insults:
- Trauma
- Stroke
- Narcotic Overdose
C. Clinical Picture of Respiratory Acidosis
- Altered Mental Status – lack of oxygen getting to brain
- Seizures
- Stupor
- Coma
- Altered cardiac contractility
D. Treatment Recommendations:
- If patient is hypoxic, provide adequate ventilation
- Most importantly treat the underlying cause aggressively!
- If Narcotic Overdose -- Reverse with antagonist
- Suggestions???
- What about multiple drugs with BZDs?
- Overdose on TCA’s with BZDs may be beneficial because BZD counteracts seizures caused by TCAs ( best treatment is to put patient on ventilator
III. Metabolic Alkalosis
A. Pathophysiology: Characterized by increase in HCO3 in plasma
- If patient has fluid loss, will make bicarb appear high
- Initiating Events can be characterized as
1) NaCl Responsive
2) NaCl Resistant
Most Common Initiating Events for Metabolic Alkalosis are:
- HCO3 is gained because of diuretics reducing fluid volume
- Nasogastric suctioning
- Prolonged vomiting
- These above events are considered NaCl responsive
- Don’t give NaCl to CHF patient because it will cause fluid buildup
NaCl Resistant Disorders
- Resistant Disorders are associated with excess
mineralocorticoid activity:
- Cushing’s Syndrome
- Aldosteronism
- Pheochromocytoma
Clinical Pearls
- NaCl responsive disorders are usually associated with urinary Cl- of approximately 10 mEq
- NaCl resistant disorders are usually associated with urinary Cl- of greater than 20 mEq
B.Clinical Picture of Metabolic Alkalosis
- Not terribly unique
- Patient may complain of muscle weakness this due usually to potassium depletion
- Patient may complain of muscle weakness due to volume depletion
C. Diagnoses of Metabolic Alkalosis Etiology
- Based more on patient history rather than laboratory data
- Look for history or nursing notes mentioning any of the following:
- Vomiting
- Nasogastric Intubation
- Diuretics
D. Treatment of Metabolic Alkalosis
- Remember it will depend on whether the disorder is NaCl responsive or NaCl resistant
- For Responsive Type - Expand the intravascular volume and replenish chloride stores with NaCl or KCl solutions unless
patient has CHF
- For CHF patient utilize carbonic anhydrase inhibitor
NaCl Resistant Disorders
- For NaCl Resistant Disorders - treat the underlying condition:
- Remove excess mineralocorticoid activity
- Surgical excision of hyperactive tissue
IV. Metabolic Acidosis
A. Pathophysiology - results from low HCO3 due to renal losses, decreased
regeneration of bicarbonate in the kidneys, or due to acid ingestion (ideas)- 81 mg ASA looks like candy( likely for children to overdose
- The lungs attempt to compensate by blowing off CO2 by increasing the rate and depth of breathing (Kussmaul breathing)
Types of Metabolic Acidosis
- There are two types of metabolic acidoisis:
1. Non-anion gap acidosis
2. Positive anion gap acidosis
- How can you discern the difference?
Determining and Calculating Anion Gap
- The Number of positively charged ions in the plasma must equal the negatively charged ions:
Na+ = Cl- + HCO3- + unmeasured ions
- Unmeasured anions consist of plasma proteins, and negatively charged ions like SO4 and PO4 not usually seen in typical clinical laboratory tests
- Unmeasured anions have a combined ionic strength of some 8 to 16 mmoles/L or (8 to 16 mEq/L)
- This value of 8 - 16 mEq/L is called the anion gap and rarely changes
- Let’s take a couple of sample cases and determine some anion gaps (I can’t wait!)
Case 1
- Pt. 60 yo male with 3 day history of n/v due to food poisoning
- Initial Lab Data Includes:
- Sodium 133 mEq/L
- Potassium 2.8 mEq/L
- Chloride 118 mEq/L
- pH 7.22
- pCO2 12 mm Hg
- Bicarbonate 6 mEq/l
- Calculate anion gap
6 mEq/L Bicarbonate
+118 mEq/L Chloride
124 mEq/l
133 mEq/L Sodium
- 124 mEq/L Bicarbonate and Chloride
9 mEq/L normal gap (within 8-16)
Case 2
- Pt. DM 1 with extended n/v from flu, no insulin in 3 days admitted to hx
- Initial Laboratory Data includes:
- Sodium 159 mEq/L
- Potassium 3.0 mEq/L
- Chloride 120 mEq/L
- pH 7.2
- pCO2 12 mm Hg
- Bicarbonate 6 mEq/L
- Calculate Anion Gap
6 mEq/L Bicarbonate
+ 120 mEq/L Chloride
126 mEq/L
159 mEq/L Sodium
- 126 mEq/L anions (Potassium and Cl)
33 mEq/L positive gap (ketoacidosis)
B. Clinical Picture of Metabolic Acidosis
- Hyperpnea (normal = 12 – 20)
- Kussmaul’s respirations: 30 – 34, usually
- Flushing of skin
- Tachycardia
C. Diagnosis of Underlying Condition causing the Metabolic Acidosis
1. If Normal Anion Gap of 8-16 mEq/l
- Use Mneumonic “D R A B” suspect:
Diarrhea
Renal Tubular Acidosis
Acetazolamide
Bricker’s Pouch (fistulae) – opening in abdominal area—lose fluid
2. If Positive A nion Gap Exists 17 mEq/L or greater
- Utilize Mneumonic “SLUMPED”
Salicylates
Lactic Acidosis
Uremia
Methanol
Paraldehyde
Ethanol
Diabetes
D. Treatment of Metabolic Acidosis
1. For Non-anion gap - correct underlying cause and replace bicarbonate deficit
2. For positive anion gap – always correction of the underlying problem, only give bicarbonate if pH is below 7.1
- usually recommend 1 or 2 amupules because cardiac function is at risk
- Never aggressively change plasma pH relative to that in the CNS—seizures may result
ACUTE RENAL FAILURE
Objectives
• Understand the pathophysiology of ARF
• Identify patient’s ARF as pre-renal, intrinsic, or post- renal based on Hx, physical
findings and evaluation of blood and urine
• Describe and understand the role of different medications used in ARF
• Given a patient in ARF student would rationalize the different approaches
needed to control the patient’s condition
Indications for Dialysis:
Acid/Base Imbalance (Acidosis)
Electrolyte Imbalance
Ingestion
Overload of volume
Uremia
Creatinine is a byproduct of metabolism of muscle breakdown; normal = 0.5 – 1.5 mg/dL
Ideal Marker to Measure Kidney Function Creatinine
1. Must be completely excreted by kidneys Π
2. Should not be reabsorbed Π
3. Should not be secreted ⊆-- ~10% secreted
4. Should not be metabolized by kidneys
5. Should not affect kidney function itself
Markers
1. Inulin – polysaccharide which meets all of the above criteria
- However, it must be given to patient since it is not endogenous
- Also is expensive; there are certain techniques needed to identify it
2. Sinistrin – polysaccharide
3. Iothalmate – dye ( bad effect on kidney
4. Iohexal – low molecular weight
5. Cystatin C – non-glycolsylated protein produced by body and independent
of gender, body mass, and inflammatory conditions
Physiological Factors with Creatinine
1. Muscle mass – correlates with age, weight (obese patients have high Cr),
gender
2. Exercise – causes SCr to increase
3. Diurnal rhythm – active in morning; SCr peaks ~7:00 PM
4. Diet – increased SCr in those who eat high protein
5. Drugs – e.g., cimetidine, trmethoprim, probenicid—compete with secretion of
creatinine
- cimetidine competes with SCr, so it gets completely filtered and gives an accurate value
- The overestimation from basal: 30 ( 3%--gave 400 mg cimetidine ( caused ratio to change from 1.3 ( 1.03, giving accurate value
**Bear with me, I honestly thought this made sense at the time I took these notes**
Definitions
• ARF is defined as sudden, normally reversible impairment of the kidneys’ ability
to excrete the body’s nitrogenous waste products of metabolism
• Acute renal failure
– increase in SCr > 0.5mg/dl (baseline 1.0mg/dl (baseline >3mg/dl)
– decrease CrCl > 50%
– deterioration over several days resulting in the failure of kidney to excrete waste and maintain fluid and electrolyte balance
– decrease in renal function that results in need for dialysis
• Anuria
– < 50ml of urine qd
• Oliguria
– 50 - 400ml of urine qd
• Non-oliguria
– > 400ml of urine qd
- these patients do better in reversing their conditions ( 1st always try to switch patient from anuria to non-oliguria
• Azotemia
- increased BUN or nitrogenous waste; signs and symptoms of a decrease in GFR
[pic]
- SCr > 1, use 1
- In obese patient (>20% of IBW), use the following corrected weight:
Corrected weight = [(Actual wt – IBW)*0.4] + IBW
Epidemiology
• Occurs primarily to inpatients
– 2-5% of all inpatients develop (ICU 6-23%)
– 25% of patients with ARF unassociated with surgery or trauma die
– 50-70% with trauma ARF die
• ~ 1% of outpatients develop; >95% recover
• 30% of patient who experienced ARF will require RRT
- SUPPORT: Study to Understand Prognosis & Preferences for Outcomes and Risk of Treatment
- looked at expected 6 month mortality; QALY (cost figures for disease states) was almost 169,000 for ARF; 45,000 for MI; 31,000 for HTN)
Two Types of Risk Factors for ARF
1. Modifiable
A. volume depletion (vomiting, hemorrhage, high diuretic intake)
B. IV contrat
- use of Mucomyst® may help
C. Nephrotoxic Agents
- Abx: aminoglycosides, amphotericin B
( use once-daily dosing for aminoglycosides
( rehydration
D. NSAIDs—both nonselective and COX-2
E. ACEI and ARB
F. Immunosuppressive agents
- cyclosporine; tacrolimus
G. obstruction
2. Non-Modifiable
A. Genetics
- kidney stones
B. DM
C. HTN
D. cancer
E. Infection/sepsis
F. Age
- at age 40, there is an annual decrease in GFR
Etiology
[pic]
- Body may adapt to a low GFR by increasing secretion of creatinine: SCr may
appear normal, even when there is failure
- use of cimetidine may have a role
Prerenal
• 70% of community acquired ARF
• 40% of hospital acquired
• Rapidly reversible in patients with normal baseline renal function
• NO structural defect in the kidney only a decrease in delivery of blood to
glomerulus (only when compensatory RAS is overwhelmed)
Prerenal – Decrease in Renal perfusion
• Hypovolemia
- dehydration, hemorrhage, diuresis
• Decrease cardiac output
- CHF, MI, drugs
• Decrease in vascular tone
- Sepsis ((severe HTN), drugs
• Decrease in intravascular volume
- third spacing, burns
• Increase in vascular tone (svere vasoconstriction will block flow of blood)
- drugs
• Blockage
- renal artery stenosis, emboli
Control of GFR (glomerular filtration rate)
• GFR is regulated by filtration pressure (intraglomerular pressure) and glomerular
blood flow
• Both of these are dependent on the afferent and efferent arteriole
• These arterioles work independent of each other
[pic]
[pic]
Prerenal – decrease in glomerular ultrafiltrate
• Drugs
– ACE, Ang-II receptor blocker
• Ang-II causes vasoconstriction of both afferent and efferent
arteriole
– NSAID
• Cause afferent vasoconstriction by decreasing afferent
vasodilatation prostoglandins (PGE2)
- Predisposing risk factors with NSAIDs:
- CHF, cirrhosis, nephrotic syndrome, chronic renal failure, hypovolemia, atherosclerotic disease of renal arteries
– Cylcosporin and tacrolimus
• Cause afferent vasoconstriction
– Radiocontrast
• Hypotension, renal vasoconstriction, osmotic diuresis, free radical production
- directly proportional to dose, molecular weight, and charge
- Risk factors for development of ARF with contrast:
- hypotension, CHF, hypokalemia, decreased renal function (CrCl < 35%), diabetic nephropathy, characteristics of the contrast dye (see above)
• Hepatorenal syndrome
– Afferent vasoconstriction (endothelin(secreted in blood vessels)
- treatment: new liver
- Some studies show that the following can “buy time”: octreotide, albumin, midodrine (vasoconstrictor)
Post Renal –Obstruction
• Accounts for < 5% of cases
• GFR decreases due to hydrostatic changes in the glomerulus
• No structural damage unless prolonged obstruction
• Must be bilateral and complete for anuria
• Common causes
– Drugs
– Tumor
– prostatic hypertrophy
– stones
Obstructive Nephropathy
• Uric acid (stones)
– Chemotherapy (tumor lysis syndrome), probenecid
- colchicine: pain control
- allopurinol: hyperuricemia
• Rhabdomyolysis
– Heroin, alcohol, statins, cocaine
• Tubular precipitation
– Acyclovir, Vit. C, Methotrexate, Sulfonamides, triamterene
Intrarenal
• Damage to kidney structure
• Classified according area of injury
• Glomerulus (Acute glomerulonephritis)
• Tubules (Acute Tubular Necrosis *ATN)
• Interstitial (Acute Interstitial nephritis)
• Vascular
• PRERENAL and POSTRENAL may lead to intrarenal
Acute Tubular Necrosis : ATN
• Most common cause of intrarenal ARF in hospitalized patients
• Usually a complication of meds, surgery, or sepsis
• Injury:
– Direct damage to tubule results in epithelial necrosis and sloughing
• Injury leads to
– Decrease in urine concentration ability
– Defective Na+ reabsorption
– Decrease in GFR
- three active transporters:
- cationic, anionic, or D glycoprotein
Causes of ATN
• Ischemia – from decrease in RBF
– Hypoxia worse in some areas of kidney
– Most reversible if caught early
• Toxins – tend to concentrate in tubule
– Exogenous (i.e., drugs)
– Endogenous
• Myoglobin, hemoglobin, uric acid
Acute Interstitial Nephritis : AIN
• Often reversible when offending agent is removed
• Interstitium provides structural support and concentration gradients
• Causes
– *Drugs
– Infection
• Streptococcal, viruses, others
- usually non-oliguric
Acute Glomerulonephritis
• Uncommon (incidence 2 – 4%)
• Alteration in structure and functional integrity of glomerular capillary circulation
• Proliferation of membrane or infiltration of inflammatory cells
• Can rapidly progress to ESRD
• Major causes
- Idiopathic
- Drugs – NSAIDS, Gold
- SLE
- use immunosuppressive agents
- many times present with proteinuria, hemoblobinuria
- dysmorphic erythrocytes is characteristic
Diagnostic Approach
This is key since early intervention improves prognosis
Must look at history along with lab and physical findings
• **Detail Medical & Medication history**
– Does the patient have chronic disease already?
– Are you in hospital or out?
– What other disease states does the patient have?
– What drugs is the patient on?
– How long have they been on them?
– Have they had trouble urinating or had increase force of stream? (e.g., with obstruction)
– Is there blood in their urine?
Laboratory Testing
[pic]
[pic]
- FeNa = fraction Na excreted
Other Diagnostic
• Radiologic
– KUB – Kidney, Ureter, Bladder
- shocked ureters: ureters is usually dilated in patients who are passing stones
• Renal ultrasound/CT—not that specific/sensitive
• Imaging – bad because contrast dye will exacerbate condition
– Radiopharmaceutical
• Biopsy
– Glomerular disease suspected
Clinical Course
• Initiation Phase
– Significant change in hemodynamic and renal function
• Oliguric Phase ~ 14 days
– Diminished urine production and increase metabolic byproducts
• Diuretic Phase ~ 2-4 days
- Increase in urine and decrease in SCr and BUN
• Recovery Phase – may take weeks to a year
Keys to treatment
• PREVENTION
• CORRECT UNDERLYING DISORDER
• GO FROM ANURIA TO NONOLIGURIA
– No drugs have been proven in randomized trials
- non-oliguric patients are less likely to need renal replacement therapy
• MANAGE COMPLICATIONS
Treatment - Prevention
• Identify patients at risk
– Elderly
– Pre-existing renal insufficiency
– Co-morbid conditions
• Shock, infection, liver disease, CHF, diabetes
– Females
– CCB prior to organ transplant
– Theophylline prior to contrast dye adminstr.
- now hydration is given 1st: Mucomyst given with ½NS
- mannitol has been added to organ preserving solution when kidneys are removed
Treatment – Prevention of Drug toxicity
• Total cumulative dose
• Maintenance dose
• Prolong therapy
• Concomitant renal toxic drugs
• Hydration – esp. dyes, ampho B, cisplatin
• Monitor for dysfunction
STOP THE DRUG
Treatment - Anuria to nonoliguria
• Fluid Management
– Maintain hydration
• In’s and out’s
• daily wts
• hemodynamics
– Improves perfusion & lowers tubular workload
• Reduce need to concentrate urine
• Reduce nephrotoxin concentration
• Volume depletion
– Colloids or crystalloids
- crystalloids: preferred—NS or Lactated Ringer’s
- colloids are not really preferred; associated with increase in mortality, with exception of hepatorenal syndrome
• *Volume overload (if you overhydrate patient)
– May respond to diuretics
– Dialysis
– Fluid restriction
- look for at least 0.5 ml/kg/hr
Treatment - Anuria to nonoliguria– Diuretics
Initiate as soon as possible
• Loops (furosemide, bumetanide, torsemide, ethacrynic acid )
- ethacrynic acid: used when sulfa allergy exists
– MOA – increase urine flow, renal vasodilatation
– Give furosemide bolus 100mg IV
– May need continuous infusion of 500-1500mg qd (do not exceed 4mg/min – ototoxicity)
– Monitor – urine output, electrolytes, volume, BP
- give loading dose of 0.1 mg/kg; continuous infusion of 0.1 mg/kg/hr
- Some conditions with diuretic resistance:
1. Excessive Na intake ( decrease Na intake
2. Inadequate dose/regimen ( increase dose, use infusion, may even add a thiazide (metolazone, Zaroxolyn®)
3. Decrease in oral bioavailability (especially furosemide)
4. Nephrotic syndrome
5. Decreased renal blood flow (RBF)
6. Increased Na reabsorption (e.g., with NSAIDs, CHF, on diuretic for a long time)
7. ATN
• Mannitol
– MOA – increase osmotic pressure of filtrate inhibiting reabsorption and increases urine output; free radical scavenging effect
– Use in hypovolemic patients
– X 2 bolus doses (of fluid), if no response stop due to accumulation that can lead to CHF, HTN, and pulmonary edema
– Monitor – urine output electrolytes, volume status
• Thiazides
– In combo, if you do not get response with CI loop
– Work at distal tubule
Treatment - Anuria to nonoliguria
• Dopamine – no statistical difference from just giving fluid (study: NORASEPT)
– MOA – renal artery vasodilatation
– *Dose – 1-5mcg/kg/min
– Monitor – urine output
- it is now believed that even with the lowest dose of DA, there is still a β1 effect)
• Calcium Channel Blocker ?
– Give before and after insult?
• Insulin like growth factor ?
• Atrial natriuretic factor ?
• Antioxidant therapy & intracellular adhesion molecules ?
• Fenoldopam (Corlopam®)??
Treatment - Complications
• Uremia
– Dialysis
• Ca / Phos
– See CRF
• Metabolic acidosis
– Dialysis
– IV/PO sodium bicarbonate—only when pH is really low (< 7.0)
• Malnutrition
– May have higher caloric needs
– Difficult due provide calories b/c of fluid restriction
– Need to minimize nitrogenous waste production
Treatment – Complications--Hyperkalemia
• > 5.5meq/dl – problem ARRHYTHMIA
• Causes
– Decrease excretion
– Drugs – ACE inhib, K+ sparing diuretics
– Redistribution due to acidosis
• As H+ levels increase more H+ moves into the cell in exchange for K+ increasing serum levels of K+
• Treatment – depends on urgency
• Urgent
– Calcium gluconate or calcium chloride – for arrhythmia
• Does not correct K+ concentration
• IV push
- also: sodium bicarbonate
– Insulin + glucose
• Insulin shifts potassium intracellularly
• Start drip with insulin and D50W
– Albuterol IV (or inhaled(doesn’t work well)
• Shifts K+ intracellularly
- even with inhaled β agonist, still wind up with arrhythmias
• Slow Onset
– Kayexalate – sodium polystyrene sulfonate
• Exchanges K+ for Na+ in GI tract
• Can be given orally or rectally with sorbitol
• Onset 2-12 hours
• Monitor: GI, electrolytes, Fluid overload
– Dialysis
• Most effective
• May take hours
• Monitor : see dialysis lecture
*– Avoid exogenous K+ and drugs
[pic]
Guidelines for Treatment:
1. Prevention: Prevention is Key!!
2. Early resuscitation
3. Treat reversible conditions
4. Nephrology onsultation
5. Prevent further damage
- monitoring and optimizing hemodynamics
- avoid hypotension and nephrotoxic agents
6. Start diuretics
- oliguric ( non-oliguric
7. RRT (Dialysis)
DRUG-INDUCED RENAL FAILURE
Introduction
• Frequently occurs in patients treated with diagnostic and therapeutic agents
• Could be manifested as a decline in GFR, urine sedimentation, protein urea,
pyuria, heamaturia or crystalluria
• Is often reversible renal insufficiency—if caught early
Incidence
• Seen in acute settings up to 7% of all drug toxicity
• 20% of all cases of hospital acquired ARF with a mortality up to 8%
• 29% of all inpatient ARF attributed to drugs
• 35% of ATN for inpatient
• Most cases of AIN as well
• In outpatient setting NSAIDs contribute to 4 folds ↑ risk of hospitalization due to
ARF during the 1st month of therapy
• Other risks factors include
– Males, > 65 yo, high dose, CVD, recent for nonrenal disease, and concomitant nephrotoxic drug use
• Other agents include ACI, cyclosporine
Recognition and Assessment of Renal toxicity
• In inpatient settings
– Sr Cr., BUN, and I’s and O’s
• In outpatient setting
– Sx of Uremia (malaise, anorexia, and vomiting), or volume overload (SOB, or edema)
• Early it could selectively alter renal tubular function without loss of GFR that can
be recognized by metabolic acidosis with bicarbonaturia, glycosuria (no
hyperglycemia), hypophosphatemia and hypouricemia.
Distal tubular injury
• Indicators include:
– Polyuria, metabolic acidosis, and hyperkalemia
– Low MW proteins like N- acetyl-β-glucosaminidase and β-microglobulin.
- found as result of insult to tissues lining renal tubule
Classification of Drug induced RD
• Psuedorenal Failure (corticosteroids, Trimethoprim, Cimeditine)
• Hemodynamically (NSAIDs, ACEI)
• Renal Vasculitis, Thrombosis, and Cholesterol Emboli
– Vasculitis and Thrombosis (Neomycin C, Methamphetamines)
– Cholesterol emboli (Warfarin, Thrombolytic agents)
• Glomerular Disease
– Nephrotic syndrome (Gold, NSAIDs)
– Glumerulonephritis (Hydralazine, Cytokine Treatment)
• Tubular epithelial Cell Damage
– Osmotic nephrosis (Manitol, IV Ig)
– ATN (Aminoglycosides, Radiocontrasts)
• Nephrolithiasis (Trimeterene, Indinavir)
• Interstitial Nephritis
– Acute Allergic (Methicillin, NSAIDs)
– Chronic (Cyclosporine, Lithium)
– Papillary necrosis (combinations of ASA, phenacetin and Caffeine
anaglesics)
• Obstructive Nephropathy
– Intratubular (Acyclovir, Sulfadiazine)
– Lower urinary tract (TCA)
Mechanism for Renal Susceptibility
• High blood flow and specialized homodynamic
– β-blockers and NSAIDs ↓ BF
- especially propranolol
- nadolol and labetalol: actually improve blood flow
– Radiocontrast may shunt BF
– Osmotic diuresis due to Manitol ↓ GBF
– ACEI dilates efferent arterioles (↓GF press.
– Salt restriction ( activation of neurohumoral renal hemodynamic control system (RAAS)( ↑ susceptibility to these drugs
• Tubular epithelial cell absorptive and secretory functions
– Drugs and their metabolites accumulation
– Impairment of mitochondrial function
– Gentamicin ↑ superoxide ion, H2O2 and its hydroxyl radical
– Cyclosporine ↑ H2O2 – similar to gentamicin
• Drug metabolism to toxic species
– Acetoaminophen local metabolism
• High energy requirement by renal tubular cells
– Amphotericin-B induced modullary tubular cell damage
• Concentration of solute in tubular lumen
– Aminoglycosides toxicity
• Urine acidification
– Methotrexate and ARF – pH < 4.5 associated with methotrexate crystallization
• Nephron adaptation to CR insufficiency
– Radiocontrast
• Age
– ↓ RBF and GFR ≥ 40 yo
Pseudo-renal Failure
• Occurs when either Sr Cr or BUN ↑ while the GFR remains intact
• Corticosteroids and tetracycline ↑ protein catabolism ⇒↑BUN
• Trimethoprim, cimetidine or pyrmethamine competitively inhibit creatinine
secretion ( retain more creatinine
Hemodynamic mediated RF
• ACEI and ARBs
– Causes constriction of both afferent and efferent arterioles ( decreased glomerular filtration pressure
– Risk factors include: RAS, CHF, volume depletion from excessive diuresis, hepatic cirrhosis with ascites, and nephrotic syndrome
– Prevention by small dose, short acting ACEI with monitoring K and Sr Cr.
- with ACEI, there is a temporary jump in SCr from baseline, about 30% ( will return to baseline
- if the increase is >30% ( remove ACEI
Management of ACEI Renal Toxicity
• D/C
• Hyperkalemia could be tx by sodium polystyrene sulfate or IV glucose with
insulin
• If patients needs ACE then ARB might be tried
Inhibition of PG-dependent Total RBF
• NSAID
– Unlikely to impair the renal function in the absence of renal ischemia or vasoconstrictor activity
– Occurs within a few days of starting the NSAID and more common with short acting
– Sr Cr, BUN ↑, urine volume and Na+ usually low, urine sediments show no change or granular casts.
NSAID Renal toxicity
• Risk factors include
– Preexisting renal insufficiency, high renin activity and levels, or SLE. Age???
• Tx
– D/C NSAIDs
– Sulindac/Cox-2
- sulindac is NSAID with least renal toxicity
- COX-2: we now know that COX-2 is harmful to kidneys, as well
– Supportive – e.g., volume
Clinical application of NSAIDs
• Reduction of proteinuria in nephrotic syndrome
Nonspecific Renal Vasoconstriction
• Cyclospsorine
– Early acute hemodynamically mediated renal insufficiency and delayed Chronic Interstitial Nephritis (CIN), generally within 1st 6 months of treatment
– Incidence of 21-25%
– HTN, hyperkalemia, hypomagnesemia and no urine sediment abnormalities
– Renal biopsy shows arterioles’ thickening, glomerular sclerosis, proximal tubule vascularization and interstitial fibrosis
Cyclosporine
• Chronic toxicity apparent after 6 – 12 months, UA shows few RBCs and WBCs
and low range proteinurea
• Risk factors include, age, high initial dose, renal graft rejection, infection,
concomitant nephrotoxic agents as well as cyclosporine metabolism inhibitors
(acyclovir)
• Tx by D/C, CCB?
- nifedipine dilates arterioles: increased RBF
- diltiazem has CYP450 inhibitor effect—may need to decrease dose of cyclosporine
Other agents
• Tacrolimus
• Triameterene – especially if used in combination with NSAID
• Propranolol – decrease RBF by 10 – 20%
• OKT3 – used in organ transplants
– ↑ vascular permeability
- increases TNF, IL-6, IL-2, γ−IFN
• Epoietin
1. ↑ colloid oncotic pressure and blood viscosity because of increased RBC production
2. Decreases seizure threshold
• Methamphetamine
– Systemic polyarteritis nodosa
• OC, cyclosporine, mitomycin C, cisplatin, and quinine
– Thrombus formation
• Warfarin
– Embolizes cholesterol particles
Glomerular disease
• Nephrotic syndrome
– NSAIDs, ampicillin, rifampin, phenytoin, and lithium
• Glomerulosclerosis
– Chronic heroin or cocaine abuse, lithium, α-interferon
• Membranous nephropathy
– Most common with IV gold (rheumatoid arthritis)
• Membranoproliferative glomerulonephritis
– Hydralazine
Tubular Epithelial Damage
• Osmotic nephrosis
– Mannitol, LMW dextran, radiocontrasts, or drug vehicles include sucrose, propylene glycol (solvent in IV lorazepam)
• Acute Tubular Necrosis
– Aminoglycosides incidence is 5-25%
– Clinical presentation include ↑ in Sr. Cr, ↓ in CrCl after 5-10 days, urine < 500 ml/d, Mg and K renal wasting
Aminoglycosides
• Toxicity of aminoglycosides (depends on number of amino groups
– Neomycin > Gent., Tobr., > amik. > netilmicin, streptomycin
- one way to decrease toxicity: once-daily dosing
• Risk factors
–large cumulative dose, synergistic, predisposing factors, prolonged treatment, recent treatment, trough > 2 mg/L
- synergistic with cyclosporine, amphotericin B, duretics, anything with renal toxicity
- Predisposing factors:
hypoalbuminuria adrenal insufficiency
obstructive jaundice shock
dehydration Gm (-) bacteremia
K+ and Mg2+ deficiencies liver disease
Advanced age
- low Mg ( wasting of K+ (“kaluric effect”) ( unless you correct Mg, you can’t fix hypokalemia
Amphotericin B
• Incidence reaches 80% when dose ≅ 4gm
- toxicity has to do with vasculariazation of small arterioles and a toxic effect on
proximal distal tubule ( direct tubular damage, increased tubular permeability
and necrosis, or due to ischemia
• Manifest as Mg, K, Na wasting, and renal tubular acidosis
• Risk factors
– Dose, rate (fast infusion), diuretic with volume depletion, other drugs with nephrotoxicity
• TX
– D/C
- there is now a liposomal preparation with possibly less toxicity than the conventional preparation
Tubulointerstitial disease
• Chronic Interstitial Nephritis
– Lithium, cyclosporine and some other drugs causes progressive irreversible condition
– Mesalazine, 5-aminosalicylic acid and ifosfamide effect can be reversible if D/C
– Lithium associated with nephrogenic diabetes insipidus (polydipsia and polyuria)
– TX include D/C, amiloride or NSAIDs
- Also can be due to Chinese herb Guang Fang Ji (aristocholic) ( glucosuria, subacute renal failure, mild HTN, proteinuria ( leads to intestinal fibrosis and atrophy and destruction of tubule, due to DNA damage
• Acute Allergic Interstitial Nephritis (AIN)
– 3-14% of all ARF
– Involve the renal tubule and their surrounding interstitial tissue
– Drugs include Abx, Neuropsychiatric, NSAIDs, and Miscellaneous
- Abx: most commonly associated with penicillin, especially synthetic (methicillin)
- Signs and symptoms (2 – 4 days): fever, rash, eosinophilia, pyuria, low level proteinuria, generally oliguric
– TX: Prednisone in a dose of 0.5-1.0 mg/kg for 1-4 wks.
• Papillary necrosis (form of interstitial nephritis)
– Classic analgesics account for 36% other agents include Dapsone in high doses
– Believed to be to the accumulation of the toxic metabolites at the tip of the papilla
– TX D/C
– Follow up for transitional cell carcinoma
Obstructive nephropathy
• Due to mechanical obstruction
• Can be caused by
– Acute Uric acid precipitation that can be tx by pretreatment hydration, urine alkalization to PH 7.0, and Allopurinol (prevents uric acid formation)
- allopurinol is also used to pretreat lumor lysis syndrome
– Muscle necrosis nontraumatic rhabdomyolysis
– Precipitation in acidic PH of the urine
- treat with hydration and keep pH of urine >6.5
– Extra-renal obstruction – stone, calculus
Things to Remember:
1. Know the principal nephrotoxic agents
2. Analyze risks/benefits before treating patients
3. Consider alternative treatment first
4. Use lowest effective dose with shortest course of treatment possible
5. Monitor patient on nephrotoxic agents
6. If toxicity is observed ( modify treatment
CHRONIC RENAL FAILURE
Objectives
• Understand the various etiologies and pathophysiology of CRF
• Sx associated with uremia
• Tx delaying progression of CRF
• Management of complications associated with CRF
Definition
• CRF is the progressive loss of nephron function by multiple etiologies resulting in
a rise in BUN and SCr
– Decrease renal reserve
– Renal insufficiency
– Renal failure
– Uremia
- may see small kidneys if you perform KUB
Background
• Progressive and irreversible decline in renal function
• 20,000 patients start dialysis/year
• In 1992, 242 K treated for ESRD and went up to 257,200 in 1995
• 9.5 billion a year
• Associated with significant mortality and morbidity
• Key is Prevent ESRD
- race is also a factor
Stages of CRF (depending on CrCl; according to National Kidney Foundation)
• Stage 1: >90 ml/min
• Stage 2: 60 – 89 ml/min
• Stage 3: 30 – 59 ml/min
• Stage 4: 15 – 29 ml/min
• Stage 5: 55: don’t use Ca2+ binders
• Corrected Ca
– {0.8 X (4-alb)} + serum Ca
• Aluminum – toxic
- aluminum hydroxide ( these salts are really very effective, but watch if patient’s Al level is high ( use Renagel®
• Sucralfate – contains Al+
• Mg++ - hyperMg, diarrhea,
• Renagel
– Complex molecule
– No Mg+, Ca+, Al+ etc…….
– Not absorbed systemically
– Will reduce PTH concentrations
– Unknown DDI
– $$$$$
Osteodystrophy – activated Vitamin D
- first, correct hyperphosphatemia
• Decreases levels of PTH
• Therapy begun when PTH > 3 x normal
• Oral
– Rocaltrol 0.25-05 mcg qd
– May cause more hyperCa+
• IV
– Calcijex (calcitriol), Zemplar(paricalcitol) 1-2mcg qod after dialysis
– Zemplar – less hyperCa+, but $$
• Pulse dosing – less hyperCa+
Aluminum Toxicity
• Minimized b/c of dialysate purification and less need for Al+ phosphate binders
• Neurotoxic, osteodystophy and anemia
• Avoid Al+ phosphate binders, diet, avoid citrates, Al+ containing drugs
- citrates enhance absorption of Al
• Treat with Deferoxamine (DFO)
– Hypotension, ocular toxicity, and acute increase in CSF Al levels
- try to keep Al < 60 mcg/L
Anemia
• Normocytic, normochromic –
– erythropoietin**- levels are normal but should not be (normal level, but not functioning well)
• Presentation – fatigue, dizziness, HA, pallor, angina, ventricular hypertrophy,
impotence, cognitive loss
• Also, blood loss(dialysis); iron, folic acid, B6, B12 deficiency; Al tox.
• Transfusion should be avoided
- Complications:
1. Infection (e.g., HIV)
2. Affects immune system
Anemia – Treatment
- usually when Hb ≤ 7 (Hct = 21), but 20% or give erythropoietin
- Fe saturation = 100 x FE/TIBC
• Benefits
– Reduce transfusions
– Improves QOL
– Decrease pruritis
• Disadvantages
– Increase Heparin requirements
– Hypertension**
– Enhance access clotting
– Flu-like syndrome
- seizures (lowers threshold)
• Darbepoetin alfa
– A long acting form
– Dosed weekly
– Conversion from epoetin based on the weekly dose
- erythropoietin generally given QOD at 50 – 100 units/kg or weekly at 40,000 units
- Indicated for chronic renal failure
- May not work if:
- iron deficient
- active infection is present
- malignancy is present
- contraindication of erythropoietin is uncontrolled HTN or risk of seizures
Uremia
• Increase in Toxins. BUN is guide
• Anoxia, NV, weakness, pruritus, twitching, neuropathy, bleeding, pericarditis
• Bleeding - normal platelets count they just don’t work
• Treatment
– Restrict dietary protein
– Dialysis
Uremia – Bleeding
• Quick fix
– Cryoprecipitate – blood product
– DDAVP – increase Factor VIII—problem with tachyphylaxis
– IV conjugated estrogens (Premarin)
• Long term
– Control BUN
– Estrogens – Ovral 2-4 pills qd
– Erythropoietin
Hyperlipidemia
• Nephrotic syndrome
– Increase total Cholesterol, LDL, TG
– Mechanism by increase Apo B production
– Treatment is basically the same
– Fish oils difficult to use b/c of NV and may enhance bleeding
• Non-nephrotic syndrome RF
– Hypertriglycerides (200-600mg)
– Mechanism by lipolysis
– Diet reduce carbohydrates and weight
– Drug therapy?
Hypertension
[pic]
Other complications
• Hyperuricemia
– Begins when GFR < 40 ml/min
– Uric acid level should be < 12 mg/dl
– No symptoms no tx
- colchicine
• GI
– Anorexia, N, V 1st sx of uremia
– Pancreatitis, D, increase GI bleeding are indicative for dialysis
Vitamin Therapy
• Fat soluble vitamins (ADEK) replacement is not required and could cause complications
• B1, B2, B6, B12, niacin, pantothenic acid, folic acid, biotin, vitamin C
• B6 (pyridoxine), C (ascorbic acid) and folic acid
• Many combinations are available
– Nephrovite
• Individual supplementation
Management of ESRD
• When GFR < 5 ml/min transplantation is needed for survival
• Dialysis indications
RENAL REPLACEMENT THERAPY
- elective in ESRD
- must educate patient first
- must look at clinical picture
- DM: ................
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