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Hypotension, Shock, Hemorrhage
and IV Fluid Resuscitation
Ziad Sifri, MD
Surgical Fundamentals and Algorithmic Approach to Patient Care
July 30, 2010
The Goals
1. Definition and diagnosis of shock
2.
Classes of hemorrhagic shock and resuscitation
3. Algorithm for the identifying of the location of bleeding
4. IV access and resuscitation in a Trauma patient
5. Initial management of patients in non-hemorrhagic shock
6. Diagnosis of the various types of non-hemorrhagic shock
7. Management of non-hemorrhagic shock
The real goal however…….
is to avoid ….
Definition
• Def: Inadequate tissue Perfusion and Oxygenation
• Effect: Cellular injury, Organ failure, Death
• Causes: hemorrhagic and non-hemorrhagic
Types of Shock
S
Septic & Spinal
H
Hypovolemic & Hemorrhagic
O
Obstructive
C
Cardiogenic
K
Anaphylactic
Shock: “Clinical Diagnosis’
•
•
•
•
•
•
•
CNS: Altered MS – 2 extremes (Dr M. presentation)
CVS1: Tachycardia, ↑ diastolic BP, ↓ pulse pressure
CVS2:↓ MAP, ↓ cardiac output
Resp: Tachypnea and ↑O2 requirement (Dr M. presentation)
GU: Decrease U/O
GI: Ileus?
Skin: Progressive vasoconstriction-cool extremities
Shock: “Laboratory Support”
• Metabolic acidosis
– ABG: Acidosis, BD > -2
– Chem-7: ↓Bicarb
– Lactate: >2
• Metabolic acidosis 2nd to
– Inadequate tissue perfusion
– Shift to anaerobic metabolism
– Production of lactic acid
Pitfalls
•Extremes of age
•Infant>160; preschool 140; school age 120; adult 100
•Athletes
•Pregnancy
•Medications
•Beta blockers, pacemaker
•Hgb/Hct concentration
•Unreliable for acute blood loss
Other Pitfalls….
Urine output adequate
despite shock
•Alcohol
•Hyperglycemia
•Home medication: diuretic..
•Therapeutic intervention: Manitol
•IV contrast: CT, Angio
•Old residual urine…
•Etc…
General Outline
• Definition, diagnosis and types of shock
• Classes of Hemorrhagic shock and resuscitation
Hemorrhage & Trauma
• Normal blood volume
– Adults: 7% of ideal weight
• 70 kg man had blood volume of 5 liters
– Child: 9% of ideal weight
• Hemorrhage
– Loss of circulating blood volume
– How much volume loss to cause shock?
– Classes of hemorrhage I-IV
Hemorrhagic Shock: “The Classes”
“Class I”
“Class II”
“Class IV”
“Class III”
EBL
EBL
EBL
EBL
<750cc
<15% of TBV
750cc – 1500cc
15 – 30% of TBV
1.5L – 2L
30 – 40% of TBV
>2L
>40% of TBV
S&S
S&S
HR: increased
Pulse Pressure: decreased
BP: no change
HR: increased
BP: decreased
MS: agitated
Urine Output: decreased
Tx
Tx
S&S
None/minimal
Tx
Crystalloids
Crystalloids
1. Crystalloid (1 – 2L)
2. Transfusion (1 – 2units)
3. Identify source of Bleed(*5)
S&S
HR: increased
BP: decreased (<60)
MS: decreased
Tx
1.
2.
3.
4.
Crystalloid (2L)
Transfusion (2 – 4 units)
Identify source of Bleed(*5)
OR
General Outline
• Definition, diagnosis and types of shock
• Classes of Hemorrhagic shock
• Algorithm for identifying the location of bleeding
Algorithm to Identify the Bleeding Source
in a Hypotensive Trauma Patient
5 Possible locations
for significant bleeding
1
2
Abdominal Cavity
Chest cavity
-Chest trauma
- Diminished breath sounds
- Desaturation, ↑O2 requirement
Chest
X-Ray
(+) Ptx-Htx
FAST →
Free fluid
External Bleeding
Clue:
DPL → (+)
-Gross blood
- >105 RBCs
Chest tube
≥ 1L of Blood
Clue:
-Abdominal/Pelvic trauma
-Flank ecchymosis
-Unstable pelvis
-Hematuria
- Abdominal trauma
- Distended abdomen
DPL (+)
First do DPL
(supra umbilical)
r/o intrabdominal
bleed
Pelvic
X-Ray
(+) Fx
DPL (-)
1) Wrap sheet around pelvis
2) Pelvic angiography
OR →Thoracotomy
5
4
Pelvis/Retroperitoneum
Clue:
Clue:
Place chest tube
On affected side
3
Blood on Floor
→ Check head/scalp
→ Check extremity
Scalp
bleed
Whip-stitch
with
nylon suture
Extremity
Bleed
Pressure
and
Elevation
Bleeding not
controlled
Long Bones
Clue:
1) Deformed extremity
2) Crush injury
3) Mangled extremity
EBL
Femur Fx 750cc–1L
Tib Fx 500-750cc
Consult Ortho
Immobilization and
minimal manipulation
of injured extremity
using splint (3Ps)
OR → Exploratory laparotomy
(+) Blush/Extravasation
Angioembolization
Tourniquet proximal
to injury
- set > systolic BP
Be alert for
compartment
syndrome
Two Goals in the management of
Hemorrhagic Shock
“ID and Tx the cause”
“Support the patient”
Locate the source of
bleeding
Establish IV access
Control it
Fluid Resuscitation
Goal #1
“Identification and Treatment of the cause”
1-Locate the source of bleeding
2-Control it
Algorithm to Identify the Bleeding Source
in a Hypotensive Trauma Patient
5 Possible locations
for significant bleeding
1
Chest cavity
2
Abdominal Cavity
3
Pelvis/Retroperitoneum
4
External Bleeding
5
Long Bones
Algorithm to Identify the Bleeding Source
in a Hypotensive Trauma Patient
5 Possible locations
for significant bleeding
1
2
Abdominal Cavity
Chest cavity
-Chest trauma
- Diminished breath sounds
- Desaturation, ↑O2 requirement
Chest
X-Ray
(+) Ptx-Htx
FAST →
Free fluid
External Bleeding
Clue:
DPL → (+)
-Gross blood
- >105 RBCs
Chest tube
≥ 1L of Blood
Clue:
-Abdominal/Pelvic trauma
-Flank ecchymosis
-Unstable pelvis
-Hematuria
- Abdominal trauma
- Distended abdomen
DPL (+)
First do DPL
(supra umbilical)
r/o intrabdominal
bleed
Pelvic
X-Ray
(+) Fx
DPL (-)
1) Wrap sheet around pelvis
2) Pelvic angiography
OR →Thoracotomy
5
4
Pelvis/Retroperitoneum
Clue:
Clue:
Place chest tube
On affected side
3
Blood on Floor
→ Check head/scalp
→ Check extremity
Scalp
bleed
Whip-stitch
with
nylon suture
Extremity
Bleed
Pressure
and
Elevation
Bleeding not
controlled
OR → Exploratory laparotomy
(+) Blush/Extravasation
Angioembolization
Tourniquet proximal
to injury
- set > systolic BP
Long Bones
Clue:
1) Deformed extremity
2) Crush injury
3) Mangled extremity
EBL
Femur Fx 750cc–1L
Tib Fx 500-750cc
Consult Ortho
Immobilization and
minimal manipulation
of injured extremity
using splint (3Ps)
Be alert for
compartment
syndrome
Goal #2
“Support the patient”
1-Establish IV access
2-Fluid Resuscitation
Goal #2
“Support the patient”
1-Establish IV access
Establish IV access before it is too late
Resuscitation: Establish IV access
Must insure good vascular access:
•2 large caliber: 14-16-gauge IV
-Rate of flow is proportional to r4 and is inversely proportional to the length
-Short large caliber peripheral IVs are the best for resuscitation
•Central Access: Central line or Cordis
-Cannot obtain peripheral access
-IVDA, severe hypovolemia, extremity injury
-Massive bleeding
-Preferred Site: Femoral *
(*Unless pelvic or abdominal vascular injury suspected!)
Goal #2
“Support the patient”
2-Fluid Resuscitation
Fluid Resuscitation
Initial fluid bolus
1-2 liters in adults
20mL/kg in children
Intravascular effect
3 for 1 rule of volume replacement: volume lost
Type of fluid for resuscitation
-Isotonic electrolyte solution
Lactated ringers vs. normal saline
Electrolyte composition of crystalloid solutions
pH
Fluid
Na
Cl
Lactate
(mEq/L) (mEq/L) (mEq/l)
Ca
(mEq/L)
K
(mEq/L)
Osm
(mOsm/L)
LR
6.7
130
109
28
3
4
279
NS
6.0
154
154
0
0
0
308
LR, lactated Ringer’s solution; NS, normal saline solution
The 3:1 Rule
The effect of the 3:1 Rule
Assess patient’s response to fluid
resuscitation
• Clinical parameters:
– MS: return of
– CVS: HR, MAP
– Urinary output
• Laboratory parameters:
– BD, Acid/base balance
– Lactate
• Non responders:
– Something is still bleeding!
– Need for invasive monitoring
Avoid the “Lethal Triad”
• Coagulopathy
– Consumption of clotting factor
– Dilution of platelets and clotting factors: transfusion of PRBCs
– MTP (now in place at UMDNJ!)
• Hypothermia
– Perpetuates coagulopathy
– Most forgotten vital sign in resuscitation (check foley!)
• Acidosis
– Inadequate resuscitation and tissue perfusion
– Anaerobic metabolism and of lactic acid production
Case #1
38 year old male ped-struck found unresponsive. He gets
intubated by EMS and is reported to have a BP of 90/60
at the scene. He has a small head laceration as well as
obvious abrasions over his chest.
In the ED, he is noted to have decreased BS on the left side
and his O2 Sats are 92% on 100% NR.
What’s next?
Portable CXR
Case #1
• Diagnosis?
• Management?
Case #1 : CT Chest
Case #2
18 year old male involved in a high speed MVC found
unresponsive with a BP of 80/P at the scene. He has a
large head laceration that is actively bleeding, an obvious
abrasions over the pelvis and bilateral lower ext deform.
In the ED, he is immediately intubated, he has equal BS and
his sats are 100%. He is actively bleeding from his scalp
and left leg. BP 80/60 P 140.
Case #2
Dx?
Type of shock? Class?
Initial Management ?
Whip Stitch head laceration
What is missing ?
The Tourniquet
WHY IS THE PATIENT HYPOTENSIVE ?
???
AVOID GETTING THE FLOOR WET !!!!
Case #2
Still hypotensive!!!
He has received: 2 L crystalloids 2 units PRBCs
CXR: Normal
Portable Pelvic X-Ray
Before
After
General Outline
• Definition, diagnosis and types of shock
• Classes of Hemorrhagic shock
• Algorithm for identifying the location of bleeding
• IV Access and Resuscitation in a Trauma patient
• Initial Management of patients in non-hemorrhagic shock
Hypotension/Shock
Diagnosis
1.
2.
3.
4.
5.
6.
Hypotension (SBP<100)
Tachycardia
Tachypnea; Sa O2 <90%
Oliguria
Change in mental status (confusion, agitation)
Labs: Acidosis, Basic Deficit, Anion Gap, Lactate
Yes (patient is in shock)
Quick evaluation of A,B,C
*Notify senior resident on call and place the patient on ECG Monitor and pulse oximeter
A. Assess airway:
if inadequate
- BVM; call anesthesia to intubate if needed
B. Assess breathing:
if ↓ breath sounds
- CXR (stable pt)
- Place chest tube (unstable pt)
C. Assess circulation:
- No pulse → CPR
- Check rate rhythm →unstable arrhythmia → ACLS Protocol
First Step in MGT
1.
2.
3.
4.
5.
6.
7.
Make sure patient is on ECG monitor and Pulse Ox.
Administer O2
Insure adequate IV access
Place foley catheter
Place CVP line (when indicated)
Order EKG
Chest X-ray r/o Ptx
Shock
1
2
Hemodynamic findings
Hemodynamic findings
CVP, PCW: decreased
CO: decreased
SVR: increased
Hypovolemic
Shock
3
Hemodynamic findings
CVP, PCW: decreased
CO: increased then decreased
SVR: decreased
CVP, PCW: increased
CO: decreased
SVR: increased
Hemorrhagic
Shock
Cardiogenic Shock
Spinal Shock
Septic Shock
Cause
1. External fluid loss
2. 3rd Spacing
Treatment
Cause
Cause
1. Trauma (*5)
2. Post-op bleeding
3. GI bleeding
1. Fluid resuscitation
2. Control/replace
fluid losses
Cause
SCI (>T4 level)
Infection
Treatment
Supportive Care
→Fluid “to fill the tank”
→ Vaso pressors
(Phenylephirine, Norepinephrine)
Treatment
1. Fluid resuscitation
2. Find source of
bleeding and control it
3. Correct coagulopathy
Treatment
1.
2.
3.
-
Identify & drain source of infection
Start appropriate Abx
Supportive care
Fluid resuscitation
Vaso pressors
(Phenylephirine, Norepinephrine)
Non-obstructive
Obstructive
DDX
Cause
1. Tension PX
2. Cardiac tamponade
3. PE
1. AMI
2. CHF
Treatment
1. CT placement
2. Pericardiocentesis
3. IV Heparin
Treatment
1. Diuresis
- Lasix
2. Afterload reduction
- Nitroprusside, Nitroglycerine
- ACE inhibitor
3. Inotropic support
- Dobutamine, Milrinone
Hypovolemic Shock
Most common cause of shock in surgical patients
Excessive fluid losses (internal or external)
Internal: Pancreatitis, bowel ischemia, bowel edema, ascites..
External: Burns, E-C Fistula, Open wounds…
Again : 2 goals
1- ID and Tx the cause
Control fluid losses: surgical, wound coverage…
2- Support the Patient
Hypovolemic Shock
Hemodynamically:
*Low to normal PCW (due to fluid losses)
Normal or Decreased CO
High SVR (compensation)
Septic Shock
Second most common cause of shock in surgical patients
Vasoregulatory substances released produce a decrease in systemic
vascular resistance, manifested by warm pink skin with peripheral
vasodilatation
Again 2 goals
1- ID and Tx the cause
Source Control: surgical, IR + start early antibiotics
2- Support the Patient
Septic Shock
Hemodynamically:
Low to normal PCW (vasodilatation and fluid losses)
Normal or increased CO
*Low SVR (primary condition!)
Cardiogenic Shock
• Forward blood flow is inadequate secondary to pump failure
• Most common cause is acute myocardial infarction (AMI)
• Other causes include:
•Myocardial contusion, Aortic insufficiency, End-stage cardiomyopathy
Two goals:
1- ID and Tx the cause: Heparin, Cardiac Cath…
2- Support the Patient
Cardiogenic Shock
Hemodynamics:
Elevated filling pressures
*Diminished cardiac output due to pump failure
Increased SVR (compensation)
Obstructive Cardiogenic Shock
No intrinsic cardiac pathology (MI..)
Pump failure due to inflow or outflow obstruction
Cause :
Tension Pneumothorax
PE
Cardiac Temponade
Air embolus (rare)
Dx and Management specific to each process
Neurogenic Shock
Spinal cord injuries produce hypotension due to a loss of
sympathetic tone
Seen in one third of patients with SCI, usually seen in patients with
an injury above T4 level
Hypotension without tachycardia or cutaneous vasoconstriction
Pearl: Must rule out other causes of shock in multiple trauma patients with a spinal cord
injury
Neurogenic Shock
Hemodynamics:
Normal to low PCW – due to peripheral venous pooling
Normal to low CO- cannot compensate
*Decreased SVR – due to loss of vasomotor tone
Shock
1
2
Hemodynamic findings
Hemodynamic findings
CVP, PCW: decreased
CO: decreased
SVR: increased
Hypovolemic
Shock
3
Hemodynamic findings
CVP, PCW: decreased
CO: increased then decreased
SVR: decreased
CVP, PCW: increased
CO: decreased
SVR: increased
Hemorrhagic
Shock
Cardiogenic Shock
Spinal Shock
Septic Shock
Cause
1. External fluid loss
2. 3rd Spacing
Treatment
Cause
Cause
1. Trauma (*5)
2. Post-op bleeding
3. GI bleeding
1. Fluid resuscitation
2. Control/replace
fluid losses
Cause
SCI (>T4 level)
Infection
Treatment
Supportive Care
→Fluid “to fill the tank”
→ Vaso pressors
(Phenylephirine, Norepinephrine)
Treatment
1. Fluid resuscitation
2. Find source of
bleeding and control it
3. Correct coagulopathy
Treatment
1.
2.
3.
-
Identify & drain source of infection
Start appropriate Abx
Supportive care
Fluid resuscitation
Vaso pressors
(Phenylephirine, Norepinephrine)
Non-obstructive
Obstructive
DDX
Cause
1. Tension PX
2. Cardiac tamponade
3. PE
1. AMI
2. CHF
Treatment
1. CT placement
2. Pericardiocentesis
3. IV Heparin
Treatment
1. Diuresis
- Lasix
2. Afterload reduction
- Nitroprusside, Nitroglycerine
- ACE inhibitor
3. Inotropic support
- Dobutamine, Milrinone
CASE # 3
• A 50 year old woman with unresectable pancreatic CA
with a T-Bili of 20 returns from IR after upsizing of her
PTC drains. She is confused, hypotension and has
decreased urine output. She is intubated and transferred
to the SICU.
• What is ur Dx?
• What is ur initial mgt?
• Hemodynamics: CVP = 5 PCW = 8 C0= 8 SVR = 300.
CASE # 4
• A 35 year old with a T-2 compete SCI and Grade III
splenic lac arrives to the SICU. He is awake and stable .
2 hours later the nurse reports that he is hypotension (BP
80/40) with a HR of 60. He remains hypotensive despite
2L of fluid. His BD is -5 and has decreased urine output
• What is ur Dx?
• What is ur mgt ?
• Hemodynamics: CVP = 3 PCW = 3 C0= 5 SVR = 900
Conclusion
1. You now know how recognize and diagnose shock
2. You know the classes of hemorrhagic shock
3. You have an algorithm to find the location of bleeding
4. You have an algorithm for the initial management of
patients in non-hemorrhagic shock
5. You know how to Dx the types of non-hemorrhagic shocks
6. You know the 2 key Goals in the management of any shock
THANK YOU
?