DR. PRAMILA BAJAJ

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DR. PRAMILA BAJAJ

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Title: DR. PRAMILA BAJAJ

1
Perioperative Fluid Management
DR. PRAMILA BAJAJ SR.
PROF. HEAD DEPTT. OF ANAESTHESIA, ADDITIONAL
PRINCIPAL, RNT MEDICAL COLLEGE, UDAIPUR (RAJ.)
www.anaesthesia.co.in anaesthesia.co.in_at_gmail.c
om
2
Perioperative Fluid Management

Fluid electrolyte management paramount in
surgical patient.
Change in Fluid (Fl.) Electrolyte (El.)
Composition
Pre.op
Post op.
In response to trauma and sepsis

3
Distribution of Body Fluids

Helps us understand the subject.
Total body water 50-60 of total body weight.
Relationship constant for an individual
reflection of body fat.

4
Distribution of Body Fluids

Water in muscle solid organs gt Water in fat
bones ? young, lean adults greater of TBW
than elderly / obese.
Av. young adult male 60 water of TBWt
Av. young adult female 50 water of TBWt,
b/c of high adipose / fat.
Estimates of TBW ? Up by 10 in malnourished
Down by 10-20 in obese.
New born infants 80 water of TBW ? Decreased
to 65 by 1 year, then constant.

5
Fluid Compartments

Total Body Water - Extracellular Fluid (20)
Intracellular Fluid (40),
TBW ECF ICF

6
Normal Water Balance

How body maintains its water volume?
Kidneys A major role.
Oral / iv fluids urine output Important
parameters of body fluid balance.

Insensible fluid input 300 ml water due to
oxidation
insensible fluid loss 500 ml through
skin (400 ml through lung 100 ml through
stool)
Fluid loss Fluid input 1000 300 ml 700 ml
Insensible loss ? in Fever, Hypermetabolism,
Hyperventilation
Sweating Active process Loss of electrolytes
water
1. Moderate sweating 500 ml
2. Severe Sweating
High fever
3. Burns
Abd. Surgery

1000 1500 ml
500-3000 ml
8
Normal Water Balance

Kidney must excrete about 500-800 ml urine / day
(irresp. of oral intake)
Daily Sodium intake 3-5 gm/d.
Balanced achieved by kidneys
In hyponatremia Salt excreted lt1 mEq/d
In Salt wasting kidneys gt5000 mEq/d.

9
Composition of Fluid Compartments
ECF compartment Balance between
electrolytes ECF ICF Principal Cation
Na K, Mg2 Principal Anion Cl-
HCO3- Phosphate Prot. ATP driven Na K
Pump ECF ICF Conc. grad.
10
Imp. Points to Remember

Proteins important contributors to Osmolality
Movement of water across compart. is free but
that of proteins and ions restricted.
Even distribution of water in all compartments.
Sodium confined to ECF because of osmotic
eIectrolyte properties
Sodium containing fluids ? distributed in ECF ?
?Vol. of IV and interstitial sp. as much as 3
times of plasma.

11
Definitions

What is Osmotic pressure?- Movement of water
across C.M. depending primarily upon osmosis.
- Determines distribution of water among
different fluid compartment. (ICF ECF)
generated by solution proportional to no. of
particles / unit volume of solvent.
does not depend upon type, valence and weight of
the particles
To generate O.P. ? Solute must be unable to cross
C.M.
Unit ? osmoles (osm) or milliosmoles (mosm).
E.g.. One mmol of Nacl ? 2mosm (one each from
Na Cl-)

12
Define Osmolality, Effective Osmolality
Osmolarity

2. Osmolality
Determined by amt. of solute diss. in a solvent
(water) measured in wt (kg)
Determinants Conc. of sodium, glucose, urea
(BUN)
Calculation
Serum osmolality 2Na Glucose BUN
18 2.8
Osmolality of ECF and ICF b/w 290-310 Osm in each
compartment

3. Effective Osmolality
Determined by solutes which do not freely
permeate cell wall and hold water within ECF
Effective Osmolality 2xNa (mEq/L) Glucose
(mg/dl)/18
Glucose accounts for only 5 mOsm/kg in effective
osmolality. ? plasma Na concentration is the
determinant of the plasma osmolality.
4. Osmolarity Determined by amt. of solute
dissolved in a solvent (water) measured in vol.
(litre).
Concentration of solution of a solute diss. in 1
litre of solvent is expressed as mOsm/L.

Concentration of Electrolytes Expressed in
terms of chemical combining activity or
equivalents.
Univalent ion (Sodium) 1 Meq 1 Mmol
Bivalent ion (Mg) 2 Meq 1 Mmol

Equivalent of an ion Atomic Weight (gm)
Equivalent of an ion Valence
15
Paediatric Surgery
How are infants and children different from
adults?

Fluid Management A critical element in paed.
surgery b/c infants children sensitive to even
small degree of dehydration ?Higher requirement
for water electrolytes / KgBw.
Inability to excrete water load due to immature
kidneys ? Overload.
Complex surgical procedures ?Rapid change in
fluid requirement ?Frequent assessment and
modification of fluid therapy.

16
Paediatric Surgery

In O.T. rapid change in req. during
- Conduct of Anaesth. Surg.
- Change in temperature
- Metabolism vol. shift (due to trauma,
hemorrhage, tissue exposure) ? Intracompartmental
fluid shift
Requires fluid replacement with sol. to
compensate for energy, water, protein
electrolyte losses.
Anaesthetist Alert for - obvious fluid loss
- Hidden fluid loss (insensible loss)
- Third Space loss

17
Physiological Considerations

Proportion of ECF/ICF change with age.
Body cells, surrounding fluid in electrical
equilibrium
TBW Vol. Fluid exchange rate vary
with age.

Before birth, nutrition demands met through
placental transfer. NFT infant - enough fluid
reserve to last till full oral breast feed.

18
Physiological Considerations ..
TBW Fat
28 wk (1kg) 80 1
Term 70-75 17 ECF (30-40 of TBW) ? gradual shift
3 mths (6kg) 70 30 Further ? in ICF ECFltICF
1 Year 60 ECF ? to 27
19
Immature Infants Higher of TBW and ECF Total
blood volume of a newborn infant 8.5 of B.W.
ECF

Intravascular Plasma Vol. Together contribute Interstitial Fluid Vol.

Functional Extracellular Fluid Vol. FEFV
ECF also includes III space / transcellular fluid which is physiologically non-functional ECF also includes III space / transcellular fluid which is physiologically non-functional ECF also includes III space / transcellular fluid which is physiologically non-functional
20
Interstitial Space

fluid filtered
High cir. vol. Vas. Comp. ??? interstitial sp.
(reservoir)
fluid filtered
Low cir. vol. Interstitial sp. ??? Vas. comp.
? buildup
circulatory vol.
Adolescence FEFV 27-30 Inter. space vol.
Plasma vol.
20 7-10
Full term infant FEFV 45

21
What is the importance of transcellular (III Sp.)
fluid?

Non functional extracellular fluid
Unavailable pool of water ? formed by
transudation from cells and EC space
E.g. Fluid within GIT formed during-
Int. Obst.
Ascitis
Urine
Pleural effusion
Fluid in III space loss
from FEFV
Fluid preferred for replacement Ringer lactate

22
Intracellular Fluid

Isotonic Solution ? Cell Vol. constant due to
free movement of water from within cells
Hypotonic Solution ? Inward water movement ?
Increased cell volume
Intracellular fluid bound to protein
Energy required for Potassium (inside cell)
Sodium transport (outside cell).

23
Describe the renal physiology in neonates.

Postnatal shift in body fluid med. by Na and H2O
excretion by immature kidneys.
Sodium and water excretion by immature kidneys ?
Postnatal Mediated by shift in body fluid
Urine Vol. ? 1st day 0-68 ml
7th day 40-300 ml
At birth GFR 25 of adult rate (20 ml min-1
1.73m-2)
Rapid ? in 2 wks slower ? to adult rate by 2 yrs
of age
Infants can handle twice the (N) vol. load b/c
-ve effects of low GFR compensated by ve effects
of low concentrating high diluting capacity
Add conc. capacity of infant well below adult.

24
Renal Physiology in Neonates .

Concentrating capacity (Max. osmolality 500-600
(well below adults) Osm/kg) in response to
water
Adult (1200 mOsm/ kg)
Diluting capacity low in dehydrated infants
If water loaded ? diluting capacity well above
adults (Osmolality 30-50 mOsm/kg)
Fasting newborn (72 hours) ? Minimum elevation of
BUN Na. (Loss of BW 13).
8 decrease in BW Neg. N2 balance even when
fluid given at 50ml/kg/day/ or unlimited amt. of
breast milk.
Milk feed ? Positive N2 balance weight gain
Wilkinson et al. 1962, Lancet 1983

25
Electrolyte Physiology

Sodium Physiology Variable therefore inaccurate
indicator of hydration.
Daily requirement (Term infant) ? 2-5 meq kg-1
day-1
Term infants retain Sodium when in negative Na
balance like adults.
? cap. to excrete Na when in positive balance.
Ac. change in balance ? Gross variation in blood
pressure, Intracerebral hemorrhage.
PPV use of PEEP ? ?ed Natriuresis, ?ed
vasopressin, ?ed water retention

26
Daily Electrolyte Requirements for Paediatric
patients
Patients wt gt10 kg Patients wt lt10 kg
Sodium 20-150 meq 2-5 meq/ kg
Potassium 20-240 meq 2-4 meq/ kg
Acetate 20-120 meq -
Chloride 20-150 meq -
Calcium 5-20 meq 0.5-3 meq/ kg
Phosphorus 4-24 meq 0.5-1.5 meq/ kg
Magnesium 4-24 meq 0.25-1 meq/ kg
27
What are the special features of CVS physiology
in infants?

Immature myocardium S.N.S. ? Propensity to
hypovolaemia greater in neonates / infants.
Myocardial contractility vas. tone
compliance ? less variable ? tachycardia ? Pri.
comp. mech. during ? vol.
Excess ? HR ? C.O. ?
Anaesth. effect ? Further depression of myocard.
? Hypovolemia exaggerated ?maintenance of
effective vas. vol. in paed. patient essential to
sustain circulatory function and vital organ
perfusion in peri-op. period.

28
Hepatic Function

Hepatic function immature
Carbohydrate reserves accumulate in last TM of
pregnancy limited stores in pre-term neonates.
Most pre-term neonate Require 10 dextrose
infusion to prevent hypoglycemia in early
perinatal period.

29
Hepatic Function .

Clinically significant hypoglycemia
Full term neonate lt 30 mgdl-1
Pre term infant
First 3 days ? lt 20 mgdl-1
After 3rd day ? lt 40 mgdl-1
Treatment Ac. hypoglycemia Bolus 0.5-1.0
g/kg-1 iv glucose followed by infusion 5-6 mg
kg-1 as maintenance infusion
Monitor serial blood glucose.

30
Hepatic Function .

Response to surgical trauma ? Catechol.
? glucocort.
? blood glucose.
Hypoglycemia - Unusual during preop. fasting in
children
- Uncommon during surgery.
- Not easily recognized during anaesth.
Dextrose in patient with prolonged fast prevents
ketosis, ? protein catabolism post operatively.
Continue glucose inf. commenced in OT until
patient awake and oral intake established.

31
What are the fluid management protocols in
infants ?

Divided into 3 phases
Deficit therapy
Maintenance therapy
Replacement therapy
Deficit Therapy Management of fluid /
electrolyte loss prior to surgery
Three components
Estimate Severity of dehydration
Determine fluid deficit
Repair the deficit

32
Assessment of dehydration severity in neonates
infants
Signs Symptoms Mild Moderate Severe
Weight loss 3-5 6-9 gt10
General Condition Alert, restless Thirsty, lethargic Cold, sweaty, limp
Pulse N. rate, vol Rapid, weak Rapid, feeble
Respiration Normal Deep, rapid Deep, rapid
Ant. Fontanelle Normal Sunken Very Sunken
Systolic pressure Normal Normal or low Low, unrecordable
Skin turgor Normal Decreases Markedly ?
Eyes Normal Sunken, dry Grossly sunken
Mucus membrane Moist Dry Very dry
Urine output Adequate Less, dark Oliguria, anuria
Capillary refill Normal lt 2 sec gt 3 sec
Estimated deficit 30-50 mg/kg 60-90 ml/kg-1 100 ml/kg
33
Fluid Management ..

History, Clinical and Evaluation Important
Confirmation by
Serum osmolarity and serum sodium
Acid-base status, Serum pH, Base deficit
Serum Potassium compared with pH
Urine Output To rule out ATN
Hyponatremic Dehydration Serum Osmolarity
lt270 m.Osmol-1
Serum Na lt130mEq/L

34
Fluid Management ..

Isonatremic Dehydration Serum Osmolarity
270-300 m.Osmol-1
Serum Na 130-150 mEq/L
Hypernatremic Dehydration Serum Osmolarity
gt310 m. Osmol-1
Serum Na gt150 mEq/L
Initiate treatment for deficit before
investigation available
Initiation with a bolus of NS over 10-12 min to
improve circulation and restore renal perfusion

35
Fluid Management ..

Patient with known contraction alkalosis 50
dextrose with 0.9 NS (Reasonable fluid of
choice)
Patient with known met. acidosis 250 ml of 0.9
NS 28 ml of 7.5 Soda bicarbonate solution
232 ml of 5 dextrose.
This gives approx. Dextrose 1.2
Sodium 149 mEq
Chloride 115 mEq
Sod. Bicarbonate 25 mEq

36
Fluid Management ..

Lactate / Acetate containing solution aggravate
met. acidosis because of failure of formation of
bicarbonate from its precursors due to poor
circulation status.
Febrile response to volume contraction Due to
decrease in skin blood flow ? Decrease heat
dissipation.
Hyperosmolarity ? Increased threshold for
sweating ? Increase calorie and fluid requirement

37
Fluid Management ..

Fluid deficit due to overnight fasting
Advocated to prevent risk of pul. aspiration
during anaesthesia
Children ? residual gastric vol., ? pH Clear
fluids allowed upto 2 hours before surgery.
Sphinter W.M. 1990 Anaesth Intensive Care
18522-526
Sips of fluid ? peristalsis but no gastric
secretion if protein absent.
H2 blockers ? gastric pH, ? gastric vol.
Sertherland AD et al. 87, Can J. Anaesth 34.
117-121.

38
Fluid Management ..

Current recommendations
Clear fluids 2 hours
Milk 4 hours
General Rule
Preop. Fluid deficit Maint./hr. x Hrs of fluid
restriction

Before Surgery
50 in 1 hour 25 each in next 2 hours
39
Maintenance fluid requirements in neonates
infants Daily and hourly
Age (d) / Wt (Kgs) Requirements ml/kg-1 day-1 Hourly mlkg-1hr-1 Type of fluid
1 20-40 2-3 10 dextrose
2 40-60 3-4 10 dextrose in 0.22 saline
3 60-80 4-6 10 dextrose in 0.22 saline
4 80-100 6-8 5-10 dextrose in 0.22 saline
0-10 kgs 100 4 mlkg-1hr-1 5 dextrose in 0.45 saline
10-20 kgs 100050 mlkg-1 40 ml2 mlkg-1hr-1 5 dextrose in 0.45 saline
gt 20 kgs 150020 mlkg-1 60 ml1 mlkg-1hr-1 5 dextrose in 0.45 saline
40
Composition of commonly used intravenous fluids
Electrolytes (meqL-1) NS Ringers lactate Isolyte P Plasmalyte A D5 Albumin 5 Hetastrach 6
Na 154 130 26 140 - 14515 154
K - 4 21 5 - lt2.5 -
Cl 154 109 21 98 - 100 154
Mg - - 3 - - - -
Acetate - - 24 27 - - -
Lactate - 28 - - - - -
Glucose (gm) - - 5 - 5 - -
Phosphate (mg) - - 3 - - - -
Osmolarity (mOsmL-1) 308 274 - 295 252 330 310
41
Maintenance Fluid Therapy

Meets ongoing fluid electrolyte demands during
surg.
Does not include blood loss / third space loss
into gut or interstitial space.
Maintenance Fluid covers
- Insensible loss evaporative loss
- Urinary loss
Insensible loss ? Solute free loss of water
through skin lungs, usually 30-35 of total
maint. req.

42
Maintenance Fluid Therapy

Determinants of Insensible loss
Ambient Temp. Humidity
Gest. Age Resp. pattern
Exposed surface area
Ventilation with humidified gases ? ? insensible
loss.
In premature infants and patients with D.
insipidus ? Obligatory production of dil. urine ?
Appropriate ? in maintenance fluid required.
In excess ADH secretion ? Patients unable to ?
urine osmolality to 300 mOsm ?need to ? vol. of
maint. fluid

Gastroschisis
43
Intravenous fluid requirements in Infants Day 1
of life 2 ml/kg per hour Day 2 of life 3 ml/kg
per hour Day 3 of life 4 ml/kg per
hour Intravenous fluid requirements in
children lt10 Kg 10 ml/kg per day 10-20 Kg 1000 ml
(50 ml/kg per day for each kg over 10 kg) gt20
Kg 1500 ml (20 ml/kg per day for each kg over
20 kg) Wt. 10 12 14 16 18 20 30 mL/h 40 45 50 55 6
0 65 70
Surgical trauma Type of Surgery Fluid replacement
Minimal Inguinal hernia repair 1-2 mlkg-1hr-1
Moderate Ureteral implantation 4 mlkg-1hr-1
Severe Scoliosis, bowel obstruction gt 6 mlkg-1hr-1
44
Replacement of blood loss

In children, all blood loss should be replaced.
Done with packed RBCs/whole blood/Crystalloid/
Colloids
Davenports law
lt10 blood loss No blood req.
10-20 ? Consider case by case
gt20 Consider packed RBCs/Whole blood
Replacement Crystalloid 3 ml for each ml of
blood loss
Ensure adequate oxygenation
Minimum hematocrit 30 older children
40 neonates acceptable

Sacrococcygeal Teratoma
45
Intraoperative Fluid Management

Responsibility of an anesthesiologist
Sufficient fluid required to compensate for NBM
hrs insensible loss during op.
Loss considerable during major abdominal /
thoracic surgery
In most cases 10 ml/kg/hr of Ringer lactate in D5
in water
Blood loss Weighing sponges
Suction bottle accumulation
Actual loss more because of blood in drapes and
op. field

46
Intraoperative Fluid Management ..

In a child with normal Hb pre-op. Whole blood /
packed RBCs infusion if blood loss 10 of B.V.
FFP/Albumin in extreme dissection without blood
loss.
Emergency Trauma / G.I. Bleed ? Continue
Pre-op. resuscitation with rapid transfusion
during op.
Prolonged hours of op.
? Monitoring Urine Output
? Serum Electrolyte blood glucose
? Hematocrit and blood gases.

Post Op-Period
- Optimum replacement and maintenance pre. and
intraop. ? child in fluid and electrolyte balance
postop.
Immediate Post-Op.
Drainage from chest tube/ intraperitoneal drains
measured replaced with blood plasma
GIT drainage collected ? Sample for electrolytes
? Measured vol. replaced at intervals of 4-12
hours.
Satisfactory oral intake 3-5 days in most cases.

48
Review of Finer Points

Why fluid therapy needs special consideration in
children?
1) Greater insensible loss
2) Greater urinary loss
3) Larger turn over
4) Inadequate expression of thirst
5) Easy fluid overload
6) Small total volume required
7) Diffusion volume and distribution of body
water

49
Disturbance in Fluid Balance in adults

Extracellular vol. deficit Common fluid
disorder in surgical patients.
Acute deficit associated with CVS CNS signs.
Chronic deficit ? in skin turgor and sunken
eyes CVS CNS signs.

50
Signs and Symptoms of Volume Disturbances
System Volume Deficit Volume Excess
Generalized Weight loss Decreased skin turgor Weight gain Peripheral edema
Cardiac Tachycardia Orthostasis/ hypotension Increased cardiac output Increased central venous pressure
Collapsed neck veins Distended neck veins Murmur
Renal Oliguria, Azotemia
Gastrointestinal Ileus Bowel edema
Pulmonary Pulmonary edema
51

Laboratory Exam
Severe deficit ? ? BUN
? Hemoconcentration
? ? G.F.R.
? Urine osmolality gt Serum
osmolality
? Urine Na lt 20 mEq/L.
Na concentration does not reflect vol. deficit.

52
What are the common causes of vol. def. in
surgical patients?

Loss of GIT fluid NG suction Peritonitis
Vomiting Obstruction
Diarrhoea
Fistula
Sequestration sec. to soft tissue injury
Burn
Prolonged surgery Intra-abdominal procedure

Intestinal Obstruction
53
Volume Control

Volume changes sensed by

Baroreceptor Osmoreceptors

Modulate Vol. Sensors located in Aortic arch and carotid sinsuses Detect changes in fluid osmolality through osmoreceptors changes in thirst diuresis through kidney
54
Electrolyte Abnormalities

Sodium
Normal values 135 145 mEq / L
Concentration Changes Changes in Serum Na
inversely proportional to TBW

Hyponatremia ? (Excess of ECW)
Volume Status (ECV) ?
High ? Normal ? Low ?
? Intake Hyperglycemia ? Sodium intake
Postop ADH secretion ? Plasma lipids/ proteins Gastrointestinal losses
Drugs SIADH Renal losses
Water intoxication Diuretics
Diuretics Primary renal disease
55

Low Serum Sodium level - Na depletion
- Dilution Intentional
Iatrogenic
To differentiate the Etiology Systemic review
of the causes
Exclude hyperosmolar causes (Hyperglycemia /
Mannitol)
Consider depletional / dilutional causes
Extrarenal (GIT) loss Urine Na (lt20 mEq/L)
Renal loss Urine Na (gt20 mEq/L)

56
How will you treat Hyponatremia?

Most cases treated by free water restriction
If severe Restrict Na
Symptomatic Hyponatremia (lt 120 mEq/L)
If neurological s/s present Give 3 NS
? Na level no more than 1 mEq/L/hour until Se.
level 130 mEq/L or s/s improve.
Asym. Hyponatremia ? Na level by no more than
0.5 mEq/L to a max. of 12 mEq/L/day. slower in
chr. states
Rapid correction may cause PONTINE MYELINOLYSIS
with seizures, weakness / paresis, akiness and
unresponsiveness ? permanent brain damage death.

57
Hypernatremia (Loss of free water / gain of sodium) ? Hypernatremia (Loss of free water / gain of sodium) ? Hypernatremia (Loss of free water / gain of sodium) ?
Volume status ?
High ? Normal ? Low ?
Iatrogenic Na adm. Nonrenal water loss Nonrenal water loss
Mineralocorticoid excess Aldosteronism Cushings disease Congenital adrenal hyperplasia Skin Skin
Mineralocorticoid excess Aldosteronism Cushings disease Congenital adrenal hyperplasia Gastrointestinal Gastrointestinal
Mineralocorticoid excess Aldosteronism Cushings disease Congenital adrenal hyperplasia Renal water loss Renal water loss
Mineralocorticoid excess Aldosteronism Cushings disease Congenital adrenal hyperplasia Renal disease Renal disease
Mineralocorticoid excess Aldosteronism Cushings disease Congenital adrenal hyperplasia Diuretics Osmotic diuretics
Mineralocorticoid excess Aldosteronism Cushings disease Congenital adrenal hyperplasia Diabetes insipidus Diabetes insipidus
Mineralocorticoid excess Aldosteronism Cushings disease Congenital adrenal hyperplasia Adrenal failure
58

Hypernatremia - Loss of free water
gt145 mEq/L Gain of Na in excess of water
How will you treat Hypernatremia?
Hypernatremia Treat associated water deficit
Hypovolemia Treat with normal saline, followed
by Hypotonic fluid (D5 or D5 in ¼ NS) after
restoration of adequate volume status.

Water deficit (L) Serum Na 140 X TBW
Water deficit (L) 140 X TBW
? in Se. Na no more than 1 mEq/h and 12
mEq/d. Chr. hypernatremia Sodium correction
(0.7 mEq/L/H) Overly rapid correction Cerebral
edema herniation Freq. neurological and Se. Na
assessment required.
59
Potassium Abnormalities

Av. Dietary intake 50-100 mEq/d
Flux of K influenced by Surgical stress
Injury
Acidosis
Tissue Collection
Extracellular K maintained by renal excretion
(10-700 mEq/d)
2 of total K extracellular Critical to
cardiac and neuromuscular function.

60
Hyperkalemia

Serum K level above 5.0 mEq/L. (N) range 3.5
5.0 mEq/L.

Hyperkalemia Increased intake Potassium
supplementation Blood transfusions Endogenous
load/destruction hemolysis, rhabomyolysis,
crush injury, gastrointestinal hemorrhage Increase
d release of K from cells. Acidosis Rapid rise
of extracellular osmolality (hyperglycemia or
mannitol) Impaired excretion by
kidney Potassium-sparing diuretics, ACE
inhibitors, NSAIDS Renal insufficiency / failure
61
What are the signs symptoms of hyperkalemia?

GIT ? Nausea, Vomiting, Diarrhea
Neuro-muscular ? Weakness
Ascending paralysis
Resp. failure
CVS Cardiac arrhythmia
ECG Peaked T wave (Early)
Flattened P wave
Prolonged PR interval
Widened QRS
Sine wave formation
VF

62
How will you treat hyperkalemia?

Potassium removal
Kayexalate (cation exchange resin)
Oral administration is 15-30 g in 50-100 mL of
20 sorbitol
Rectal administration is 50 g in 200 mL 20
sorbitol
Shift potassium
Glucose 1 ampule of D50 and regular insulin 5-10
units I.V.
Bicarbonate 1 ampule I.V.
Nebulized Albuterol (10-20 mg)

63
How would you treat hyperkalemia? .......

Goal To decrease body K and shift K from
extracellular to intracellular.
Discontinue exogenous K intake (IV, enteral and
parenteral solution)
Circulatory overload / Hypernatremia may result
from Kayexalate and bicarbonate.
Ca. Gluconate (5-10 ml of 10) / Ca Chloride ? to
counteract myocardial eff. of Hyperkalemia.
May cause digitalis toxicity in patients on
digitalis.
Dialysis ? When conservative measures fail.

64
Hypokalemia

Common in surgical patients
K ? by 0.3 mEq/L for every 0.1 ? in pH above
normal.
Mg depletion due to drugs like amphotercin,
Aminoglycosides, Toscarnet, Cisplatin ? Renal K
wastage.

65
Hypokalemia

Inadequate intake
Dietary, potassium-free intravenous fluids,
potassium-deficient total parenteral nutrition
Excessive potassium excretion
Hyperaldosteronism
Medications ? Penicillins, diuretics
Gastrointestinal losses
Direct loss of potassium from gastrointestinal
fluid (diarrhea)
Renal loss of potassium (gastric fluid, either as
vomiting or high nasogastric output)

What are signs symptoms of hypokalemia?
GIT - ileus, Constipation.
Neuromuscular Weakness, fatigue, ? tendon
reflexes paralysis
Cardiovascular Cardiac arrest
Pulseless electric activity
asystole
ECG Changes U Waves
T wave frequency
ST seg. changes
Arrhythmia (Patient on digitalis)

67
How will you treat hypokalemia?

Serum potassium level lt4.0 mEq/L
Asymptomatic, tolerating enteral nutrition KCl
40 mEq per enteral access x 1 dose
Asymptomatic, not tolerating enteral nutrition
KCl 20 mEq IV q2h x 2 doses
Symptomatic KCl 20 mEq IV q1h x 4 doses
Recheck K level 2 hrs after end of infusion if
lt3.5 mEq/L asymptomatic replace as per above
protocol

Potassium repletion Determined by symptoms
Oral Supplementation Mild / asymptomatic.
IV Not more than 10-20 mEq/h in unmonitored
setting.
40 mEq/hr if ECG monitoring available.
If sec. to Mg depletion Correct Mg def. first
Exercise caution in patient without oliguria /
impaired renal function.

69
Magnesium

4th most common mineral in body
Primarily intracellular
1/3 of extracellular Mg bound to serum albumin
Plasma levels poor indicator in presence of
Hypoalbuminemia
Normal dietary intake - 20 mEq (240 mg) / day
Excretion Feces Urine.

Hypermagnesemia Rare
Impaired renal function
Excess intake
Mg containing laxative / Antacids
What are the signs symptoms of Hypermagnesemia?
GIT Nausea Vomiting
Neuromuscular Weakness, lethargy, decreased
reflexes.
CVS Hypotension arrest.
ECG Increased PR interval
Widened QRS
Elevated T waves.

71
Treatment

How will you treat Hypermagnesemia?
Withhold exogenous sources of Mg
Correct volume deficit
Correct acidosis
Acute symptoms Inj. Ca chloride 5-10 ml
Dialysis in severe cases.

72
Hypomagnesaemia
Causes

Diminished absorption or intake
Malabsorption, chronic diarrhea, laxative abuse
Prolonged gastrointestinal suction
Small bowel bypass
Malnutrition
Alcoholism
Increased renal loss
Diuretic therapy (loop diuretics, thiazide
diuretics)
Hyperraldosteronism, Bartters syndrome
Hyperparathyroidism, hyperthyroidism
Hypercalcemia
Drugs (aminoglycoside, cisplatin, amphotericin B
Pentamidine)
Others
Diabetes mellitus
Post parathyroidectomy (hungry bone syndrome)
Respiratory alkalosis
Pregnancy

73
Treatment Hypomagnesemia

How will you treat Hypomagnesemia?
Asymptomatic / Mild Oral supplementation
Intravenous correction depends upon severity
Magnesium level 1.0-1.8 mEq/L
Magnesium sulfate 0.5 mEq/kg in normal saline 250
mL infused IV over 24 h x 3 days
Recheck magnesium level in 3 days

Magnesium level lt 1.0 mEq/L
Magnesium sulfate 1 mEq/kg in normal saline 250
mL infused IV over 24 h x 1 day, then 0.5 mEq/kg
in normal saline 250 mL infused IV over 24 h x 2
days
Recheck magnesium level in 3 days
If patient has gastric access and needs a bowel
regimen
Milk of magnesia 15 mL (approximately 49 mEq
magnesium) q24h per gastric tube hold for
diarrhea

75
Calcium

Vast majority in bony matrix
Extracellular fluid lt1
Se. Ca2 3 forms ? Protein bound 40
Complexed to anions (PO4) 10
Ionized 50
Ionized fraction responsible for neuromuscular
stability
Albumin measurement necessary when measuring
total Ca2
Adjust total Serum Ca2 down by 0.8 mg/dL
for every 1-g/dl ? in albumin.
Acidosis ? Protein binding ? ionized fraction

76
Hypercalcemia

Defined as Serum Ca gt 8.5 10.5 mEq.
or
? in ionized as Ca level gt 4.2 - 4.8 mg/dl

77
Causes of hypercalcemia

Increased intake or absorption
Milk-alkali syndrome
Vitamin D or vitamin A excess
Endrocrine disorders
Primary hyperparathyroidism (adenoma,
hyperplasia, carcinoma)
Secondary hyperparathyroidism (renal
insufficiency, malabsorption)
Acromegaly
Adrenal insufficiency
Neoplastic diseases
Miscellaneous causes
Thiazide diuretic-induced
Pagets disease of bone
Hypophosphatasia
Immobilization
Familial hypocalciuric hypercalcemia
Complications of renal transplantation
Iatrogenic

What are the signs and symptoms of hypercalcemia?
GIT Anorexia, Nausea/vomiting, abd. pain
Neuromuscular Weakness, Confusion, Coma,
Bonepain
Renal Polydipsia
CVS Hypertension, arrhythmia, Polyuria
ECG Short QT interval
Prolonged PR QRS interval
? QRS Voltage
T Wave flattening widening
AV Block ? CHB ? Cardiac arrest

How will you treat Hypercalcemia?
Symptomatic hypercalcemia (gt12g/dl) requires t/t
Treatment of hypercalcemia without malignancy
Start with saline volume expansion ? This ? renal
resorption of Ca.
Add loop diuretic after achieving adequate volume
status. But these are temporary measures.

Drugs
Biphosphonates
Calcitonin
Corticosteroids
Gallium Nitrate, Mithramycin
Refractory Hypercalcemia Dialysis

81
Hypocalcemia
Serum Ca2 lt8.5 10.5 mEq/L, ? in ionized Ca2 lt
4.2-4.8 mg/dL

Decreased intake or absorption
Malabsorption
Small bowel bypass, short bowel
Vitamin D deficit
Increased loss
Alcoholism
Chronic renal insufficiency
Diuretic therapy
Endocrine disease
Hypoparathyroidism (genetic, acquired including
hypo- and hypermagnesemia)
Sepsis
Pseudohypoparathyroidsim
Calcitonin secretion with medullary carcinoma of
the thyroid
Familial hypocalcemia

What are the signs and symptoms of hypocalcemia?
Neuromuscular Hyperactive reflexes, Parasthesia
Carpopedal spasm, seizures
Chvostek sign
Trosseau sign
CVS Heart failure, ? cardiac contractility
ECG Prolonged QT interval
T wave inversion
Heart block
V.F.

83
Hypocalcemia

How will you treat hypocalcemia?
Normalized calcium lt4.0 mg/dL
With gastric access and tolerating enteral
nutrition Calcium carbonate suspension 1250
mg/5 mL q6h per gastric access recheck ionized
calcium level in 3 days
Without gastric access or not tolerating enteral
nutrition Calcium gluconate 2 g IV over 1 h x 1
dose recheck ionized calcium level in 3 days.
Acute Hypocalcemia Inj. Cal. gluconate 10 iv
Correct asso. deficit in Mg, K, pH
Hypocalcemia refractory if Hypermagnesemia is not
treated first

84
Phosphorus

Primary intra-cellular divalent anion
Abundant in metabolically active cells
Responsible for maintaining energy production
(ATP)
Levels controlled by renal excretion

85
Hyperphosphatemia
Causes

Massive load of phosphate into the extracellular
fluid
From outside the body
Hypervitaminosis D
Laxatives or enemas containing phosphate
Intravenous phosphate (especially if renal
insufficiency coexists)
Cell destruction by chemotherapy of malig,
particularly lymphoproliferative disease
Metabolic acidosis (lactic acidosis,
ketoacidosis)
Respiratory acidosis (phosphate incorporation
into cells is disturbed)
Decreased excretion into urine
Renal failure (acute, chronic)
Hypoparathyroidism
Pseudohypoparathyroidism
Excessive growth hormone (acromegaly)
Pseudoperphosphatemia
Multiple myeloma, hypertriglyceridemia, cell lysis

What are the signs and symptoms of
Hyperphosphatemia?
Mostly asymptomatic
In advanced cases?metastatic soft tissue deposits
How will you treat Hyperphosphatemia?
Phosphate binders Sucralfate
Aluminum containing antacid
Dialysis for patient with renal failure

87
Hypophosphatemia
Causes

Diminished supply or absorption
Starvation
Parenteral alimentation with inadequate phosphate
content
Malabsorption syndrome, small bowel bypass
Vitamin D-deficient and vitamin D-resistant
osteomalacia
Increased loss
Phosphaturic drugs theophylline, diuretics,
bronchodilators, corticosteroids
Hyperparathyroidsim (primary or secondary)
Hyperthyroidism
Renal tubular defects
Inadequately controlled diabetes mellitus
Intracellular shift of phosphorus
Respiratory alkalosis, Salicylate poisoning
Electrolyte abnormalities
Hypercalcemia, Hypomagnesemia
Metabolic alkalosis

What are the signs and symptoms of
Hypophophatemia?
Usually not significant unless severe deficiency
Related to ? O2 del. to tissue and ? in ATP
Manifest as cardiac dysfunction / Muscle weakness

89
How will you treat Hypophosphatemia?

Phosphate level 1.0 2.5 mg/dL
KPHO4 or NaPO4 0.15 mmol/kg IV over 6 h x 1 dose
Recheck phosphate level in 3 days
Phosphate level lt 1.0 mg/dL
Tolerating enternal nutrition KPHO4 or NaPO4
0.25 mmol/kg over x 1 dose
Recheck phosphate level 4 hours after end of
infusion
KPHO4 or NaPO4 0.25 mmol/kg (LBW) over 6 h x 1
dose recheck phosphate level 4 hours after end
of infusion if lt2.5 mg/dL, then KPHO4 or NaPO4
0.15 mmol/kg (LBW) IV over 6 h x 1 dose

90
How to calculate the rate of fluid infusion?

For routine IV set
15 drops 1 ml
Rule of TEN for fluid Cal. for 24 hours
IV fluid in litre / 24 hours x 10 Drop rate /
min
Rule of Four for fluid Cal for one hour
Drop rate / min. x 4 Vol. in ml/ hour
For micro-drip IV set
1 ml 60 ?drops
No. of ?drops / min Vol. in ml / hr.

91
Preoperative Fluid Therapy

A frequently used formula for maintenance fluid
for first 10 Kg 100 ml / kg / d
for next 10-20 Kg Additional 50 ml/kg/d
for wt. gt 20 kg 20 ml / kg / day
But many surgical patients have vol. /
electrolyte disturbance associated with their
disease.
Therefore, pre-op. volume status and electrolyte
assess a must.
Vol. deficits in patients with ? Emesis /
Diarrhea
Poor intake
III space loss
GI dysfunction
Peritoneal / bowel inflammation
Ascitis, crush injuries

Tachycardia Orthostasis predominate with acute
vol. loss accompanied with oliguria
hemoconcentration
Ac. volume deficits should be corrected prior to
surgery.
Start fluid replacement with isotonic crystalloid
depending upon electrolyte profile.

Patient with CV signs of volume deficit ?
1-2 L of isotonic fluid followed by continuous
infusion
Resuscitation guide - Reversal of signs of
volume deficit (Vital signs)
- Adequate urine output (½ 1 ml / kg / hour in
adult)
- Correction of base deficit
Close monitoring essential in all esp. so in
patients with impaired renal function
Electrolyte abnormality correct to the extent
that ac. S/S relieved prior to surgery.

94
Intraoperative Fluid Therapy

Compensatory mechanism lost with induction of
anaesthesia.
Hypotension will manifest if volume deficit
present.
Measure blood loss, III space loss, loss from
exposed bowel, large soft tissue wounds, complex
fractures and burns and replace accordingly.

In general which fluid is appropriate
intraoperatively?
Selection of fluid needs to be individualized
depending upon age, vitals, basic etio. and type
of surgery and asso. Illness.
RL To replace I.O. fluid loss
Most physiological fluid, also corrects
acidosis
NS Used intraop when RL contraind. or when large
vol. of resuscitation required like hypovol.
shock
D5 Initial fluid replacement
- Replacement for insensible fluid loss
- Maintenance fluid deficit during starvation
- Corrects intracellular dehy. provides
calories

96
Postoperative Fluid Therapy

Should be based on patients current estimated
volume status and projected ongoing losses.
Any pre. / intraop. deficit should be corrected
and ongoing req. included in maintenance.
III sp. losses should be included.
In early post op. period Isotonic solution
Guide Vital Signs and Urine output
If uncertainty CVP / Swan-Ganz Catheter

After 24-28 hours Change to 0.45 Saline
without added dextrose in patient unable to
tolerate enteral nutrition.
Add potassium if renal function and urine output
adequate.
Daily fluid requirement based on volume
electrolyte status.
No need for electrolyte measurement in
uncomplicated cases

98
What are special considerations in postoperative
fluid therapy?

Overestimation of losses may lead to volume
excess
Earliest sign Weight gain
Av. Post op. patient not requiring nut. support
loses ¼ to ½ pound /day.

What problems can occur if following iv fluids
are used as sole agents for maintenance?
1) D5 Provides only water glucose. No
electrolytes.
Risk of Hyponatremia / Hypokalemia
2) DNS Contains Na 154 mEq/L,
No Potassium, (N) child requires 30-50
mEq
Risk of hypernatremia, hypokalemia
3) RL Na 130 mEq, Pot. 4 mEq, No glucose
Risk of Hypernatrania, Hypokalemia,
Hypoglycaemia

100

Can we use D5 in initial phase of shock?
No, because
1 litre D5 ? ? in intravascular
volume by 83 ml
Contains no electrolytes ? electrolytes
disturbance
Rapid infusion ? Osm. diuresis ?Detrimental

Omphalocele
101
Management in Neuro-surgical patients

Special challenge to anesthesiologists
Often receive diuretics (Mannitol/ Frusemide) to
treat cerebral edema
? large amounts of IV fluids to correct pre-op
dehydration and to maintain intra/post op.
hemodynamic stability
Fluid restriction if excessive ? Hypotension ? ?
ICP ? ? CPP ? devastating

102

Little human data on the impact of fluid on brain
IV fluid therapy manipulates ?
1. Osmolality
2. Colloid oncotic pressure
3. Hematocrit ? 30-33 ?optimal viscosity O2
carrying capacity ? may improve neurological
outcome.
Hct lt30 ? ? neurological injury

103
How will you control ICP and brain swelling?

Diuretics Mannitol Frusemide used extensively
Mannitol Creates an osmotic gradient between
intravas. comp and brain parenchyma
Frusemide Reduces cell swelling
Also ? CSF production
Hypertonic salt solutions primarily used for
small vol. resuscitation in patient with hemo.
Shock
Data suggest that they ? ICP and improve CPP
similar to Mannitol.
Disadvantages Danger of Hypernatremia
Rebound ? ICP

104

3. Hypertonic / Hyperoncotic solution
(E.g. Hypertonic Hetastarch or Dextrose solution)
Have powerful hemodynamic properties
Advantageous in patients with head injury and
multiple trauma for prevention of secondary
ischemic brain damage
Small volume can restore normovolemia rapidly
Successfully used to treat ? ICT in patients with
head injury and stroke

105
Implications for Patient Care

Fluid Restriction Moderate fluid restriction
causes ? in serum osmolality and prevents
hypo-osmotically driven edema ? beneficial
Intra Op. Replacement
Rate should be sufficient to replace urinary
output and insensible losses
Repeat osmolality check required
Small volume of RL safe
If large vol. required use a more isotonic
fluid or a combination of isotonic crystalloid
and colloid

106

Post op. Period - Large volume not required
Periodic osmolality check and give fluids
accordingly
What are the points to be remembered for a head
injury patient?
Prompt restoration of systemic pressure is
essential
Avoid Hypotonic solution (RL),
Avoid glucose containing solution
Give fluids with osmolality around 300 mOsm/L
Colloids for large volume deficit

107
Subarachanoid Hemorrhage (SAH)

Avoid Hypovolemia and Hyponatremia
Isotonic crystalloids usually take care of
hyponatremia
If severe hyponatremia use mild hypertonic
fluids (1.25 or 1.5 saline)
Avoid fluid restriction
Hypertensive / Hypervolemic therapy widely
accepted to prevent cerebral vasospasm

108
Management of patients with renal diseases

What are the General Rules?
Fluid restriction required in edematous and
oliguric patients to avoid volume overload,
pulmonary congestion, hypertension / hyponatremia
Anuric patient Fluid restricted upto 500 ml/day
only
Oliguric patient Fluid intake Urine Output
500 ml
Monitor urine output chart and daily weight.
Loss of weight ? ? in accumulated fluid ? ? edema

109

Do not chase urine output in edematous patient
Urine output ? in response to diuretic therapy
Aim is removal of accumulated fluid, therefore
continue fluid restriction.
3. Salt restriction req. to ? edema, pulmonary
congestion and hypertension.
4. Avoid Hyperkalemia Can be fatal
Avoid K rich food
Avoid K rich IV fluids

110

Acute renal failure ? Characterized by rapid
decline in renal function.
Accumulation of water, crystalloid solutes and
nitrogenous end products.
Has varied presentation
Pre-renal azotemia
Non-oliguric ac. renal failure
Oliguric renal failure
Diuretic phase of ac. renal failure

111

Pre-renal Azotemia
Pt. improve with early adequate fluid therapy
0.5 1 Lt. isotonic saline infused over 30-60
min. if no response ? IV diuretics to promote
urine flow
Monitor Pulse, BP and JVP
Give isotonic saline in hypotensive states.
With-hold K till urine output is established.

112

Non-oliguric ARF
Due to Septicemia, drug toxicity, A.I.N.
Diagnosis difficult as there is no ? urine
output.
High index of suspicion req.
Do not need fluid or salt restriction
Restrict Potassium intake.
Oliguric ARF If urine output lt40 ml/d in adults
or lt0.5 ml/kg/hr in children
? excretion of water, electrolytes, nitrogenous
waste products
Restrict Salt and water (esp. K)
Maintain daily wt loss chart. (Daily loss of 0.2
to 0.3 kg ideal)
- Treat with diuretics to establish urine
outflow.
- If ineffective - Mannitol/ low dose dopamine
(lt3 µg/kg/min)

113

Diuretic phase of ARF
Renal functions recover through repair of renal
tissue.
- Do not chase urine output at this stage
- Avoid volume depletion and dehydration
- Replace deficit of NaCl, HCO3, K, Mg etc.
- Preferred IV fluid 0.45 saline with K as
required

114
Chronic Renal Failure

CRF due to chr. glom. disease
S/S of volume overload and hypertension
? restrict fluid and salt intake
Diuretics
Avoid Hyperkalemia
Preferred IV fluid D-5 or D-10
CRF due to chronic tubulo-interstitial disease
- Absence of edema / Volume dep. due to polyuria
Advise plenty of fluid and salt intake to prevent
dehydration
Correct Met. acidosis ? Give Sodium Bicarbonate
Avoid treat hyperkalemia

115
How will you manage TURP syndrome?

S/S secondary to neuro., CVS and electrolyte
imbalance due to absorption of irrigation fluid
through prostatic veins.
Risk factors - Surgery gt 60 min
- Prostate (Resected wt gt30 gms)
- Irrigant volume gt 30 L
- Inexperience

116

Prevention Early diag. and prompt treatment
Correct pre-existing Hyponatremia (risk factor)
Irrigation fluid flow lt 300 ml / min
Avoid 5 Dextrose pre-op.
? pre-op. maintenance fluid.
Prophylactic use of Frusemide
Treatment
Terminate surgery
Diuretics 66 cases corrected
Fluid restriction
Mannitol 15
Hypertonic saline Slow I.V. 3 hypertonic
saline.
In general 200 ml sufficient

117
Patient with Trauma

Tissue injury ? activated sys. infl. response ?
permeability of vas. endo ? Tissue edema
Plasma shifts to interstitial extra-cellular sp.
? ? intravascular volume

Concurrent hemorrhagic insult ? further reduction
in plasma volume
118
How will you resuscitate patients with trauma?

Fluid Resuscitation
Improves outcome ? morbidity
Restores physiological homeostasis
Balanced salt solution infusion current
standard
Give as rapid as possible 1-2 L in adults
20 ml / kg in children
No reported difference in outcome with
crystalloid v/s colloid resuscitation

119

Options
Isotonic crystalloids Readily available, least
expensive but larger infusion volume
required
Oncotic pr ? ? interstitial edema ? detrimental
to lung
Hypertonic crystalloids
Restore blood volume by maintaining a contracted
interstitial space
Small volume required
Believed to have positive inotropic effect on
myocardium ? in renal, mesenteric coronary
blood flow

120

Colloids
- Favored by some
- More rapid and effective correction of
intravascular volume deficits
- Natural Colloids Carry the risk of
transmission of infection (HCV, HIV etc.)
- Anaphylactoid reaction

121
Combined Crystalloid Colloid Resuscitation

Currently under investigation
Hypertonic component ? draws water out of
intra-cellular space replenishes extra-cellular
space.
Colloid component ? transiently partitions this
fluid in plasma space ? prolongs beneficial
hemodynamic effects
Studies indicate improved survival when
hypertonic saline and Dextran40 (HSD) are used
together.
HSD infusion Corrects meta. derangement
improves arterial O2 tension
? mesenteric renal micro-circulation

122
Conclusion

Accurate fluid, electrolyte assessment therapy
essential
Precise calculation of preop. deficits,
maintenance ongoing loss req. a must for proper
management of fluid homeostasis
Practical wisdom indicates it is dose rather than
the type of fluid that is important
Judicious fluid management a keen eye on pts
status go a long way in benefiting the pt.

123
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