ACID BASE DISORDERS, RENAL TUBULAR ACIDOSIS & MIXED
ACID BASE DISORDERS.Dr Mohammed
IMO Ward 14
Chittagong Medical College Hospital
INTRODUCTION• About 20,000 moles of C02 are produced each day by the metabolism of CHO & fat.
•Non volatile acid is produced each day by the metabolism of protein (50-100 mmol /day)
• If 1 HCO¯³ is lost from the body 1 H+ stay behind, the net result is addition of 1 free H+ into the body.
•Conversely if H+ is lost 1 HCO¯³ is added to the body.
Types of Acids
Volatile Acids: carbonic acids
Non Volatile Acids: HCl, H2SO4, H3PO4, Lactic acid & Ketoacids.
Calculations There are various calculations that
are commonly used diagnostically in interpreting acid base disorders and distinguishing between different causes of acid base disorders.
Calculating the anion gap is an approach that must be taken in all cases of metabolic acidosis.
Other calculations such as osmolal gap and urinary anion gap, delta gap, osmolarity & urinary electrolytes.
Ammonia
Acidaemia causes increase ammoniagenesis
Alkalaemia causes descrease ammoniagenesis
Hypokalaemia causes increase ammoniagenesis
Hyperkalaemia causes decrease ammoniagenesis
Facilitate non volatile acid secretion at the level of collecting tubule
Anion Gap
The anion gap is estimated by subtracting the sum of Cl- and HCO3- concentrations from the plasma Na concentration.
Na + Unmeasured cations = Cl- + HCO3- + Unmeasured anions
Anion gap = [Na] – ([Cl-] +
[HCO3-])
The major unmeasured cations are calcium, magnesium, gamma globulins and potassium. The major unmeasured anions are negatively charged plasma
proteins (albumin), sulphate, phosphates, lactate and other organic anions.
The anion gap is defined as the quantity of anions not balanced by
cations. This is usually equal to 12 ± 4 meq/L
and is usually due to the negatively charged plasma proteins as the
charges of the other unmeasured cations and anions tend to balance out.
If the anion of the acid added to plasma is Cl- , the anion gap will be normal (i.e., the decrease in [HCO3-] is matched by an increase in [Cl-]). For example: HCl + NaHCO3 → NaCl + H2CO3 → CO2 + H2O
In this setting, there is a meq. for meq. replacement of extracellular HCO3- by Cl- ; thus, there is no change in the anion gap, since the sum of Cl-] + [HCO3-] remains constant.
This disorder is called a hyperchloremic acidosis, because of the associated increase in the Cl- concentration.
GI or renal loss of HCO3- produces the same effect as adding HCl as the kidney in its effort to preserve the ECV will retain NaCl leading to a net exchange of lost HCO3- for Cl-.
In contrast, if the anion of the acid is not Cl- (e.g. lactate, β-hydroxybutyrate), the anion gap will increase (i.e. the decrease in [HCO3-] is not matched by an increase in the [Cl-] but rather by an increase in the [unmeasured anion]: HA + NaHCO3 → NaA + H2CO3 → CO2 + H2O, where A- is the unmeasured anion.
Causes of elevated Anion gap acidosis is best remembered by the mnemonic KULT or the popular MUDPILES
K = Ketoacidosis (DKA,alcoholic ketoacidosis, starvation)
U = Uremia (Renal Failure) L =Lactic acidosis T = Toxins
(Ethylene glycol, methanol, paraldehyde, salicylate)
Mnemonics(MUDPILES)
M = Methanol U = UremiaD = DKA (also AKA and starvation) P = ParaldehydeI = INHL = Lactic acidosis E = Ethylene GlycolS = Salycilate
In case of hypoalbuminaemia
Because, negatively charged plasma proteins account for the normal anion gap, the normal values should be adjusted downward for patients with hypoalbuminemia.
The approximate correction is add in the normal anion gap of 2.5 meq/l for every 1g/dl decline in the plasma albumin concentration
(normal value = 4 g/dl).
“THE EQUILIBRIUM”
pH = pK + log {[ acid ] / [ base ]}
H+ + HCO3- ═ H2CO3 ═ CO2 + H20
“The Buffer system” :Extracellular- Hb,Proteins, HCO3-
Intracellular- Proteins, H2PO4-
Urine- NH3, H2PO4- , HCO3-
Urine Anion Gap
The three main causes of normal anion gap acidosis are:
Loss of HCO3- from Gastrointestinal tract (diarrhea)
Loss of HCO3- from the Kidneys (RTAs)
Administration of acid
Distinguishing between the above 3 groups of causes is usually clinically obvious, but occasionally it may be useful to have an extra aid to help in deciding between a loss of base via the kidneys or the bowel.
Calculation of the urine anion gap may be helpful diagnostically in these cases
The measured cations and anions in the urine are Na+, K+, and Cl- ; thus the urine anion gap is equal to:
Urine anion gap =
[Na+] + [K+] - [Cl-]
Urine anion gap = unmeasured anions – unmeasured cations
In normal subjects, the urine anion gap is usually near zero or is positive.
In metabolic acidosis, the excretion of the NH4+ (which is excreted with Cl- ) should increase markedly if renal acidification is intact.
Because of the rise in urinary Cl- , the urine anion gap which is also called the urinary net charge, becomes negative, ranging from -20 to more than -50 meq/L.
The negative value occurs because the Cl- concentration now exceeds the sum total of Na+ and K+.
If one molecule of metabolic acid (HA) is added to the ECF and dissociates, the one H+ released will react with one molecule of HCO3- to produce CO2 and H2O.
This is the process of buffering.
The net effect will be an increase in unmeasured anions by the one acid anion A- (ie anion gap increases by one) and a decrease in the bicarbonate by one meq
As a memory aid, remember ‘neGUTive’ - negative UAG in bowel causes.
Remember that in most cases the diagnosis may be clinically obvious
Causes of Renal tubular Acidosis (RTA Type-1, 2 and 4)
The Delta Ratio (∆/∆)
The delta ratio is sometimes used in the assessment of elevated anion gap metabolic acidosis to determine if a mixed acid base disorder is present.
Delta ratio = ∆ Anion gap/∆ [HCO3-]
or ↑anion gap/ ↓ [HCO3-
Now, if all the acid dissociated in the ECF and all the buffering was by bicarbonate, then the increase in the AG should be equal to the decrease in bicarbonate so the ratio between these two changes (which we call the delta ratio)
should be equal to one.
As described previously, more than 50% of excess acid is buffered intracellularly and by bone, not by HCO3- .
In contrast, most of the excess anions remain in the ECF, because anions cannot easily cross the lipid bilayer of the cell membrane
In lactic acidosis, for example, the ∆/∆ ratio averages 1.6:1
On the other hand, although the same principle applies to ketoacidosis, the ratio is usually close to 1:1 in this disorder because the loss of ketoacids anions (ketones) lowers the anion gap and tends to balance the effect of intracellular buffering.
A delta-delta value below 1:1 indicates a greater fall in [HCO3-] than one would expect given the increase in the anion gap.
This can be explained by a mixed metabolic acidosis, i.e a combined elevated anion gap acidosis and a normal anion gap acidosis, as might occur when lactic acidosis is superimposed on severe diarrhea.
In this situation, the additional fall in HCO3- is due to further buffering of an acid that does not contribute to the anion gap.
(i.e addition of HCl to the body as a result of diarrhea)
Delta Ratio <0.4=Hyperchloremic normal anion gap acidosis
Delta Ratio <1= High and normal anion gap acidosis
Delta ratio 1 to 2 = Pure anion gap acidosis
Delta ratio 1.6:1 =lactic acidosis Delta ratio >2= High anion gap acidosis
with concurrent metabolic acidosis.
Osmolar Gap
The Osmolar Gap is another important diagnostic tool that can be used in differentiating the causes of elevated anion gap metabolic acidosis.
The major osmotic particles in plasma are Na+ , Cl- , HCO3-, urea and glucose and as such, plasma osmolarity can be estimated as follows
Plasma osmolarity = 2(Na) + glucose/18 + BUN/2.8
The normal osmolar gap is
10-15 mmol/L H20 .
The osmolar gap is increased in the presence of low molecular weight substances that are not included in the formula for calculating plasma osmolarity.
Common substances that increase the osmolar gap are
Ethanol, ethylene glycol, methanol, acetone, isopropyl ethanol and propylene glycol.
In a patient suspected of poisoning, a high osmolar gap (particularly if ≥ 25)
with an otherwise unexplained high
anion gap metabolic acidosis is suggestive of either methanol or ethylene glycol intoxication
SIMPLE ACID BASE DISORDERS
METABOLIC ACIDOSIS
METABOLIC ALKALOSIS
RESPIRATORY ACIDOSIS
RESPIRATORY ALKALOSIS
MIXED ACID BASE DISTURBANCES
Metabolic acidosis + Respiratory acidosis
Metabolic acidosis + Metabolic alkalosis
Metabolic acidosis + Respiratory alkalosis
Metabolic alkalosis + Respiratory acidosis
Metabolic alkalosis + Respiratory alkalosis
WHO IS THE PRIMARY CULPRIT ?
WHO IS TRYING TO COMPENSATE ?
HOW TO TRACE THE MIXED ACID BASE DISTURBANCES ?
IS THERE AN OTHER DISORDER NOT APPARENT IN THE ABG SLIP ?
TO REMEMBER“ A NORMAL ABG DOES NOT RULE OUT AN
ACID BASE DISTURBANCE “
THE APPROACH- the 5 steps
STEP I - Catch The Primary Disorder
STEP 2- Is the compensation adequate ?
STEP 3- The 4 “Gaps”
STEP 4- Don’t forget the electrolytes !
STEP 5- Approach to each of the disorder
THE NORMAL VALUES
pH= 7.35 -7.45 HCO3- = 22-26 mEq/l pCO2 = 35- 45 mmHg ANION GAP = 9 -16 meq /l Na+ = 135 -145 meq/l K+ = 3.5 – 5.0 meq/l Cl- = 101-112 meq/l Se.osmolality = 275 -293 meq/l
STEP1-Catch The Primary Disorder
pH < 7.35 – ACIDOSIS ↓ HCO3- ↑Pco2
pH > 7.45 – ALKALOSIS ↓ Pco2 ↑ HCO3
STEP 2-Is the compensation adequate?
Various formulae available
To remember-*Respiratory compensation (lungs)occurs fast*Metabolic compensation (kidneys)occurs slow
STEP 3- The 4 “Gaps
Serum Anion gap Urine anion gap The Delta gap Osmolar gap Correction for albumin
Corrected anion gap
For every 1 g/dl fall of albumin, anion gap falls by 2.5 meq/l
Hence, need to add 2.5 to anion gap for every 1 g/dl fall of albumin
Step 4 – The Electrolytes
Tracing the “pattern” Egs-1.Low Na,High K, N. AG Met. acidosis and
hypotension Addison’s Disease2.Hypertension,hypokalemia,metabolic
alkalosis Cushing’s Disease3.Low Na, Low K, Low Cl, Met.Alkalosis in a
hypertensive pt.- Probable diuretic usage4.Low K, High Cl, renal stones, Normal anion
gap Met.AcidosisRenal Tubular Acidosis
METABOLIC ACIDOSIS
↑ ANION GAP ( k.u.s.m.a.l )
NORMAL ANION GAP
+ URINE ANION GAP = R.T.A
- URINE ANION GAP = G.I bicarbonate losses,Drugs,Addison’s
METABOLIC ALKALOSIS
CHLORIDE RESPONSIVE• Urine Cl < 15 meq/l , ECV contracted• G.I losses, diuretics, post hypercapnia,• Post acidotic states, admin. of non reabs.
Anions (drugs )
CHLORIDE NON RESPONSIVE• Urine Cl > 25 meq/l ,hypervolemia, HTN• Low K, Low Mg, Bartter’s syn.
RESPIRATORY ACIDOSIS
CAUSES OF HYPOVENTILATIONRespiratory problems, neurogenic poblems,
neuromuscular,drugs
RESPIRATORY ALKALOSIS
Causes of hyperventilation• CNS stimulation ( pain, anxiety , fever,
trauma, tumor, infection )• Drugs ( progesterone, salicylates )• Hypoxemia ( pneumonia, ARDS )• Chest receptor stimulation ( PE , LVF )• Septicemia , Hepatic failure
Question?
A patient with AG=12,Serum HCO3 24mEq/LIn ABG pH=7.40, [HCO3]=24, PCO2=40,Then patient develop lactic acidosis AG
rises from 12 to 32 HCO3 doesn’t fall it is still in 24 mEq/l
pH remains =40 PCO2= 40What happened?
Step 1: Everythings look normal Step 2: PCO2 & HCO3 normal no
respiratory disorder Step 3:AG is incresed by 20. there is
incresed AG but HCO3 is normal So change in HCO3= AG/1.5=13.3mEq/l HCO3 level should be (24-13.3)=10.7 But HCO3 level is in 24 ,so there must be
something that pushing the HCO3 level to 24
It is a metabolic alkalosis. The severe anion gap acidosis is masked by metabolic alkalosis.
If we don’t calculate the anion gap we can miss this mixed metabolic acidosis.
Question :2
A pts pH=7.65, PCO2=30, HCO3=32, AG=30Temperature is 102 degree & BP=80/50. the urine analysis shows
numerous WBC & urinary deep stick is negative .
Step 1: pH is up & HCO3 is up so Metabolic alkalosis.
Step 2: Compensated PCO2 in this case of metabolic alkalosis PCO2=40+0.7(32-24)=45.6 But PCO2 is 30 so respiratory alkalosis is also
present. Step 3: AG is 30 so high anion gap acidosis
is present this is due to lactic acidosis.
So Ans is Metabolic alkalosis with respiratory alkalosis with severe high anion gap metabolic acidosis