"Rico has something in his eye" test hints

Question 1

define + explain meumonic “DIMS”

Answer 1

mnemonic for differentiating seizures/AMS

Drugs (intoxication or withdrawal)
Infection (CNS or systemic)
Metabolic and Endocrine (hyper/hypoglycemia, thyroid, HPA axis, etceteraaaaa)
Structural (CNS lesion/mass)

Question 2

“D” in DIMS

Answer 2

DRUGS

1. Overdose of prescription drugs
2. illicit drug toxicity
3. withdrawl from drugs or illicit substances

Question 3

“I” in DIMS

Answer 3

INFECTIONS

1. pneumonia
2. urinary
3. skin/soft tissue
4. abdomen
5. CNS infection

Question 4

“M” in DIMS

Answer 4

METABOLIC/ENDOCRINE

1. altered pH
2. hypo/hyper Na+ Ca++
3. acute liver or renal failure
4. diabetic ketoacidosis
5. Endocrinopathies (hypo-/hyper-cortisol, hypoglycemia thyrotoxicosis)

Question 5

Shock states diagram thing for different hemodynamic values (CO, SVR, MAP, CVP, PCWP)

CARDIOGENIC

Answer 5

1. MAP: decreased
2. CO/SV: decreased
3. CVP: increased (right sided failure)
4. PCWP: increased (left sided failure backing up into lungs)
5. SVR: increased (clamping down, peripheral compensation)

Question 6

Shock states diagram thing for different hemodynamic values (CO, SVR, MAP, CVP, PCWP)

EARLY DISTRIBUTIVE

Answer 6

1. MAP: decreased
2. CO/SV: increased
3. CVP: decreased
4. PCWP: decreased
5. SVR: decreased

Question 7

Shock states diagram thing for different hemodynamic values (CO, SVR, MAP, CVP, PCWP)

HYPOVOLEMIC

Answer 7

1. MAP: decreased
2. CO/SV: increased
3. CVP: decreased
4. PCWP: decreased
5. SVR: increased

Question 8

Shock states diagram thing for different hemodynamic values (CO, SVR, MAP, CVP, PCWP)

LATE DISTRIBUTIVE

Answer 8

1. MAP: decreased
2. CO/SV: decreased
3. CVP: decreased
4. PCWP: increased
5. SVR: decreased

Question 9

Shock states diagram thing for different hemodynamic values (CO, SVR, MAP, CVP, PCWP)

OBSTRUCTIVE (PE)

Answer 9

1. MAP: decreased
2. CO/SV: decreased
3. CVP: increased (↑ RV afterload)
4. PCWP: decreased
5. SVR: increased (compensatory peripheral clamping down)

Question 10

Shock states diagram thing for different hemodynamic values (CO, SVR, MAP, CVP, PCWP)

OBSTRUCTIVE (tamponade)

Answer 10

1. MAP: decreased
2. CO/SV: decreased
3. CVP: increased
4. PCWP: increased
5. SVR: increased

Question 11

“2 salt and a sticky BUN”

Answer 11

This is the formula for obtaining a CALCULATED serum osmolarity

1. Serum calculated osmolarity = “2 salt and a sticky BUN”
2. calculated by the following equation: Calculated osmolality = (2 x Na) + Glucose + BUN + (1.25 x ETOH)

the last portion is a correction factor for alcohol

To obtain your Osmolar gap take your serum Osmolality (measured) – serum Osmolarity (calculated). normal range is -10 to +10

Question 12

muscarinic effects of organophosphate poisoning

Answer 12

1. Muscarinic receptors in heart, eye, lung, GI, skin and sweat glands
2. Bradycardia
3. Miosis
4. Bronchorrhea / Bronchospasm
5. Hyperperistalsis (SLUDGE)
6. Sweating
7. Vasodilation

Question 13

nicotinic effects of organophosphate poisoning

Answer 13

1. fasciculations, flaccid paralysis

2. Tachycardia, hypertension

Question 14

discuss + explain the hypothalamic pituitary adrenal (HPA) axis

Answer 14

DISCUSS

1. The HPA axis is our central stress response system
2. The HPA axis is responsible for the neuroendocrine adaptation component of the stress response

EXPLAIN

1. hypothalamus releases corticotropin-releasing hormone. CRF binds to CRF receptors on the anterior pituitary gland → adrenocorticotropic hormone (ACTH) release
2. ACTH binds to receptors on the adrenal cortex → adrenal release of cortisol
3. At a certain blood concentration of cortisol, the cortisol exerts negative feedback to the hypothalamic release of CRF → stoppage of pituitary release of ACTH (via negative feedback loop)
4. systemic homeostasis returns

Question 15

AEIOU Indications for Dialysis in Patients with Acute Kidney Injury

Answer 15

1. A – Acidosis – metabolic acidosis with a pH <7.1
2. E – Electrolytes – refractory hyperkalemia with a serum potassium >6.5 mEq/L or rapidly rising potassium levels
3. I – Intoxications – use the mnemonic SLIME to remember the drugs and toxins that can be removed with dialysis: salicylates, lithium, isopropanol, methanol, ethylene glycol
4. O – Overload – volume overload refractory to diuresis
5. U – Uremia – elevated BUN with signs or symptoms of uremia, including pericarditis, neuropathy, uremic bleeding, or an otherwise unexplained decline in mental status (uremic encephalopathy)

Question 16

CCP Interventions to correct abdominal compartment syndrome

Answer 16

1. sedation & analgesia (Improve Abdominal Wall Compliance)
2. head of bed elevation at 30 degrees (Improve Abdominal Wall Compliance)
3. neuromuscular blockade (Improve Abdominal Wall Compliance)
4. gastric decompression with OG tube (Evacuate Intra-Luminal Contents)
5. avoid excessive fluid (Correct Positive Fluid Balance)
6. diuretics (Correct Positive Fluid Balance)
7. maintain a APP > 60mmHg with vasopressors (organ support)
8. optimise ventilation strategies (organ support)

Question 17

Intra-abdominal pressure (IAP) definition

Answer 17

1. the steady state pressure concealed within the abdominal cavity

Question 18

Intra-abdominal Hypertension (IAH) definition

Answer 18

1. sustained intra-abdominal pressure (IAP) of > 12mmHg

Question 19

Abdominal Compartment Syndrome (ACS) definition

Answer 19

1. sustained IAP > 20mmHg with new organ failure

Question 20

Intraperitoneal Structures

Answer 20

S - stomach
A - appendix
L - liver
T -transverse colon, sigmoid colon, upper third of the rectum
D - duodenum (the first 5cm)
S - small intestine (the jejunum, the ileum, the cecum)
P - pancreas (tail)
R - reproductive organs uterus, fallopian tubes, ovaries, gonadal blood vessels (female)
S - spleen
S

Question 21

Retroperitoneal Structures

Answer 21

S - suprarenal structure 
A - aorta
D - duodenum 
P - pancreas 
U - ureters 
C - colon (A + D)
K - kidneys 
E - esophagus 
R - rectum

Question 22

biliary tree anatomical/physiological pathway

Answer 22

1. biliary tree is a series of GI ducts allowing newly formed bile from the liver to be concentrated and stored in the gallbladder prior to release into the duodenum
2. Bile is secreted from hepatocytes and drains from both lobes of the liver via intralobular ducts and collecting ducts into the left and right hepatic ducts
3. left and right hepatic ducts join to form the common hepatic duct, which runs alongside the hepatic vein
4. common hepatic duct descends and is joined by the cystic duct which regulates bile flow in and out of the gallbladder for storage and release
5. the common hepatic duct and cystic duct combine to form the common bile duct
6. common bile duct descends and passes posteriorly to the duodenum and head of pancreas
7. common bile duct now joined by main pancreatic duct, forming the hepatopancreatic ampulla (ampulla of Vater) – which then empties into the duodenum via the major duodenal papilla
8. major duodenal papilla is regulated by a muscular valve, the sphincter of Oddi

Question 23

define Budd-Chiari syndrome

Answer 23

1. congestive hepatopathy caused by blockage of hepatic veins
2. Two of the hepatic veins must be blocked for clinically evident disease
3. Liver congestion and hypoxic damage of hepatocytes eventually result in predominantly centrilobular fibrosis
4. The obstruction may be thrombotic or non-thrombotic anywhere along the venous course from the hepatic venules to junction of the inferior vena cava (IVC) to the right atrium

Question 24

If someone has an elevated INR from cirrhosis and is not on warfarin should they get PCC’s for reversal of coagulopathy?

Answer 24

1. No
2. Don’t be stupid
3. It’s not gonna do anything
4. You’ll just look like an idiot

Question 25

markers of liver injury vs LFT’s

Answer 25

Liver Injury

1. There are five main markers of liver injury
2. ALT, AST, gamma-glutamyltransferase (GGT), alkaline phosphatase (ALP) and total bilirubin

Liver Function Tests

1. Bilirubin
2. Glucose
3. Albumin
4. INR
5. PT

Question 26

Octreotide describe/define + dosage

Answer 26

1. a somatostatin analogue in variceal and non-variceal upper GI bleeding (UGIB)
2. binds with endothelial cell somatostatin receptors, inducing strong, rapid and prolonged vaso-constriction
3. Decreases Portal/Splanchnic Pressure –> Potential to Decrease Bleeding and Rebleeding
4. Decrease Acid Secretion –> Prevent Clot Dissolution
5. 50 mcg IV bolus (range 25-100mcg), followed by 25-50 mcg/hr drip

Question 27

common modes of RRT

Answer 27

Modes of continuous RRT (CRRT)

1. Slow Continuous Ultrafiltration (SCUF)
2. Continuous Venovenous Hemodialysis (CVVHD)
3. Hemofiltration (CVVHF)
4. Hemodiafiltration (CVVHDF)
5. Continuous Arterio-Venous Hemofiltration (CAVHF),
6. Slow low-efficiency daily dialysis (SLEDD)

Other:

Peritoneal dialysis (PD)
Plasmapheresis or plasma exchange
Intermittent Hemodialysis (IHD)

Question 28

IHD vs CRRT

Answer 28

IHD:

Name: Intermittent hemodialysis
Mechanism and molecules removed: Dialysis – mostly low Molecular Weight
Use: Ambulatory CRF, Hyperkalemia
Blood flow: 300 - 400 mL/min
Dialysate flow: 500 mL/min or 30 L/hr
Efficiency: High
Urea clearance: (mL/min) 150
Hemodynamic stability: Poor (hypotension common)
Duration: 3-4 h 3x/week
Access: Fistula or vascath (must be good!)
Anticoagulation: Not needed
Dialysis Dysequilibrium Syndrome (DDS): Insufficient time for equilibration between compartments can cause cerebral edema
Drugs and toxicology: Risk of rebound if high VD. Better for low VD (e.g. toxic alcohols)
Logistics: Need tap water supply, need hygienic effluent removal, Technically difficult

CRRT:

Name: Continuous renal replacement therapy
Mechanism and molecules removed: Small + middle molecules with CVVHDF
Use: Critically ill/Non-ambulatory
Blood flow: 150 - 200 mL/min
Dialysate flow: CVVHF: nil/CVVHDF: 1 L/h
Efficiency: Low (but increased clearance of high VD molecules over time)
Urea clearance: (mL/min) 30 (CVVHDF)
Hemodynamic stability: Good
Duration: Continuous (24h/filter)
Access: Vascath only
Anticoagulation: Important (if filter clots can lose ~150 mL blood)
Dialysis Dysequilibrium Syndrome (DDS): N/A
Drugs and toxicology: Slower removal
Logistics: High workload, clearance limited by interruptions, costly sterile dialysate bags, immobility

Question 29

SIADH versus CSW

Answer 29

SIADH

1. hyponatremia (decreased serum Na+, increased urine Na+) LOW SERUM SODIUM
2. euvolemia/slight hypervolemia NORMAL VOLUME
3. CVP normal-high NORMAL VOLUME
4. decreased urine output (d/t ↑ urine osmolality)
5. Replace salt (3% HTS)
6. water retention d/t elevated ADH levels
7. increased urine sodium

CSW

1. hyponatremia (decreased serum Na+, increased urine Na+)
2. hypovolemia/dehydrated (patient is DRY)
3. CVP low DECREASED VOLUME
4. increased urine output
5. Replace fluids (0.9% NS)
6. excess secretion of sodium + water
7. increased urine sodium

Question 30

AKIN Classification for Acute Kidney Injury

Answer 30

Classifies severity of acute kidney injury, similar to RIFLE Criteria

To be diagnosed with acute kidney injury by the AKIN definition, patient must have at least one of the following within the past 48 hours

1. Absolute increase in serum creatinine ≥26.4 μmol/L
2. Increase in serum creatinine ≥1.5x above baseline
3. Oliguria (urine output <0.5 mL/kg per hour) for >6 hours

Question 31

RIFLE Criteria for Acute Kidney Injury (AKI)

Answer 31

1. Classifies severity of acute kidney injury, similar to AKIN Classification

Question 32

optimal blood product transfusion ratio in trauma

Answer 32

1. Haemostatic resuscitation involves resuscitation with blood components resembling whole blood
2. aims to avoid or ameliorate acute coagulopathy of trauma and the complications of aggressive crystalloid fluid resuscitation while maintaining circulating volume
3. Involves blood component ratios of 1 unit PRBCs : 1 unit FFP : 1 unit platelets

Question 33

how does ARDS relate to trauma (how does trauma lead to ARDS)

Answer 33

1. Severe trauma predisposes to ALI and ARDS
2. development of ARDS may be related to mechanism of injury (eg, lung contusion, long bone fracture leading to fat embolism) or resuscitation (eg, transfusion)
3. In a study that included 1762 patients with major traumatic injury, ARDS occurred in 24%
4. Predictors of ARDS after trauma included increasing subject age; increasing APACHE II score; increasing injury severity score; and the presence of blunt injury, pulmonary contusion, massive transfusion, or flail chest.

Question 34

ACS treatment pathway

Answer 34

1. Dual antiplatelet therapy (Aspirin + P2Y12 inhibitor)
2. Anticoagulant (UFH/enoxaparin/fondaparinux)
3. Oxygen (sats >90%)
4. Rate control (Metoprolol)
5. Analgesia (NTG, opioids)
6. Statin therapy
7. Reperfusion (TnK or PCI)
8. Angiotensin-converting enzyme inhibitors or ARB’s

Question 35

discuss “thrombolytic facilitated PCI”

Answer 35

1. thrombolytic facilitated PCI is using thrombolysis as a mechanism to facilitate a “better” PCI. (Ie giving a dose of lytics’ before PCI even when the person would be within the window timeframe for primary PCI)
2. Don’t do it
3. Facilitated PCI is bullshit

Question 36

mechanisms of preload assessment

Answer 36

1. Passive leg raise
2. Decrease in HR when you give a fluid bolus
3. Use ultrasound to assess IVC collapsibility (patient must be sedated/paralyzed/on VCV
4. CVP assessment
5. JVP height measurement
6. Arterial waveform pulse pressure variation (SBP delta P variation of 16%)

Question 37

mechanisms of perfusion assessment

Answer 37

1. Extremities colour, temperature, cap refill, mottling
2. If cold skin, mottling, or delayed cap refill grab your ultrasound, look at the heart, consider dobutamine to improve forward flow

Question 38

Discuss the appropriate times to contact PTCC during a scene response and IFT

Answer 38

1. Upon receiving the initial call
2. Upon takeoff/leaving for the call
3. Prior to takeoff departing the sending heading for the receiving
4. If there are any logistical changes that need to be clarified/made/communicated
5. When you are clear of the call

Question 39

Cranial nerves 1-12

Answer 39

1. Olfactory
2. Optic
3. Oculomotor
4. Troclear
5. Trigeminal
6. Abducens
7. Facial
8. Vestibulocochlear
9. Glossopharyngeal
10. Vagus
11. Accessory
12. Hypoglossal

Question 40

Assessment for CN I (olfactory)

Answer 40

“Can you smell this” or “do you have any problems with your smell”

Official test is to hold up a jar of coffee or some such item

Question 41

Assessment for CN II (optic)

Answer 41

“Can you see this”

Visual acuity, peripheral vision (Snellen Chart)

pure sensory

Question 42

Assessment for CN III (oculomotor)

Answer 42

Open eyelids. Eye movement up and in (Perform H test)

Question 43

Assessment for CN IV (trochlear)

Answer 43

Eye movement down. (Perform the H test)

Question 44

Assessment for CN V (trigeminal)

Answer 44

Facial sensation x 3 “TRIgeminal”. Sensation at top, middle, bottom of face . compare right vs left

MIXED motor/sensory

Question 45

Assessment for CN VI (abducens)

Answer 45

Eye movement lateral (Perform the H test)

motor

Question 46

Assessment for CN VII (facial)

Answer 46

“smile, show me your teeth. Raise your eyebrows” looking for facial symmetry

Question 47

Assessment for CN VIII (vestibulocochlear)

Answer 47

“Can you hear this”

Hearing bilaterally, balance (assessing for vertigo)

pure sensory

Question 48

Assessment for CN IX (glossopharyngeal)

Answer 48

taste on the tongue (sensory), swallowing (motor)

mixed motor/sensory

Question 49

Assessment for CN X (vagus nerve)

Answer 49

swallowing reflex (motor)/parasympathetic response (sensory)

mixed motor/sensory

Question 50

Assessment for CN XI (accessory nerve)

Answer 50

have the patient shrug their shoulders up and down

pure motor

Question 51

Assessment for CN XII (hypoglossal nerve)

Answer 51

stick out your tongue, move your tongue around (motor)

Question 52

Cough reflex (unconscious/sedated patient)

CN’s and how to assess

Answer 52

CN X [Vagus]

can be stimulated by a suction catheter down and endotracheal tube

Question 53

Gag reflex (unconscious/sedated patient)

CN’s and how to assess

Answer 53

CN IX [Glossopharyngeal] and X [Vagus]

Some sources recommend shaking the endotracheal tube, whereas others recommend inserting a tongue depressor or suction catheter into the posterior pharynx.

Question 54

corneal reflex (unconscious/sedated patient)

CN’s and how to assess

Answer 54

CN V [Trigeminal] and CN VII [Facial]

the provider lightly touches a wisp of cotton on the patient’s cornea. This foreign body sensation should cause the patient to reflexively blink.

Question 55

anions vs cations

Answer 55

1. cations are positively charged

2. anions are negatively charged

Question 56

Define the KULT acronym for metabolic acidosis

Answer 56

1. KETOACIDOSIS
2. UREMIA
3. LACTIC ACIDOSIS
4. TOXINS (includes medications)

Question 57

What are the causes of a low AG?

Answer 57

1. Decreased albumin
2. GI ingestion (tums)
3. Lab error
4. Math error

most commonly it’s gonna be a math error or a lab error

Question 58

what is the 5 step CCP process to ABG interpretation

Answer 58

1. State the ‘emia’. Is it acidemia or alkalemia?
2. State the ‘osis’. What is the driver? Metabolic vs Respiratory
3. Calculate the AG. Na - (HCO3- + Cl) = x (corrected for albumin)
4. Expected compensation? Does the patient have appropriate compensation?
5. Is there a superimposition present?

Question 59

Causes of NAGMA

Answer 59

1. RTA (failure of kidneys to Reabsorb all of the filtered bicarbonate and/or failure of kidneys to Synthesize new bicarbonate to
   replace bicarbonate lost to metabolism
2. GI losses (puking/shitting out all your bicarb)
3. Hyperchloremia (too much NS)

Question 60

MUDPILES CAT

Answer 60

M - Methanol, metformin (increases lactate)
U - Uraemia
D - Diabetic ketoacidosis
P - paracetamol, paraldehyde, Phenformin, pyroglutamic acid, propylene glycol
I - Iron, isoniazid
L - Lactate (numerous causes)
E - Ethanol, ethylene glycol
S - Salicylates

C - Cyanide, carbon monoxide
A - Alcoholic ketoacidosis
T - Toluene

Question 61

Expected compensation ratio (pCO2:HCO3-) for metabolic acidosis

Answer 61

1:1

Question 62

Expected compensation ratio (HCO3- : pCO2) for metabolic alkalosis

Answer 62

1:0.7

Question 63

Expected compensation ratio (pCO2:HCO3-) for respiratory alkalosis

Answer 63

1:0.5

Question 64

Expected compensation ratio (pCO2:HCO3-) for respiratory acidosis

Answer 64

1:0.3

Question 65

Liver function tests

Answer 65

1. Bilirubin
2. Glucose
3. Albumin
4. INR
5. PT

Question 66

Liver enzymes

Answer 66

1. AST
2. ALT
3. GGT
4. Alkaline phosphatase (ALP)

Question 67

Which coagulation factors are dependent upon vitamin K for synthesis?

Answer 67

X, IX, VII, II (prothrombin group)

10-9-7-2

Question 68

Normal range for platelets

Answer 68

130–380 × 10⁹/L

Question 69

Normal range for INR (non anti-coagulated blood)

Answer 69

0.9–1.2

Question 70

Normal range for Prothrombin time (PT)

Answer 70

10–14 seconds

Question 71

Normal range for aPTT (non anti-coagulated blood)

Answer 71

22-30 seconds

Question 72

Normal range for fibrinogen

Answer 72

2.0 to 4.0 g/L

Question 73

Normal range for hemoglobin

Answer 73

Male 125–170 g/L

Female 115–155 g/L

Question 74

Hemostatic goals in trauma

Answer 74

1. Hgb > 70
2. Platelets > 100
3. INR < 1.8
4. Temp > 36
5. Fibrinogen > 1.5

Question 75

4 A’s of anesthesia

Answer 75

1. amnesia
2. analgesia
3. areflexia
4. autonomic stability

Question 76

Big syringe (“three syringes principle”)

Answer 76

1. induction agent. “amnesia”.

2. typically a “big syringe” because push dose propofol is done in a 20cc syringe

Question 77

Little syringe (“three syringes principle”)

Answer 77

1. analgesic agent and/or paralytic agent. “analgesia” + “areflexia”.
2. usually a 10cc syringe “little” because it’s smaller than the 20cc propofol syringe

Question 78

Chaser syringe (“three syringes principle”)

Answer 78

1. hemodynamic support agent.
2. examples include push dose epinephrine, phenylephrine, atropine
3. “chases” your induction to maintain autonomic stability. 4. depending on how unstable the patient is, you may lead with your chaser syringe

Question 79

depolarizing NMBA and mechanism

Answer 79

1. succinylcholine

2. binds to and activates the ACh receptor, at first causing muscle contraction, then paralysis

Question 80

non-depolarizing NMBA and mechanism

Answer 80

1. rocuronium

2. competitively blocks the binding of ACh to its receptors

Question 81

causes of increased airway resistance

Answer 81

1. bronchospasm
2. ETT problems (too small/kinked/bitten/flexed/obstructed)
3. mucus plugging/secretions
4. water in HME
5. blocked exhalation valve

Question 82

causes of decreased lung compliance

Answer 82

1. ARDS
2. atelectasis
3. abdominal distention (abdominal HTN)
4. CHF
5. consolidation
6. fibrosis (pulmonary fibrosis)
7. hyperinflation
8. pneumothorax
9. pleural effusion

Question 83

Oxygen delivery equation (DO2)

Answer 83

1. DO2 = CO x CaO2 (mL/min/m2)

2. CaO2 = (1.34 X Hgb X SaO2) + (0.003 X PaO2)

Question 84

4 types of hypoxia

Answer 84

1. hypoxic
2. hypemic
3. stagnant
4. histotoxic

Question 85

5 causes of hypoxemia

Answer 85

1. V/Q mismatch
2. Diffusion impairment
3. Shunt (think right to left shunt)
4. Hypoventilation
5. Decreased partial pressure of inspired oxygen (think high altitude)

Question 86

Virchow’s triad

Answer 86

1. Hypercoagulability
2. Vascular stasis
3. Endothelial injury/dysfunction

Question 87

adverse effects of oxygen d/t hyperoxia and oxygen toxicity

Answer 87

Cellular injury due to increased ROS (reactive oxygen species)

1. Increased ROS eg superoxide anion, hydroxyl radical, hydrogen peroxide
2. ROS lead to inflammation and secondary tissue injury / apoptosis
3. deplete cellular antioxidant defences
4. react / impair function of intracellular macromolecules
   cell death

Respiratory

1. pulmonary vasodilation resulting in V/Q mismatch and CO2 retention in COPD
2. Haldane effect leads to decreased affinity of Hb for CO2 and contributes to CO2 retention in COPD
3. increased mortality in CO2 retainers from high flow O2 compared with titrated O2 in a prehospital RCT
4. increased respiratory rate
5. Denitrogenation of the lungs causing resorption atelectasis
6. Bronchopulmonary dysplasia: neonates
7. > 60% O2 causes tracheal irritation, sore throat, substernal pain, pulmonary congestion, decreased VC
8. Dry nose and mouth, increased susceptibility to mucous plugging
9. Increased R to L shunt fraction
10. Accelerated lung injury from bleomycin toxicity and paraquat poisoning
11. Delay recognition of hypoventilation by SpO2 monitoring during sedation (irrelevant if using ETCO2 monitoring)

Immune

1. Increased risk of secondary lung infection due to: impaired mucociliary clearance
2. decreased bactericidal capacity of immune cells

Cardiovascular

1. Increased mortality post-cardiac arrest with hyperoxia (PaO2>300 mmHg)
2. Systemic vasoconstriction leading to increased SVR, increased BP, decreased heart rate and decreased cardiac output
3. Normobaric hyperoxia reduces coronary blood flow by 8 to 29% in normal subjects and in patients with coronary artery disease or chronic heart failure
4. Increased myocardial infarct size (AVOID study, 2015)
5. No reduction in myocardial ischemia in the presence of coronary artery disease unless SpO2 <85-90%
6. Impairs endothelium-mediated vasodilation

Neurological

1. Acute toxicity with hyperbaric 100% O2 causing altered mood, vertigo, LOC, convulsions
2. Retinopathy of prematurity
3. Hyperoxia decreases cerebral blood flow by 11 to 33% in healthy adults
4. Hyperoxia associated with increased mortality in stroke and TBI

Haematological

1. Prolonged exposure to 100% O2 impairs erythropoiesis

Question 88

benefits of NIPPV

Answer 88

1. increased oxygenation
2. increased end organ perfusion of oxygen
3. increased ventilation
4. decreased work of breathing
5. potentially avoids intubation

Question 89

Contraindications to NIPPV

Answer 89

1. Cardiac arrest
2. Respiratory arrest
3. Unable to protect airway
4. Upper airway obstruction with foreign bodies
5. Untreated or loculated pneumothorax found on imaging
6. SHOCK
7. Post GI surgery (caution)
8. Maxillofacial injury
9. Intractable vomiting

Question 90

CCP approach to establishing Mech Vent

Answer 90

1. Am I adequately oxygenating (PaO2)
2. Am I ventilating appropriately (PaCO2)
3. Am I on safe ground
4. What is my current acid-base status

Question 91

Goals of NIPPV

Answer 91

1. Decrease WOB (unload respiratory muscles)
2. Increase FRC
3. Improve atelectatic recruitment
4. Improve lung compliance
5. Improve oxygenation
6. Decrease LV preload, decrease LV afterload, improve cardiac output, improve forward flow
7. PEEP matching for autoPEEP

Question 92

Adverse effects of NIPPV

Answer 92

1. Local skin damage around bridge of nose
2. Mask leak
3. Eye and mouth irritation from mask leak air flow
4. Sinus pain and sinus congestion
5. Claustrophobia
6. Mild gastric distention

Question 93

target UO in sepsis

Answer 93

1. > 0.5mL/kg/hr

Question 94

PULMONARY EDEMA + LOW BP (“wet and cold” Cardiogenic Shock) treatment algorithm

Answer 94

1. IV/O2/Monitor
2. Differentiating the shock (pump failure vs mechanical complications)
3. fix the lungs
4. optimize the MAP
5. optimize volume status
6. consider inotrope for HFrEF
7. treat underlying etiology
8. mechanical circulatory support

Question 95

treatment for patients who are “cold and wet”

Answer 95

1. Systemic hypoperfusion due to low cardiac output (cold)
2. Filling pressures are elevated (wet)
3. Giving volume will worsen their pulmonary congestion (making them wetter)
4. Removing volume will worsen their systemic hypoperfusion (making them colder)
5. Management of cold and wet cardiogenic shock usually requires interventions to improve cardiac function (e.g., inotropic medications, revascularization, or a mechanical support device)

Question 96

discuss “fixing the lungs” in acute HF

Answer 96

1. NIPPV will reduces cardiac preload and afterload, and improve VQ matching. The most important parameter is the expiratory pressure (CPAP), which should be ramped up rapidly if possible
2. Intubation is Often needed for frank cardiogenic shock (especially patients with delirium due to brain hypoperfusion). Intubation Provides full support for the work of breathing, which may allow shunting of blood away from the diaphragm and towards vital organs
3. If the patient has large pleural effusion and this is causing significant respiratory distress or hypoxemia, then therapeutic drainage may be beneficial

Question 97

discuss “optimize the MAP” in acute HF

Answer 97

1. the blood pressure needs to be high enough to perfuse the organs. However, if the pressure is too high, this will ↑ the workload on the heart (excessive afterload) → increased MVO2
2. Often an ideal BP will be in the low-normal range (e.g. MAP 60-65 mmHg)
3. hypertension should be managed with afterload reduction. Afterload reduction may ↑ CO, ↓ pulmonary edema, and ↓ MVO2.
4. In the acute phase, high-dose NTG infusion is the preferred vasodilator
5. hypotension may be managed with an inopressor (e.g., epinephrine or norepinephrine). Norepinephrine is recommended as a front-line agent for cardiogenic shock. Epinephrine may be a reasonable choice for a patient with ↓ EF, hypotension, bradycardia. and poor CO

Question 98

discuss “optimize the volume status” in acute HF

Answer 98

Consider giving a fluid challenge if the following conditions are met:

1. There is insufficient end-organ perfusion (e.g. acute kidney injury).
2. No evidence of pulmonary congestion (e.g. no B-lines on lung ultrasonography).
3. Overall assessment suggests true hypovolemia (e.g. no systemic congestion).

Consider diuresis if the following conditions are met:

1. There is significant pulmonary and/or systemic congestion.
2. Overall assessment suggests total body fluid overload.

Question 99

CCP approach to CXR interpretation

Answer 99

1. Patient Information
2. Previous Imaging
3. Technique
4. Adequacy
5. Heart
6. Mediastinum
7. Lungs and Lung Borders
8. Soft Tissues
9. Bones
10. Lines and Tubes

Question 100

NG versus OG tube on CXR

Answer 100

NG tube appears larger because it has two radiopaque line that create the illusion of a bigger structure

Question 101

3 zones of the neck

Answer 101

Zone 3 - Angle of mandible to base of skull
Zone 2 - Cricoid to angle of mandible
Zone 1 - Clavicle to cricoid cartilage

Question 102

Zone III (upper neck) structures

Answer 102

Distal portion of the internal carotid arteries
Vertebral arteries
Jugular veins
Pharynx
Spinal cord
Cranial nerves IX, X, XI, XII
Sympathetic chain
Salivary and parotid glands

Question 103

Zone II (midneck) structures

Answer 103

Common carotid arteries
Internal and external branches of carotid arteries
Vertebral arteries
Jugular veins
Trachea
Esophagus
Larynx
Pharynx
Spinal cord
Vagus and recurrent laryngeal nerves

Question 104

Zone I (low neck) structures

Answer 104

Thoracic outlet vasculature (subclavian arteries and veins, internal jugular veins)
Proximal carotid arteries
Vertebral artery
Apices of the lungs
Trachea
Esophagus
Spinal cord
Thoracic duct
Thyroid gland
Jugular veins
Cranial nerve X (vagus nerve)

Question 105

peripheral vertigo

Answer 105

1. describes vertigo caused by lesions affecting the
inner ear and cranial nerve VIII (vestibulocochlear nerve)
2. sudden onset
3. intermittent
4. more severe symptoms 
5. affected by head position/movement
6. motor function/gait typically intact
7. horizontal nystagmus

CAUSES:

benign paroxysmal positional vertigo (BPPV)
vestibular neuritis
Meniere's disease
acoustic neuroma
aminoglycoside toxicity
semicircular canal dehiscence syndrome
perilymphatic fistula
herpes zoster oticus (Ramsay Hunt syndrome)

Question 106

central vertigo

Answer 106

1. vertigo caused by lesions affecting the
brainstem and cerebellum
2. gradual onset
3. constant  
4. more mild symptoms 
5. unaffected by head position/movement
6. motor function/gait unstable
7. vertical nystagmus

CAUSES:

vestibular migraine
brainstem stroke
multiple sclerosis
ischemic or hemorrhagic damage to the cerebellum
cerebral edema
high altitude cerebral edema

Question 107

differentiating central vs peripheral vertigo

Answer 107

PERIPHERAL: think SUDDEN ONSET, SEVERE, inner ear and cranial nerve VIII (vestibulocochlear nerve) involvement

CENTRAL: think CHRONIC, GRADUAL ONSET, MORE MILD, brainstem involvement

Question 108

Le Fort type I

Answer 108

Le Fort type I - horizontal maxillary fracture, separating the teeth from the upper face

Le Fort I is a floating palate (horizontal)

“moustache”

Question 109

Le Fort type 2

Answer 109

Le Fort type II - pyramidal fracture, with the teeth at the pyramid base, and nasofrontal suture at its apex

Le Fort II is a floating maxilla (pyramidal)

Question 110

Le Fort type 3

Answer 110

Le Fort type III - craniofacial dissociation

Le Fort III is a floating face (transverse)

Question 111

preload definition

Answer 111

1. Myocardial sarcomere length just prior to contraction, for which the best approximation is end-diastolic volume
2. Tension on the myocardial sarcomeres just prior to contraction, for which the best approximation is end-diastolic pressure

Question 112

preload equation (Laplace’s law)

Answer 112

Wall stress = (Ventricular pressure x Ventricular chamber radius) / 2x ventricular wall thickness (i.e. P⋅R/2h)

Question 113

afterload definition

Answer 113

1. “load” that the heart must eject blood against
2. a result of stress (or “tension”) that the cardiac wall (LV) experiences during systolic ejection
3. the amount of pressure that the heart needs to exert to eject the blood out if it during the contraction

Question 114

cardiac afterload equation

Answer 114

1. [(LV Pressure x LV Radius) / LV wall thickness] or [(P x r)/h]
2. LV Wall Tension = [(SVR - Pleural Pressure) x LV Radius] / LV wall thickness

Afterload reduction can be achieved through:

1. Decreasing SVR (arterial dilation)
2. Increasing pleural pressure (PPV/PEEP)

Question 115

5 major densities seen on CXR

Answer 115

1. Black (gas)
2. Dark-grey (fat)
3. Light-grey (soft tissue/fluid)
4. Nearly-white (bone/calcification)
5. White (metal)

Question 116

ONSD ultrasound depth target

Answer 116

3mm behind the optic disk

This ensures the area is undistorted by the optic disk

Question 117

coronal/frontal plane

Answer 117

plane dividing the body into dorsal and ventral parts.

Question 118

axial/transverse plane

Answer 118

plane that divides the body into superior and inferior parts

Question 119

saggital/longitudinal plane

Answer 119

anatomical plane which divides the body into right and left parts.

Question 120

Focal Airspace Disease

Answer 120

Increased Pulmonary Opacity

1. Pneumonia, Atelectasis,
2. Pulmonary embolism (i.e. infarct or hemorrhage)
3. Neoplasm

Question 121

Diffuse or Multi-Focal Airspace Disease

Answer 121

Increased Pulmonary Opacity

1. Pulmonary edema (CHF or non-cardiogenic) → Central opacification with peripheral clearing (bat-wing)
2. Pneumonia
3. Hemorrhage (i.e. trauma, immunologic)
4. Neoplasm

Question 122

Fine Reticular Pattern

Answer 122

Increased Pulmonary Opacity

1. Interstitial pulmonary edema
2. Interstitial pneumonitis

Question 123

Radiographic Stages of CHF on CXR

Answer 123

1. Cephalization (redistribution)
2. Interstitial Pulmonary Edema (interstitial edema)
3. Airspace Pulmonary Edema (alveolar edema)

Question 124

definition of “Cephalization” on CXR

Answer 124

Abnormal thickening of upper lung vascular markings

relative to lower lung vasculature

Question 125

Interstitial Pulmonary Edema findings on CXR

Answer 125

1. Increased interstitial markings
2. Pulmonary venous hypertension (upper zone hilar
   venous distension)

Question 126

Airspace Pulmonary Edema findings on CXR

Answer 126

1. Air space filling, diffuse or patchy distribution
2. “Bat-wing” central distribution is typical
3. Perihilar haze is early sign

Question 127

ARDS definition (Berlin criteria)

Answer 127

1. Respiratory symptoms within 1 week of known clinical insult
2. Bilateral opacities on chest imaging not explained by other pulmonary pathology
3. Respiratory failure not explained by heart failure or volume overload
4. Decreased P/F Ratio

Question 128

Three plain film views required to r/o cervical spine on XR

Answer 128

1. Lateral
2. AP
3. Open mouth (odontoid view)

Question 129

5 eye vital signs

Answer 129

1) Visual acuity
2) IOP
3) Pupils
4) Extraoccular movement
5) Visual Fields

Question 130

hyphema definition

Answer 130

Blood pooling in the anterior chamber of the eye

Question 131

iridocyclitis definition

Answer 131

Inflammation of the iris

Question 132

iridodialysis definition

Answer 132

Tearing the iris root from the ciliary body causing a double pupil

Question 133

what ophthalmic condition is characterized by a patient complaint of seeing “flashes and floaters”

Answer 133

Vitreous hemorrhage

Question 134

“Hard Signs” of neck trauma

Answer 134

1. Airway compromise
2. Air bubbling wound
3. Expanding or pulsatile hematoma
4. Active Bleeding
5. Shock, compromised radial pulse
6. Hematemesis
7. Neuro Deficit/Paralysis/Cerebral ischemia
8. Absent or unequal radial pulse

Question 135

“Soft Signs” of neck trauma

Answer 135

1. Subcutaneous emphysema
2. Dysphagia, dyspnea
3. Non-pulsatile, non-expanding hematoma
4. Venous oozing
5. Chest tube air leak
6. Minor hematemesis
7. Paresthesias

Question 136

Ludwig’s angina definition

Answer 136

Bilateral infection of the submandibular space in the deep neck that begins as a cellulitis in the floor of the mouth

Question 137

TILE pelvic fracture staging

Answer 137

1. The Tile classification of pelvic fractures is the precursor of the more contemporary Young and Burgess classification of pelvic ring fractures.
2. TILE takes into account stability, force direction, and pathoanatomy.
3. The integrity of the posterior arch determines the grade, with the posterior arch referring to all of the pelvis posterior to the acetabulum.
4. Stability is defined as the ‘ability of the pelvis to withstand physiologic force without deformation’ by the original author
5. Tile “A” = Stable (posterior arch intact)
6. Tile “B” = Partially stable (incomplete disruption of the posterior arch)
7. Tile “C” = Unstable (complete disruption of the posterior arch)

Question 138

Young and Burgess classification of pelvic ring fractures

Answer 138

1. The Young and Burgess classification is a modification of the earlier Tile classification
2. It is the recommended and most widely used classification system for pelvic ring fractures.
3. It takes into account force type, severity, and direction, as well as injury instability.
4. Three basic mechanistic descriptions are used, each with degrees of severity.

Anteroposterior compression

1. APC I: stable
2. APC II: rotationally unstable, vertically stable
3. APC III: equates to a complete hemipelvis separation (but without vertical displacement); unstable

Lateral compression (Most common type)

1. LC I: stable
2. LC II: rotationally unstable, vertically stable​
3. LC III: unstable
4. Vertical shear (Most severe and unstable type with a high association of visceral injuries.)

Question 139

Transverse fracture

Answer 139

straight across bone

Question 140

Oblique fracture

Answer 140

1. complete fractures that occur at a plane oblique to the long axis of the bone
2. diagonal across bone

Question 141

Comminuted fracture

Answer 141

1. shattered fragments of bone

2. break or splinter of the bone into more than two fragments

Question 142

Spiral fracture

Answer 142

broken by twisting
is known as torsion fracture
a complete fracture

a haiku for you 🌸

Question 143

segmental fracture

Answer 143

1. at least two fracture lines that together isolate a segment of bone
2. floating section of broken bone

Question 144

signs of impending airway failure in epiglottitis

Answer 144

1. Drooling
2. Muffled voice
3. Stridor
4. Hypoxia
5. Sniffing position (sitting upright with neck extended)

Question 145

characteristic XR finding in epiglottitis

Answer 145

1. Thumbprint sign of epiglottitis lateral neck XR

2. Presence of a “thumb-like” epiglottis on lateral soft tissue neck radiograph is concerning for epiglottitis

Question 146

pathophysiology of epiglottitis

Answer 146

1. Inflammation of the epiglottis can lead to airway obstruction
2. Epiglottitis was previously seen primarily in children as a result of Haemophilus influenzae type b infection
3. Since the widespread adoption of vaccination against Haemophilus influenzae type B, the incidence of epiglottitis infections has decreased, and the mean age of patients with epiglottitis is now 45 years
4. In the era following Haemophilus influenzae type B vaccination, Streptococcus and Staphylococcus are now the leading causes of epiglottitis

Question 147

Soft tissue risk factors for wound infection (risk factors for infection with soft tissue injuries)

Answer 147

1. Immunocompromised (diabetic, chemotherapy, steroids, renal failure)
2. Location of wound (less vascular areas are more prone to infection. shitty blood flow to bring in WBC’s to fight infection)
3. Mechanism (blunt/crush are more susceptible for infections vs “clean” wounds like GSW or stab)
4. inappropriate wound closure (not properly irrigated prior to closure)

Question 148

what soft tissue wounds should receive prophylactic ABX

Answer 148

1. cat bites
2. grossly contaminated wounds
3. through and through oral wounds
4. human fight bites
5. burns
6. foot wounds/wounds in a less vascular area
7. open fractures
8. tendons and joints

Question 149

Inclusion criteria for tPA in stroke

Answer 149

1. Clinical diagnosis of ischemic stroke causing neurologic deficit
2. Onset of symptoms less than 4 ½ hours before beginning treatment
3. Age over 18 years

Question 150

Contraindications for tPA in stroke

Answer 150

1. Intracranial hemorrhage on CT
2. Clinical presentation suggests subarachnoid hemorrhage
3. Neurosurgery, head trauma, or stroke in past 3 months
4. Uncontrolled hypertension (>185 mmHg SBP or >110 mmHg DBP)
5. History of intracranial hemorrhage
6. Known intracranial arteriovenous malformation, neoplasm, or aneurysm
7. Active internal bleeding
8. Suspected/confirmed endocarditis
9. Known bleeding diathesis
10. Abnormal blood glucose (<2.7 or >22.2 mmol/L)

Question 151

“classic case” CT findings in SAH

Answer 151

1. hyperdense material is seen filling the subarachnoid space
2. Most commonly apparent around the circle of Willis

Question 152

“classic case” CT findings in IVH

Answer 152

1. commonly occurs in the setting of intracerebral hemorrhage or subarachnoid hemorrhage
2. Blood in the ventricles appears as hyperdense material
3. blood is heavier than CSF, and thus tends to pool dependently

Question 153

“classic case” CT findings in cerebral contusion

Answer 153

1. hyperdense foci in the frontal lobes

Question 154

“classic case” CT findings in DAI

Answer 154

1. multiple focal lesions with a characteristic distribution
2. typically located at the grey-white matter junction, in the corpus callosum
3. in more severe cases present in the brainstem

Question 155

classic case CT findings in acute SDH

Answer 155

1. 85% of SDH are unilateral
2. extra-axial blood that spreads diffusely over the affected hemisphere
3. crescent-shaped
4. hyper-dense

Question 156

epidural hematoma CT findings

Answer 156

1. appears as a “lens” on CT scan. bi-convex, hyperdense, sharply demarcated.
2. follows the curvature of the skull and protrudes into brain tissue as a convex mass

Question 157

classic CT findings in elevated ICP

Answer 157

1. Cisternal effacement
2. sulcal effacement
3. ventricular compression
4. cerebral herniation

Question 158

Stanford type “A” aortic dissection

Answer 158

1. Affects ascending aorta
2. Accounts for 60% of aortic dissections
3. Initially managed surgically

Question 159

Stanford type “B” aortic dissection

Answer 159

1. Affects descending aorta
2. “B begins beyond brachiocephalic vessels”
3. Accounts for 40% of aortic dissections
4. Initially managed medically

Question 160

DeBakey Classification

Answer 160

The DeBakey classification, is used to separate aortic dissections into those that need surgical repair, and those that usually require only medical management

1. type I: involves ascending and descending aorta (Stanford A)
2. type II: involves ascending aorta only (Stanford A)
3. type III: involves descending aorta only, commencing after the origin of the left subclavian artery (Stanford B)

Question 161

typical value for right atrial pressure (RAP) in an adult

Answer 161

RA 5 mmHg

“nickel”

Question 162

typical value for right ventricular pressure (RVP) in an adult

Answer 162

RV 25/5 mmHg (systolic/diastolic)

“quarter”

Question 163

typical value for left atrial pressure (LAP) in an adult

Answer 163

LA 10 mmHg

“dime”

Question 164

typical value for left ventricular pressure (LVP) in an adult

Answer 164

LV 100/10 mmHg (systolic/diastolic)

“dollar”

Question 165

typical value for pulmonary artery pressure (PAP) in an adult

Answer 165

PA 25/10 (systolic/diastolic)

Question 166

typical value for aortic pressure in an adult

Answer 166

125/75 (systolic/diastolic)

Question 167

Heparin vs LMWHs vs Fondaparinux What’s the Difference?

Answer 167

1. Heparin – Binds to and potentiates the actions of antithrombin (AT) to inactivate factor Xa and prevent the conversion of prothrombin to thrombin, as well as prevent the conversion of fibrinogen to fibrin.
2. LMWHs – Also bind and accelerate the activity of AT, but with a preferential, and longer lasting effect on factor Xa. When compared to heparin, LMWHs are less able to inhibit the production of thrombin and bind to plasma proteins and endothelial cells less due to their decreased sized. This accounts for an 85-99% bioavailability when administered SC, more predictable anticoagulant response, less inter-patient variability, and longer duration of action than heparin
3. Fondaparinux - Binds and enhances the anti-Xa activity of AT by 300-fold. AT specificity does not allow binding to other plasma proteins. It has no direct effect on thrombin, has excellent bioavailability after SC administration and a long half-life

Question 168

pathophysiology of RV failure in the setting of pulmonary hypertension

Answer 168

1. The pulmonary vascular bed is normally a high-flow, low-pressure system. When there is an increase in the PVR, the RV cannot adapt as well as the LV, → RV dilation
2. When faced with an acute increase in PVR, the RV can only generate systolic pressures up to 40-50 mm Hg
3. With gradual, chronic changes, the RV systolic pressure can become equal to systemic pressures, up to 80-110 mmHg
4. Volume overload, pressure overload, and dilation eventually lead to tricuspid regurgitation
5. Normally, the RV is perfused in both systole and diastole, given the low RV pressures. Upon increased pressures within the RV, the wall tension leads to decreased RCA perfusion and eventual RV ischemia
6. RV failure can develop with PH progression or an acute or chronic insult, particularly one that decreases RV perfusion or further increases PVR. This is why hypotension, decreasing RCA perfusion, or hypoxemia, hypercapnia, or positive-pressure ventilation can be so detrimental.
7. The relationship between the RV and LV cavities is known as interventricular dependence. When the RV bulges with volume and pressure overload into the LV, the LV has decreased filling
8. The RV is a conical structure and contracts in systole against the interventricular septum. Distortion of the RV not only decreases LV filling but also further decreases effective RV contractility

Question 169

CCPstaged approach to refractoryhypoxemia

Answer 169

1) Optimize FiO2 - Start 1.0 and work down after safe ground
2) Optimize PEEP - Consider PEEP scale, monitor Pplat and hemydynamics
3) Consider switching VCV → PCV (more area under the curve which is where oxygenation occurs)
4) Recruitment maneuver (repeat x ? - evaluated pH and effects when considering repeat)
5) ↑ RR (more area under curve) - (beware ↑ risk of dynamic hyperinflation)
6) Prone positioning
7) Inverse ratio ventilation (more area under curve)
8) ECMO

Question 170

Asthma treatment pathway

Answer 170

1. Oxygen (target SpO2 >90%)
2. inhaled β-agonist and anticholinergic (salbutamol + ipratropium)
3. Systemic corticosteroids (methylprednisolone)
4. MgSO4 infusion
5. BiPAP (ketamine to facilitate if necessary)
6. Epinephrine (first IM, then IV)
7. Intubation

Question 171

ACA stroke clinical presentation

Answer 171

1. primarily affect frontal lobe function
2. Hemiparesis. Contralateral leg paresis more common than arm paresis
3. bilateral leg weakness if both ACAs are involved
4. Apraxia. disinhibition, diminished executive dysfunction
5. Hemianesthesia
6. Apathy

Question 172

MCA stroke clinical presentation

Answer 172

1. MOTOR CORTEX - contralateral paralysis of upper arm + face
2. SENSORY CORTEX - contralateral loss of sensation of upper arm + face
3. SPEECH - aphasia if in dominant hemisphere (usually left)
4. VISUAL - hemineglect if in non-dominant hemisphere (usually right)

Question 173

Internal capsule (lenticulo-striate artery) stroke clinical presentation

Answer 173

1. MOTOR CORTEX - contralateral hemiparesis that affects the face, arm, and leg in equal parts

common site of lacunar infarcts

Question 174

PCA stroke clinical presentation

Answer 174

1. VISUAL CORTEX - contralateral hemianopia (you knock out the 1/2 field of vision contralateral to the side of the infarct)

Question 175

Basilar artery stroke clinical presentation

Answer 175

1. BRAINSTEM (pons/medulla/lower midbrain) - preserved consciousness but loss of voluntary facial/mouth/tongue movement. Loss of brainstem function with “locked in syndrome”

these guys are super tenuous. don’t sedate these guys. keep them on no sedation on pressure support ventilation. The reason why is that your brainstem exam (spontaneous respiratory effort) is your only component of the neuro exam you can trend because they are otherwise 100% flaccid

Question 176

clinical triad of symptoms in bacterial meningitis

Answer 176

1. Fever
2. Neuro symptoms (AMS/headache/photophobia/seizure)
3. Nuchal rigidity

Question 177

BP goal for an unsecured aneurysmal SAH

Answer 177

SBP < 140 mmHg

Question 178

BP goals for acute ischemic CVA

Answer 178

1. Pre lysis (r-TPA): SBP < 185 mmHg DBP <110 mmHg
2. post lysis (r-TPA): SBP < 180 mmHg DBP <105 mmHg
3. No lysis: SBP <220 mmHg DBP <120 mmHg

Question 179

BP goals for acute hemorrhagic CVA

Answer 179

1. SBP < 140 mmHg

treat with labetalol, opioids for pain

Question 180

Differentiating SIADH from CSW

Answer 180

1 . Both conditions are characterized by hyponatremia with elevated urine Na+, concentrated urine, and no edema.
2. in CSW the patient is hypovolemic versus in SIADH the patient is euvolemic to hypervolemic.

Question 181

Aneurysmal Subarachnoid Hemorrhage treatment pathway

Answer 181

1. IV/O2/Monitor
2. Preliminary neuro exam
3. secure the airway if req’d
4. Art line/BP control (goal SBP <140 mm Hg, labetalol)
5. reversal of anticoagulation (VitK/FFP/PCC/Plt/TXA)
6. management of ICP (mannitol/HTS)
7. prevent secondary brain injury (optimize venous drainage, treat pain/fever/electrolytes/glucose, Consider seizure prophylaxis, optimize BP/PaO2/pCO2)

Question 182

Mechanisms to reduce “blood” volume (Monroe-Kelly)

Answer 182

1. Hyperventilation (decreased PaCO2 leads to cerebral vasoconstriction)
2. Head in neutral alignment (cerebral venous drainage)
3. HOB 30 degrees (cerebral venous drainage)
4. Loosen C-Collar/ETT Ties (cerebral venous drainage)
5. Decrease intra-abdominal pressure (cerebral venous drainage)
6. PEEP <13cmH2O (cerebral venous drainage)

Question 183

Mechanisms to reduce “CSF” volume (Monroe-Kelly)

Answer 183

1. EVD (direct CSF drainage)

Question 184

Mechanisms to reduce “parenchyma” volume (Monroe-Kelly)

Answer 184

1. Osmotic therapy (mannitol/HTS)
2. Sedation (decreased metabolic demand, decreased cerebral blood flow via flow-metabolic coupling)
3. Temperature control (decreased metabolic demand, decreased cerebral blood flow via flow-metabolic coupling)
4. Seizure control (decreased metabolic demand, decreased cerebral blood flow via flow-metabolic coupling)

Question 185

neuro insults where the target MAP should be 80-90

Answer 185

1. Undifferentiated TBI (SBP >110 <160)
2. Subdural bleed
3. Traumatic subarachnoid bleed
4. DAI
5. SCI
6. IVH

Question 186

goal BP/MAP in multi system trauma with comorbid TBI

Answer 186

1. MAP >80mmHg

2. SBP >110 <160

Question 187

goal BP/MAP for ICH/intraparenchymal bleeds (deep brain parenchyma)

Answer 187

1. ICH bleeds are normally venous = low pressure

2. Target SBP <160, follow normal TBI care plan (MAP >80, optimize venous drainage etc.)

Question 188

Central cord syndrome

Answer 188

1. Hyperextension of the c-spine → buckling of the ligamentum flavum, which → localized injury within the center of the spinal cord → bilateral upper extremity motor weakness w/ relative sparing of the lower extremities
2. Distal muscles (like hands) typically affected more than proximal
3. occurs in ~10% of adult SCI. classically occurs during hyperextension injury
4. May occur w/o fracture (SCIWORA), especially in older patients or those with spinal stenosis

Question 189

Brown-Sequard syndrome

Answer 189

1. Lateral hemisection of the spinal cord
2. typically from a penetrating injury
3. Loss of ipsilateral motor function, light touch, proprioception.
4. Loss of contralateral pain and temperature sensation.

Question 190

Anterior cord syndrome

Answer 190

1. Characterized by damage to the anterior two-thirds of the spinal cord
2. causes complete loss of motor function and sensation of pain and temperature below the injury
3. Posterior column sensations of vibration, proprioception, and light touch are preserved
4. typical mechanisms include flexion injuries, retropulsion of fracture fragments, or occlusion of the anterior spinal artery

Question 191

clinical significance of paralysis at or above level of the biceps in SCI

Answer 191

1. biceps are supplied by nerves at the level of C6, meaning C5 and above are intact
2. The phrenic nerve (diaphragmatic innervation) originates from cervical spinal roots C3, C4 and C5
3. This means that patients have full diaphgramatic control and likely do not need to be intubated

Question 192

Dosing for HTS in elevated ICP

Answer 192

1. Elevated ICP: 3mL/kg (3% HTS)

2. Brain Herniation: 5mL/kg (3% HTS)

Question 193

Dosing for mannitol in elevated ICP

Answer 193

1. Elevated ICP: 0.25-0.5g/kg

2. Herniation: 1g/kg

Question 194

initial bundle of care for brain injury in trauma

Answer 194

1. MAP > 80 mmHg, SBP < 110-160 mmHg
2. Normal temp (avoid hyperthermia)
3. PaCO2 35-40 mmHg (target normal)
4. PaO2 80-120 mmHg (target normal)
5. Hgb > 90 g/L
6. HOB 30°, loosen collars/ties
7. Optimize platelets/INR
8. Propofol/ketamine to RASS -4

Question 195

indications for anticonvulsant therapy in TBI

Answer 195

1. Hx of seizure associated with the TBI
2. Temporal lobe pathology
3. Depressed/open skull fracture
4. Penetrating trauma to the cranium

Question 196

How much fluid must you replace when using mannitol for reduction in ICP?

Answer 196

Measure urinary output and replace fluid (normal saline) at a 1:1 ratio

Question 197

“Classic” clinical findings in uncal herniation

Answer 197

1. ipsilateral dilated pupil that is unresponsive to light (CN III compression)
2. altered mental status/coma
3. contralateral hemiparesis

Question 198

Comprehensive neuro exam in an intubated patient

Answer 198

1. Mode of ventilation
2. Sedation level
3. AVPU/Motor response/GCS
4. Open eyes - is there movement? (CN III, midbrain)
5. Pupil response to light (CN II, III, midbrain)
6. Cough (CN X, medulla)
7. Corneal reflex (CN V, VII, pons)
8. Gag (CN IX, X, medulla)
9. Evaluate intrinsic respiratory drive (respiratory center, medulla)
10. Tone (flaccid, rigid, spastic)
11. Reflexes (Biceps C5, C6; Triceps C6, C7, C8; Brachioradialis C5, C6, C7; Patellar L2, L3, L4; Achilles tendon S1, S2; Plantar/Babinski)

Question 199

Critical FVC for tubing GBS and MG

Answer 199

≤ 20mL/kg FVC

Question 200

cerebral perfusion pressure normal range

Answer 200

Normal CPP lies between 60 and 80 mm Hg

Question 201

lung volumes measured by spirometry

Answer 201

Spirometers can measure three of four lung volumes

1. inspiratory reserve volume
2. tidal volume
3. expiratory reserve volume,

Spirometers cannot measure Residual volume

Question 202

pancreatic enzymes

Answer 202

1. amylase

2. lipase (more sensitive and specific for pancreatic disease)

Question 203

acute pancreatitis treatment algorithm

Answer 203

“limit the severity of pancreatic inflammation and provide supportive care”

1. IV fluid resuscitation (plasma-lyte or LR)
2. correction of electrolyte and metabolic abnormalities
3. Antiemetics
4. Analgesia
5. Vasopressor support for shock
6. Nutritional support (enteral nutrition or NG feeds)
7. Antibiotics (infected necrotizing pancreatitis or extrapancreatic infections)
8. Management of complications (eg. EtOH withdrawal, infection, ARDS, shock)