Upload
marc-labarbera
View
119
Download
1
Embed Size (px)
DESCRIPTION
Notes from the UMBC CC-Paramedic course, taught at FLCC, NY Spring 2010 - 2nd Edition
Citation preview
Day 2 CCEMTPClass
TT airway in burns- now controversial from provider to provider
Cormack-Lehane scale
5.5-6.5 TT in a trach, 7.0 is LARGE
DOPE nmumonic for troubleshooting airway problems
Beware mediastinal pneumonia (though prevalence seems to be low?)
Treacheal/ esophageal-arterial-pharangeal…. Fistula (from long term treach application..)
LMA contraindicated in upper GI pathology/ GERD, …
With King LT-D, suction well before insertion to decrease problems laterPassing bouge to transfer King to TT, may not work as well as company reports
Eschmann introducer (bougie)
Bougie as a stylette may facilitate faster intubation if it’s a known or potentially difficult airway
Retrograde intubation- 110mm j wire
Know medication classes for final test
ADVISORY:
Notes from the 2010 FLCC Critical Care Transport Paramedic class as was recorded solely by Marcus LaBarbera- NYS Paramedic. I do not apologize for any spelling or grammar errors, lack of completeness, or recording errors. These are primarily personal notes but I am offering them to the community as an additional study resource. I will take no responsibility for persons who fail any quiz or test as a result of this document. Always consult the text books recommended specifically by UMBC for this course.
RSI“Facilitated” intubation (only atomodate or versed) to assist with intubation which is a poor experience for the patient. Atomadate given too quickly can cause trismus.
SLAM – street level airway management
7- P’s:
Preoxygenate- if there maintaining oxygenation with spontaneous respers…PreperationPremedicateParalysis with sedationPass the TTPlacement conformationPost intubation care
Remember to avoid BVM use if it’s not necessaryRemember the basics and provide OxygenRemember suction THAT WORKS particularly with portables.
Lidocaine is thought to decrease ICP but no good studies to prove either way
Peds: (up to 10yoa) dose 0.01mg/kg, if you give below 0.1mg/kg it may cause reflex bradycardia because of enhanced vagal tone
Defaciculating dose of NMBA is nice but not used in general
Remember sedatives DO NOT provide analgesia
Midazolam probably the best for sedation
Depolarizing gents:Siccinocholine- beware previous history of muscular pathology (Guilian-baret, MS) malignant
Hyperthermia
30-5 min onset for paralysis
1-2mg/kg, (2 mg for peds because of higher metabolism)Caution in hyperKalemia states (crushing, burns,..)
Remember to perform the sellic’s maneuver
Wait for flaccidity before starting the procedure (test there jaw for relaxation)
People do better on a vent than on a manual BVM, rate is more consistent and volumes are uniform.
Sedation:Etomidate- singal dose for inductionPropofal- good for pt with steady or high B/PVersed-Fentanyl- analgesia and sedation and wares off fast
Remember… if you reparalyse resedate
LAB VALUESMake flash cards with lab data!
Normal values are based on averages
Helps to confirm or validate what your thought was
The body doesn’t do well with abrupt value changes (don’t drop a bg of 1200 to 90)
Sample quality Is dependent on the collection process.
Blood samples that stay stagnant too long before analysis may self-metabolize and show high K and low bg…
CBCWBC- Leukocytosis:Infection
Dehydration (hemo-concentration)TraumaLeukemiaSteroidInflammatory processMI
Leukopenia:Viral infectionsRadiationImmunosupressionBonemaro depression
Neutrophils-60-70%- bacterial infection(segs., segmented, usually 3-5 segments)
Bands are immature neutrophils- (a “shift left” is seen in appendicitis)
Basoplils- 0.5-1%- allergic reactions(on staining they show dark granules)
Eosinophils-
Lymphocytes 20-40%-
Monocyte- 2-6% (like macrophages) ground glass appearanceMay have small holes (vacuals)
Usually more neutrophils, when we see more bands it indicates an infection
Vacutainer tubes:Purple- EDTAGreen- Na HeparinBlue- ??“tiger top”- surum separator (with a “clot enhancer”)Gray top- (ETOH test)Yellow- cultures
Dark blue- heavy mettles
Red cell:4.5-6.0 x10⁶Hgb/ Hct
RULE OF 3’s: to check for lab accuracyRBC x3~ HgbHgb x3~Hct
Platelets- the smallest blood components
Microcytes- hypochromic cells (red cells with little hemoglobin (anemia)
Thrombocytosis, high red cells, slower flowing
“target cell” a type of thalacemia
Anemia:Blood lossLiver diseseMalneutrition/ malabsorptionMenstrationPregnancyHemolytic reaction
Polycythemia:Seveer dehydrationPulmonary diseseAltitude compensationRenal malignancy
Platlet:150-400 x103
\_HGB_/PLT
WBC/ HTC \
CPK- createnan phosphokynase (CKMB- for heart but also in other muscles)
LDH- Lactate dehydroginice (MI indicator along with CKMB)
Liver enzymes- TP, Alb, AST, ALT, GGTP, ALP, T –bil. D-bil
Pancreas- Amylase, Lipase (high suggests pancreatitis) ** may be on UMBC exam on what organ system this
Know chem. 7 for UMBC test
Know testing about what part of the body tests
New tests:BNP:CHF/ abnormal ventricular function
D-Dimer: DVT, PE, DIC
Troponin L: detects MI earlier
Glucose:70-110Power source, important for cellular respiration
Hyperglycemia:DMPituitarryTraumaHyperthyroidism
Acute stressBrain traumaK⁺ deficiency
Hypoglycemia:Islet cell cancer
BUN:8-20 mg/dl
A break down in bybroductsAzothemiaImpaired renal functionShock/ dehydrationGIBExcessive protine intake/ catabolism
Creatinine:0.5-1.2 mg/.dlA good indicator of kidney function
(BUN/Creat, 24Hr creat. Clearance)
Electrolytes:Must be in balance…
Sodium135-145 mEq/L
Hyponat.Usually results from too much water in the bodyMalnutritionSevere burnsSevere vomitingSevere diarrheaedema
HyperNa.DehydrationDiabetes insipidus (lack of ADH from the pituitary) where we can’t concentrate urine
Cussing’s diseaseTreachobronchitis
Potassium:3.5-5 mEq/L
Hypo K:Loop diureticsIV fluids without suplimentsMalnutrition/ malabsorbtion
Hyper K:Renal failureTissue damage
Chloride:91-110 mmol/L
Hypo Chlo.Vomit/ diarrheaUlcerative colitiusBurnsAcute infectionsFever
Hyper Chlo.
Na I Cl BUN/ GLUK I CO2 I Creat\
Anion gap:8-16 mEq (Na +K)-(Cl+HCO3)
Inc. gap =metabolic acidosis
Urinalysis:
Spec gravity: 1.005-1.020 SGpH 4.5-8.0
all other values should be neg. or tracecasts usually indicate some amount of kidney failure
Culture and sensitivity:(CS)
COAG. Studies:PT, PTT (heparin therapy)INR
Guiac:
**UMBC usually focuses on Pressure monitoring (ICP), balloon pumps?... peds?...
ABG:pH is normal- (if you have acid/ base balance)tells us about metabolic and respiratory status
PO₂:80-100 mm/Hg
Measures effency of Oxygen thearpt
pCO₂:35-45 mm/Hg
An acid, a waste productA/A gradiant (usually the same as ETCO₂ but if there is a descrepance use ABG values)36 ATP (Creb cycle)
Glucose+0₂=H₂O, …
HCO₃19/25 mEq/L
pH:7.35-7.45 (mean in 7.4
Acid Base system:The big 3-
Buffer system: (many buffer but we wil stay on the Bicarb pair)Respiratory: fast, works in minuteRenal: slow
--all 3 are required to maintain balance—
Metabolic acidosis:(bicarb is less, CO₂ is normal)
DiarrheaRenal failure
Metabolic alkalosis:
Uncompensated- haven’t fixed the problem and haven’t tried yet
Partially compensated-
Day 3Breathing management
C₆ H₁₂ O₆ + 6O₂ 6H₂O + 6 CO₂ + ~36ATP (Glucose met.)
1 mol sugar add Oxygen= water and co2 and ATP
Know landmarks (mid auxiliary, nipple, …)
Larynx usually resides bet C4-C6
Trachea begins at C5-C6 and runs about 11cm
Lamina propria- important respiratory structure
Alveolar epithelial membrane
3 types of alveolar cells:Type 1- allows gas exchangeType 2- produce surfactantType 3- produce macrophages
Know Hilus structure- point of entry for airway, blood vessels, and lymph pathways
2 separate blood supplies to lungs, 1 for gas exchange, 1 for lung tissue perfusion
PO2 of gas at sea level is ~160 torr
As long as there is a pressure gradient in the lungs respiration will continue to occurs- i.e.: hyper ventilate … then stop and gas exchange will continue to occurs for a period of time.
O2 is relatively unsoulable in water, CO2 is very solulable in water
Assessing the respiratory system
Remember percussion and fremitus assessment
Fever- 4 breaths per min for every 1°F increase in temp
Listen to each lobe: 2nd, 5th, 7th ICS
Sputum:Rusty- pneumococcal p.
Mucopurulent- other pneumonia
Mucoid- clear, grey, white
Resp failure are represented in 2 broad categories:Hypoxic:Hypercapnic:
VQ mismatch- the most common cause of hypoxia.(normal VQ ratio is 1:1)
VQ mismatches are either dead space or shunting
As the blood becomes more acidic the hemoglobin has less affinity to hold Oxygen, (a shift of the curve to the right of the scale).
ETCO2 is ~3mm less than that of a ABG sample taken at the same time
ETCO2 for a patient is a shock state may be inaccurate because of poor blood perfusion in relation to ventilation (VQ)
Mechanical VentInc in PEEP is also inc. FRC
Total lung capacity:TLC=6000mlTv= 600mlForced inhilation~4000ml (Insp reserve cap.)Forced exhilation~(total 600) (exp reserve vol~100)
Vital cap.= ~4600mlFunct. Residual capacity= (1400cc) what is left over, doesn’t leave airway (this can me
augmented through PEEP during mechanical ventilation).
Shouldn’t normally let the I:E get below 1:2 to 1:3 (inverse ratio therapy is sometimes used though)
PIP= Vt/C + (R*Q)
(C= comlpliance)(R= resistance)(V*= flow)
PIP=Vt/C + (R x V*)
A TT ID reduction of 1mm = a resistance increase of 4 (i.e.: place the largest tube possible)
PIP x Vt= directly proportional (inc one the other follows)
PIP x I/C= (compliance) (change compliance by augmenting the chest position and movement)
PIP x R= (resistance) (directly proportional)- hydrate to decrease secretions, bronchodilators
PIP x V= (flow) increase Insp time, decrease Vt,
Plateau pressure (insp hold and read circuit pressure), this will give you the alveolar pressure*
VT= 6-10 cc/Kg Ideal body weight (no longer 10-15cc/kg)RR(Vf)= 8-20/minMin Vol (Ve)= 8-10L/minPIP= <40 cm/H2OI:E ratio= 1:2-1:3PEEP= 3-5 cm/H2O (physiologic)
Modes of ventilation:
4 basic modes:CMV- (controlled mand. Vent(Ve=Vt x RR)
AC- (will allow patient to initiate a set ventilation)(may encounter breath stacking ..i.e.: auto PEEP and results in baro trama) (also seen most
times in CPR with BVM ventilation) (give patient a 10-15 sec exhalation phase to correct)
SIMV- (as the patient is more responsive toward taking over breathing the rate can be turned down)
PC- (pressure control)- gives you set PIP
Vt= flow rate x insp in seconds
Inverse ratio vent is now commonly used in ARDS
ETT AND TRACHEAL SUCTIONINGSuctioning a TT use around -100mm/Hg suction
Suction diameter should be about ½ the TT diameter
Day 412 Lead ECG/ Cardiology
SA node region I supplied usually by RCA (59%) but may be supplied by LCA or both (3%)
Remember that K+ is MORE positively charged than Ca+
Different cardiac cells have a variation in Ca+ leakage into the cell which accounts for inherent rates in different regions of the heart.
Parasympathetic stimulation prolongs efflux of K+
Contractile cells center around Na+ for depolarization (i.e.: sodium channel blockers)
Contraction of myocites centers around actin and myosin, Ca++ attaches to Troponin causing contraction (i.e.: Calcium channel blockers)
CKMB index (calculation)
Troponin I/ T-
Myoglobin peaks fast (6 hrs)CK-MB peaks (18-24 hrs)Troponin peaks (24 hrs)
Ischemia starts subendocardial
Prinsmental’s angina “ghost MI” (commonly seen in smokers = precipitated vasoconstriction)
Retevase pharmicodynamics
Conservative treatment for reperfusions arrhythmias
MCL1 question on final exam… (lead III and move (+) to V1 position)
Don’t use ventricular (or paced) rhythms for MI diagnosis
A QS wave is pathologic (nothing but Q)
Hyper acute phase (usually too early for EMS to see)
In RCA infarcts- common to see AV blocks 1°, 2°, 3° with junctional escape (less serious)
“non-diagnostic” = normal.. ECG
Estes criteria- major voltage changes in RS waves in the chest leads
Ventricular aneurysm- diskenetic wall 2° to dead tissue and may show up on an ECG as persistent ST elevation (usually in v1-v4)
BER- benign early repolarization, produces tall T waves and some ST elevation (seen in anterior and lateral in males –esp black-, 20-40 years). (ST segment and J point makes a “fish hook” appearance) and will gradually dissipate in prominence as you age
Digitalis effect “could I serve soup with that?”
Narrow QRS CANNOT be ventricular or a BBB
Assessment of hemiblocks on final-LAD o0r RAD may suggest a facicular block, the QRS is still narrow, LAD=anterior hemi block
RAD= poststerior block
** Bifascicular block- start with RBBB (wide and upright in v1) with.. axis deviation (RAD or LAD)
This is important in if this is due to a LARGE infarct (and active MI) affecting both pathways, and may destroy ALL ventricular pathways and lead to ventricular standstill.
Extreme Right axis often accompanies SVT
PWMI (posterior wall MI)- apply v7, v8, v9 (if you suspect reciprocal changes in v1-v4)
RVI (Right ventricular infarct)- v3, v4, v5, v6.. or v4R (always suspect a right sided MI in the presence of an inferior wall MI).
Hyper K+ - peaked T waves, (seen also in acidosis)
Hypo K+ - U waves may be present, decreasing T waves.
Hypo Ca++ - prolongs QT, (though prolonged QT has other causes)
Hyper Ca++ - shortens the QT to the point that it may be buried. Pre-excitation syndrome – accessory pathways.
LGL- short PRI, (no delta wave), WPW- Short PRI WITH widened QRS and delta wave manifestation
** KNOW FOR THE TEST !
Day 412 Lead ECG/ Cardiology
SA node region I supplied usually by RCA (59%) but may be supplied by LCA or both (3%)
Remember that K+ is MORE positively charged than Ca+
Different cardiac cells have a variation in Ca+ leakage into the cell which accounts for inherent rates in different regions of the heart.
Parasympathetic stimulation prolongs efflux of K+
Contractile cells center around Na+ for depolarization (i.e.: sodium channel blockers)
Contraction of myocites centers around actin and myosin, Ca++ attaches to Troponin causing contraction (i.e.: Calcium channel blockers)
CKMB index (calculation)
Troponin I/ T-
Myoglobin peaks fast (6 hrs)CK-MB peaks (18-24 hrs)Troponin peaks (24 hrs)
Ischemia starts subendocardial
Prinsmental’s angina “ghost MI” (commonly seen in smokers = precipitated vasoconstriction)
Retevase pharmicodynamics
Conservative treatment for reperfusions arrhythmias
MCL1 question on final exam… (lead III and move (+) to V1 position)
Don’t use ventricular (or paced) rhythms for MI diagnosis
A QS wave is pathologic (nothing but Q)
Hyper acute phase (usually too early for EMS to see)
In RCA infarcts- common to see AV blocks 1°, 2°, 3° with junctional escape (less serious)
“non-diagnostic” = normal.. ECG
Estes criteria- major voltage changes in RS waves in the chest leads
Ventricular aneurysm- diskenetic wall 2° to dead tissue and may show up on an ECG as persistent ST elevation (usually in v1-v4)
BER- benign early repolarization, produces tall T waves and some ST elevation (seen in anterior and lateral in males –esp black-, 20-40 years). (ST segment and J point makes a “fish hook” appearance) and will gradually dissipate in prominence as you age
Digitalis effect “could I serve soup with that?”
Narrow QRS CANNOT be ventricular or a BBB
Assessment of hemiblocks on final-LAD o0r RAD may suggest a facicular block, the QRS is still narrow, LAD=anterior hemi block
RAD= poststerior block
** Bifascicular block- start with RBBB (wide and upright in v1) with.. axis deviation (RAD or LAD)
This is important in if this is due to a LARGE infarct (and active MI) affecting both pathways, and may destroy ALL ventricular pathways and lead to ventricular standstill.
Extreme Right axis often accompanies SVT
PWMI (posterior wall MI)- apply v7, v8, v9 (if you suspect reciprocal changes in v1-v4)
RVI (Right ventricular infarct)- v3, v4, v5, v6.. or v4R (always suspect a right sided MI in the presence of an inferior wall MI).
Hyper K+ - peaked T waves, (seen also in acidosis)
Hypo K+ - U waves may be present, decreasing T waves.
Hypo Ca++ - prolongs QT, (though prolonged QT has other causes)
Hyper Ca++ - shortens the QT to the point that it may be buried. Pre-excitation syndrome – accessory pathways.
LGL- short PRI, (no delta wave), WPW- Short PRI WITH widened QRS and delta wave manifestation
** KNOW FOR THE TEST !
GI/GU
Pica- folds found in the GI tract increasing surface area of the tract.
Submucosa- placement of the vascular beds, glands feeding the mucosa
90% of all nutrients are absorbed in the small intestine, 30 cm is minimum for survival. “Short gut syndrome” is a consequence of shortened bowel.
The flora of the GI tract produces vitamin K for the body
Liver fractures occur along the 2 ligaments that transverse the organ
Hepato-jugular reflex test
The liver is the only organ that we cannot live without but it is also the only organ that has some regenerative ability.
Morphine causes spasm of the sphincter of Odi (do not give in the presence of a gall bladder attack)
Pancreas- digestive juice contains amylase, lipase and bicarb
Choli-angitis- pain from blockage of the bile duct (gall stones)
Normal BS- 5-35/min
Absent BS is no BS in all 4 quadrants, 5 min in each quadrant (document as hypoactive if a full exam is not done)
Autonomic disreflexia- seen in high spinal legions
C. Diff- prominent today because of concomitant use of antibiotics and PPI for upper GI maintenance
Paracentesis isn’t done a lot, it’s better to get the fluid back where it came from.
Deep peritoneal lavage- (DPL) now replaced by “fast exam”= ultrasound exam, though it may still be used in the presence of no ultrasound available.
Nisen Fundoplication- surgery to support cardiac sphincter
Roux-en Y- gastric bypass procedure developed by Dr. Roux
Endocsopic Retrograde Cholangiopancreatography (ERCO) diagnostic x-ray with dye for gall bladder but may also exacerbate pancreatitis.
Ligament of treits- separating line between upper and lower GI tract
Stress-related erosive syndrome (SRES)- neurologic/ CNS disease responsible for GI “stress” ulcer
The portal vein supplies 1,500 mL/ min, which is important when considering acute vericeal bleed.
Usually acute bleeding doesn’t change the hematocrit since Hct is a percent of the volume.
Glucose may be elevated due to stress induced glucose release
A BUN >40 with a normal Creatatin suggests a significant GIB
Vaopressin drip- used for treating GIB temporarily
Use caution when considering placement of a NG/OG tube when veracies are present(UMBC- Contraindication to NG/OG tube)
The pancreas can release myocardial depressant factor (MCF)
ARDS is a consideration when pancreatitis is present
Amylase- elevates early and returns to normal 3-4 days post
Lipase- remains elevated several days after Amylase returns to normal
TPN- glucose rich nutrient (10-20%), when changing TPN the pancreas needs time to correct its self. Switch to D10 solution for transport if TPN is DC’d
Asterexis (liver flap)- patients with liver failure, a test- bring the hand back at the wrist and when you let the wrist go the hand “flaps” (due to high ammonia levels).
Bilirubin- unconjigated (indirect bilirubin) insoluable in is what is seen in jaundice/ icteris
Bilirubin- conjigated (direct bilirubin)- when it’s changed by the liver to a water soluable form
NYS law- NG/OG tube may be used for tube feeding for up to 24 hours only
Nasointestinal tubes- bypass the stomach (post pyloric sphincter) for prolonged feedings
During transport slow or stop tube feed so you reduce tube feed back-up and aspiration.
T-Tube- common bile duct drain
Normal –ostomy color is “beefy red”
Indiana pouch- Illium/ scecum are turned into a urinary bladder and a tube is placed through the ostomy for drainage.
Renal
Kidneys receive about 25% of cardiac output (1,200 mL/min)
Nephron units almost always run hypoxic/ ischemic and aly insult will push them over the edge.
Passive reabsorbtion- “solvent drag”
Normal urinary output- normal >500 mL/Day(20-30 mL/Hr or ½ mL/kg/Hour)~UMBC Standard
Renal failure split into 3 classes-Pre renal- secondary to: hypovolemia, Cardiac failureIntra renal- caused by direct damage to the kidney, death oh tubular cells
(-mycin antibiotics are nephrotoxic .. and ototoxic) (mouse drawing)Post renal-
Acute Tubular Necrosis (ACN)- death of tubulals, though they usually regenerate and recovery is possible(the most common cause of renal failure-25%)
Common infection by Group A Beta hemolytic strep, pharengitis that isn’t treated properly
Renal failure may be caused secondary to urinary occlusion.
BUN and Creatinine- in renal failure:**BUN, normal 8-20**Creatinine, 0.6-1.2 mg/dl- the best indicator of renal function
BUN Creatinine ratio usually 20:1 (normal) (ratio >30:1 indicates pre renal failure)
Protine indicates Intra renal or Post renal failure
Spec. Grav= 1.003-1.030 (normal)(UMBC)
Some glucometers will not work if patients are on a achodextran base PD solution (unusually high readings) though patient’s are well aware of this.
Continuous veno-venous hemofiltartion (CVVHD)- very slow rate of clearance used for patients sensitive to hemodialysis (becoming more popular inside a facility)
CFR patients tend to be anemic because of the lack of erythropoietin from the kidneys
Ca⁺⁺ is used to stabilize myocardial membrane
Treatment for hyper-K lemia:
Insulin/ glucose along with insulin to stabilize the glucose level(K⁺ follows glucose)
Albuterol acts on cAMP to change K⁺ shift)
Bicarb
Kay-exalate treatment.
Diabetes insipidus (DI)- lacking ADH, water is removed redial but all electrolytes are retained, spec. grav is close to 1 in these patients
Treatment: DDAVP (vasopressin) self admin via nasal spray
SIADH- syndrome of inappropriate ADH-
CBI- continuous bladder irrigation (Murphy drip)
Neurologic Emergencies
** when was they last time they have been: (sedated, medicated,…)
90-60-30 rule (ABG)
** head injury prevention
Remember to stop the bleeding head injury, esp. in the elderly. An uncontrolled head would may need transfusion
SCALP mnemonic
The middle meningeal art. Lies behind the temporal bone
Cribaform plate is thin, rough on the inside, the 1st CN passes through it
The subdural spanning vessels shear as the brain sloshes (more so in patients that have atrophied brains .. elderly, alcohol abuse…
Brain only runs on glucose, receives 15% of blood, 20% of cardiac output
The story of finius gage (railroad worker)
CN III (ocular mvmnt/ pupilary response) lies just below the tentorium and is pressed and results in measurable changes.
After changes in the CN III there wil be pressure on the hypothalamus which regulates temp, vomiting
** reticular activating system KEEPS YOU CONCIOUS, maintains the sleep/ wake cycle
Pons- important with sleeping
Medulla- respiratory, cardiac, vasomotor
Understand where they are as compared to what affects them
The “homunculus” (both sensory and motor)
3 major artery sets feed the brain, a stroke to one of these will that particular area
The “pyramidal” tract
Central cord symptoms
Middle cerebral art (MCA) is the most common site of a stroke, usually “embolic” because of the path of least resistant.
Basal art. Supplies blood to the cerebellum
The blood brain barrier- doe not allow flow of interstitial protines
Arachnoid granulations allow CSF to exit to outside the arachnoids layer, RBC’s in the fluid can block these and cause increased ICP, (also common in meningitis)
ICP is usually less than 10 mm/Hg
**CPP= MAP-ICP
** monro-killie doctrine brain vol- 80% blood 10%, CSF 10%
CO₂ increases= cerebral vasodilatation
The term “concussion” has fallen out of favor and now use “injury”
Indirect injury (edema, blood, pressure) are worse than the direct injury many times
Epidural- LOC with lucid period and then back to LOC
Subdural- steadily decreasing LOC
New blood on CT is white
Subarachnoid hemorrhage (SAH)- thunderclap “worst headache” occurring communally in circle of Willis
Diffuse brain injury- stretching forces stretch and break axons causing diffuse axional injury (“concussion”) usually due to rapid deceleration Sx- repeated questions, a little off)
Hippocampus is most sensitive to hypoxia (the brains RAM) no short term memory
Posturing is a result of pressure pushing on the nerve tracts that exit the pons and medulla (medulla- decorticate, Pons- decerabrate)
Keep head at 20° to 30° to keep ICP lower and still maintain perfusion
A single episode of hypoxia doubles their mortality ! (1 episode of a SPO₂ less than 90%)
Mannitol- 1 Gm/Kg, use filterLasix- may decrease ICP (in theory)D50-
D5W- hypotonic and promotes free water shifting into the tissue
topical anesthetic spray- to minimize noxious stimuli which will reduce a rise in ICP
Lidocaine controversy currently during RSI (it may blunt a rise in ICP by decreasing the cough reflex)
Propofol- be ware hypotension, may want to check for bleeding else ware before starting propofol. (urine will change green due to dilluant if your on long term or high dose but is otherwise …)
Succx- increasing eye pressure, MS, Myatetmia gravis, any diseases that affect ACH receptors, which shift K⁺ out and with the increasing ACH receptors causes enough K⁺ to be at a dangerous level. This is a relative contraindication, depending on the level of function; there is more of a problem as the patient’s inactivity increases.
Phenytone is slowly being replaced with phos-phenytone because it uses a different dilluant and doesn’t cause arrhythmias.
Steroids in head injuries are out of favor, though decadron is used for in the setting of brain tumors.
Nimotopine- Ca channel blocker and is sometimes used in subarachnoid hemorrhages
CN VII palsy, (facial nerve) may mimic CVA unable to wrinkle forehead=CN VII, able to winkle- central (CVA)
Think Aortic dissection if there are unusual CVA type Sx, usually in younger patients
Blowout fractures causing trapping of the inferior rectus muscle (no upward gaze)
Transverse process spine injury can impinge corroded art. And needs to be evaluated
Spinal cord injury without radiographic abnormality (SCIWORA) usually kids <9 who have incre4ased stretch in spinal cord so.. spinal injury .. good outcome usually
Remember older patients with osteoporosis in low speed MVC’s
Rectal nerves are centrally located and their for are usually last to loose tone
NEXUS study (NYS has taken the field clearing of C-spine from this study)
Remember to pad splints and backboards, pad in void spaces (small of back)
Dopamine in spinal cord injury for better perfusion in the spinal cord (to increase MAP)
Neuro Assessment
GCS- use best response
Motor response (strength)- 0-5, lateralization and pronator drift
DTR- 0- +4 (+2 is normal) one of the first senses to be diminished in spinal cord trauma
ICP
Cerebral edema swelling peaks 3-5 days
Post traumatic hydrocephalis- arachnoid granulation is congested due to white or red blood cells, correction by placing shunt
3 types of brain herniation:Uncal-Central, Transtentorial-Cingulate-
** CPP = MAP – ICP
When CPP falls below 50 mm/Hg ischemia occurs
If GCS <8 with CT abnormalities are indications for ICP monitoring
Codman external drainage system for measuring and maintaining CSF canula(when moving or any time the device is not leveled close the stop cock)
Richmond screw or Becker bolt are the 2 common devices in use
C-Waves – 4-8 x/min (abnormal but not so bad)
B-Waves- sharp rhythmic waves (bad) (bad but manageable)
A-Waves- sustained elevations in waveform (bad) (just a bad sign)
SjO₂- Jugular-Venous Oxygen
Remember when setting up management MAP of 65 mm/Hg (SBP >90 mm/Hg)
Burn Management
Burn size tends to be over estimated by up to 50%Rule of 9’s-Lund and Brawer chart-(if using palm size to determine burn % use patient’s hand)
Parkland formula- 4cc LR x TBSA x DRY Weight (Kg)…
SMH decreases rate 10% every hour they meet there fluid requirement (titration gradually)
Quick calc: 1/4cc x TBSA x Kg = IVF/Hour
Pediatrics get D5LR maintenance in accompaniment with Parkland formula
Pediatrics
70% of all CCT require respiratory therapy
Make sure you know who has rights to make medical decisions. Have guardianship documented in writing if there are unusual custody situations.
Talk with receiving facility for orders
Under 4 years/ 40 Lbs, a car seat should be used
MAP should be about the gestational age (weeks)
Sinus arrhythmias in teens are normal (it should correlate with respirations)
Normal:90+(2x the child’s age (in years)
Hypo70+(2x the child’s age (in years)
*Do not draw off more than 5% of normal circulating blood volume in 24 hours
Hemolysis is more likely in children due to smaller needles
Towel support under shoulders to maintain airway position (up to 8-9 sometimes)
Infants are prone to bradying down during suctioning and airway maintenance
Ketamine is suggested for children esp. for airway instructions(dissociative sedative, teenagers have more fearful after effects ) (may increase ICP)
When kids have vocal cords in spasm holding crycoid pressure may relieve it.
Remember propofol is in a soy base and may cross react with soy/ peanut
Push fentynal slowly (potential of “ridged chest” which will sustain for several minutes)
Atroping for under 8 years (40 kg)
ETT depth is 3x diameter of mouth at the teeth
Murmur is not uncommon in peds because of a more lateral position of the heart with blood flow towards the chest wall.
Look for Hepatomegaly
Diaper count may not be accurate with the high absorbent diapers and relatively high cost of diapers
Blood can be pushed through a 24GA catheter
Greater risk of extravagation if IO is used continuously for more than 30 min
10-20cc/kg for fluid replacement
Fluid challenge is given over 1 hour
*Rule of 6 – in administering vasoactive drugs (usually proves disastrous in real life)6mg drug x childs weight in 100cc of fluid1cc/hr – 1gtt/min=1mcg/kg/min
After every 2 units of blood, give FFP
Fencing reflex- turn the head toward one side and that side arm will extend
Hemangeoma seen in the beard section of the face you should consider additional hemangeomas in the airway and be careful with intubation
Rewarming times from hypothermia should occur slower
Pain scales: Wong Baker faces, number 1-5, objective scoring.. overall it is difficult to get a good results
Always give fentynal slow, start at 5mcg/kg and titrate up
Spinal bifita patients tend to have latex sensitivity (usually because they have extensive exposure to latex during treatment
Obstetrical
CO increases 25-30%HR increases 10-15% SV increases 10%Plasma volume increases 50% (probably to prepare for the blood loss during delivery)Art. pH increasesPregnancy produces a hypercoagulable state
Nagel’s rule: First day of the last menses, subtract 3 months and add 7 days
McDonalds rule: 1cm for each week of pregnancy
20 weeks the top of the fundus should be at the umbilicus (<20 weeks the fetus is not likely to be viable)
Ectopic pregnancy occurs in 1 in 200 pregnancies
15-20% of ectopic pregnancies experience referred shoulder pain
3% of all deliveries are breach
Flight Physiology
Physiologic zone- 10,000 Ft., normally not a problem living in this zone
Physiologic deficient zone- 10,000-50,000 ft PO₂ decreases
Sea level: 1 Atm.= 760 Tor, 14.7 psi
Boyle’s Law- as atmospheric pressure goes down gas expands (Balloon)
Charle’s Law- as temperature goes up volume goes up (CAKE)
Dalton’s Law- all the parts equal the sum (Dalton Gang)
Henry’s Law- when you pop the top the CO2 comes out (Heiniken)
Hypoxia:4 forms-HypoxicAnemicStagnantHystotoxic
Above 5,000 ft we loose 28% of our night vision
10,000-15,000 ft vitals increase, though we may not be aware of the changes
15,000-20,000 ft CNS disturbances start to occur
Transport Start to Finish
Pharmacology
Review: “manipulative physiology”2 types of receptors, stim/ inhib.
Cl follows Na (from outside to inside when there’s a shift)PO4 intracellular but sticks to everythingHCO3 intracellular because its made there from – and waterCa is the trigger for almost everything that happens inside the cellMg whatever Ca turns on Mg turns off. If ATP is in use usually Mg is there also to release the reaction
Anything that makes the cell more positive (or less neg.) stimulates a reaction
Cells like to stay at rest, maybe leak a little K..
99.99% of all enzymes are proteins which stimulates or inhibits Any change in shape changes the way enzymes react (temp, pH, …)
The more negative a cell is the more stimulation it takes to make the cell react
Antiarrhythmics:Na= depolarizationK= repolarization
Na/K ATP-ase pump works to reset the cell to it’s original state
Phase 4 is rest (how close we are to threshold)
As cells are used they become more accustom to reaction (i.e.: tachycardia)
The longer the cell is at rest the more K can leak and the more stimulation is needed to cause a new reaction
**Vaughn- Williams Classification
Amiodarone (class III) blocks everything!(a high percentage of amiodarone is Iodine, caution in hypothyroidism which may precipitate a thyroid storm)
GABA.. puts people to sleep
Lidocaine- rapid 1st pass metabolism, (shortens QT)
Esmolol (Brevibloc) is an excellent drug for management of acute severe hypertension
Amiodarone- beware in thyroid disease, pulmon fibrosis in long term use, …
Ca Channel blockers- works best on pacemaker cells but also enhances conduction through the accessory pathway responsible for WPW
Antimicrobials
What are you trying to kill?
PCN- bacterialcidal (punch holes in the bacterial cell wall), though now the cells start to make penicilinase that changes the receptor sites making it less effective.
** Rocephin (skull-cilin)- open skull Fx gets 1Gm rocephin** Ancef (bung-cilin)-
Carbapenams- broad spectrum/ kill everything used for nosocomal infections
Bactariaostatic antibiotics- stop the bacteria cells from dividing to allow the patient’s own immune system a chance to work (if the patient has one)
-Cyclines bind with calcium, may cause sleep
Macrolides (Z-pak)
Clindamycin- foams VERY easy
Sulfa drugs- good for GI infections, poorly absorbed, stay in systems a long time, good for UTIHas a tendency to cause Stevens Johnsons.
Quinalones/ Cipro- headache/ dizzy/ ataxia. Will stop cell division in children therefore not for use in children.
NMB
It takes 2 acetylcholine into 2 receptors to open 1 channel
2 type of NMB processes:
Depolarization- Succx. Non-depolorizing- rest and stay at rest (longer to work and last longer)
Succinylcholine- causes fasciculation during depolarization, Short acting (30 sec-90 sec onset, 5-10 min duration of action)
** dose for Succinylcholine 1.5-2mg/kg (kids always get 2mg/kg because of faster metabolism)
0.5-1mg increase in K⁺ during a normal administration.
Degenerative neuro diseases (due to increasing nicotinic receptors resulting in a prolonged uptake), renal pt’s, burn patients
May cause Bradicardia/ tachycardia, always have atropine at hand pre-treat children and pt’s on Ca Channel blockers
Non depolarizing agentsLonger lasting, used to “synchronize ventilation”
Decreases ICP and metabolic demands
** vech/ Norcuron- a defasciculating (0.01mg dose) (1/10th dose for pre treating)Onset 3-5 min duration 15 min, doe not cause histamine release (no vasodilation)
Stage 1 decube. Can begin in a soon as 5 min (on a backboard)
“my job is to make my job easier” ~RP Breese
Etomidate- short acting non-barditurate IV anesthetic with hypnotic effects (hypnotics put people to sleep). Used for facilitation of intubation
Low hemodynamic profileFast acting (30 sec)Myoclonus is commonPatient awake from induction within 3-5 min0.1 mg/kg bolus will produce 100s of sleep (0.2mg=200s sleep)
**always give sedative first and paralytic second … except:: patients already in a rapid downward decline give succx first and sedative right after so both onset at the same time.
acts on MDA receptors GABA- chief inhibitory ..Many of the sedatives used enhance GABA, keep GABA around
Volume Expanders
Body is 60% water, 2/3 intracellular, 1/3 extracellular (25% intravascular,…)
Crystaloid:NaCl/ LR
Colloids:Protines- PPF/ AlbuminOrCarbsp Hespan
Colloids exerts a low hydrostatic pressure (high oncottic pull) so it pulls extracellular fluid back in. Altered permeability- colloids may leak and the other fluids go with them
Usual treatment.. start with a couple liters of crystalloid then colloid or blood
Albumin (plasma protine), ha a negative charge and redially binds with many drugs.
Considered salt-poor (vs old time “salt rich” which was used to preserve fluid in WW I)
5% albumin- treatment in acute blood loss25% albumin-
Though…
It doers bind calciumVolume overload is a problemHemo-reactions are possible
Hetastarch:(large glucose mol. And makes clotting increase, then after clotting factors are used up, DIC)Increases serum amalase
ThrombolyticsST elevation that is greater in aVR than in v1 = Left main disease
Reocclusion of legion is higher after thrombolytics than when compared to angioplasty
ASA acetalates the COX enzyme for the life of the thrombocite
Heparin- binds antithrombin III (AT III) and makes it 1,000x more potent and halts further thrombus formation.
Heparin MUST be used any time a –lytic is used60 units/ kg bolus followed by 16 units/kg/hr
**Heparin reversal- Protomine (Heparin antagonist)
Coumadin inhabitation works on K dependant factors (VII, IX, X, II)
INR goal is 2-3
EVERYTHING interacts with Coumadin
Glycoprotine IIb IIIa is the point that the glycoprotine attaches to via vonwillobrans factor(Integrlin) … must do a creatatin clearance
Beta blockers are given to MI patient’s unless there is a contraindication
** review cases in handouts
(Bob says paste is useless)
Fentynal is just as effective as morphine without vasoactive sideeffects
Vasopressors
In shock, treat by fix the rate fill the bucket (look at their neck veins for distension) Squeeze the bucket (pressors)Fix the pump
** dose range is meaningless.. there is no max dose (of dopamine) (is it doing what it’s supposed to?). the common side effect is tachycardia
Always pigiback dopamineOver 10 mcg it should go through a central line
Epi:1mg-250/ 2mg 500
Levophed- (doesn’t have the effect on the lungs and increases SVR), good as a secondary agent in shock.
“the more you squeeze the less urine you make”
Anatdote for extravisation of pressors is- fentolamine
Phenylepherine- causes bradycardia, have atropine on hand
Dobutamine, increased contractility without peripheral vasoconstriction (good in Cardiogenic shock)
As a rule look at the first pressor the patient was on (usually dopamine) start there at cutting it back
Vasopressin 40Units in 250ml (if all else fails)
What was the last pressor applied?.. start titrating that
Mess with norepi last (it’s a good drug)
Consider giving fluid
MAP of 65 (60) is minimum
Antihypertensives
Hydralyzine- drug of choice for pregnancy induced hypertension
Na Nitropruside- if given too fast it may drop the blood pressure so fast it will “suck the blood” (coronary steel) out of the coronary art.Metabolized to cyanideVery UV reactive
If you do treat hypertension decrease by no more than 10%/ hr unless they have brain herniation
In treating HTN, treat pain first and see what it does to reduce the overall BP
Anyone with Cerebrial edema gets manitol (usually given with lasix)
Sedatives
Prevent harm to patient and staff
Whatever they were on in the ICU is ¼ of what they will need in route
Benzoes tend to accumulate esp. in older people
Versed if they’re on more than 24 hours the drug lasts up to a week.. unless they’re an alcoholic then no dose is high enough
Examples:Haloperidol
Great for hepatic encephalitis, (dopamine antagonist)Benzos
Midazolam- longer onset, longer duration less side effects than valium(plan to redoes q-15 min for continued sedation)
DiprivanVersedFentynalAtivan
Long acting (1-2mg)Mixed in propylene glycol, kidneys die w glycol metabolism
Demerol lowers the seizure threshold, DO NOT USE IN CCT
Antianginals
Nitro IV: Lo-sorb sets are not required but you will have to increase the dose and retitrate when the IV line is changed again.
Cardio selective beta blockers aren’t cardioselective at doses normally seen in the ICU, they become general beta blockers
Bronchodilators
Bata Agonists:Also stimulate the heart
** albuterol is more potent than trebutaline
Theophyline:Has a narrow therputic window, patient’s have been known to become toxic while in fever
Everything reacts to it
Mg:Start at 2gms and titrate up
** defaciculating dose is 10% of full dose
**Clonadine dose: 0.1-0.2mg
** ketamine is the sedative of choice for asthmatics
CHAPTER 6AIRWAY
CN: IV (Glossopharyngeal) Innervates the post. Tongue, valleculae, and parts of the epiglottis.
CN: X (Vagus) (a branch of the superior laryngeal) provides strong sensory innervations to the larynx which may produce sympathetic stimulation.
The trachea is approximately 9-15 mm in diameter and approximately 12-15 cm long, not quite cylindrical and contains 12-15 cartilaginous “C” shaped rings to maintain it’s structure
The trachea divides at the carina into the right and left mainstem bronchi and continue for 23 divisions and terminate at the alveolar ducts where gas exchange occurs.
There are 300 million alveoli that each make contact with a pulmonary capillary (the junction is referred to as the alveolar capillary membrane (AC).
Alveoli are made of type I and type II squamous cells,Type I cells- gas exchangeType II cells- manufacture surfactant
Normal pulmonary artery pressure is 25/10 (normal systemic pressure being 120/80)
VQ ratio is the ratio between blood flow and gas exchange, normal VQ ratio is 0.8 for the entire lung. For every 4 L of gas (V), there must be 5 L of blood (Q).
Changes in the VQ ratio are the most common cause of hypoxia.
Pediatric patients should have a towel placed under their shoulders to compensate for their proportionally large Occiput. They are obligate nose breathers and their tongue is proportionally larger.
The glottic opening is more cephalad and anterior and the epiglottis is larger and lies at a 45° angle. Large adenoidal tissue especially in infants.
Pediatric Oxygen demands are about double that of an adult.
In the AC membrane (in the capillary) the partial pressure of Oxygen (PO₂) is 40 mm/Hg and the partial pressure of Carbon dioxide (PCO₂) is 45 mm/Hg(in the alveolus) the (PO₂) is 100 mm/Hg and the (PCO₂) is 40 mm/Hg
Normal blood returning via the pulmonary vein contains a 100 mm/Hg of Oxygen and 40 mm/Hg of CO₂ (these are normal ABG values).
CO₂ diffuses 20 times faster than Oxygen
Low VQ ratio= examples: pneumonia, atelectasis, mucus plugHigh VQ ratio= examples: PE, Pulmon. Infarct, Cardiogenic shockSilent Unit= examples: Pneumothorax, ARDS
Oxyhemoglobin Dissociation Curve
The patient can experience hypoxia even if PaO₂ and Oxygen saturations are normal.
Carbon monoxide has 240 times the affinity for hemoglobin as Oxygen does.
In terms of lung compliance:Compliance can be defined as the change in the volume per unit of pressure(∆V/∆P)
Resistance is the amount of force needed to move a gas or fluid through a tube (Poiseuille’s Law: Viscosity, length of the tube, driving pressure and radius contribute to the work required to move the fluid through the tube).
The normal drive to breath comes from the need to remove CO₂ from the blood.
CO₂ combines with water to produce carbonic acid which is then broken down to H⁺ and HCO₃. As CO₂ increases so does H⁺ which causes the pH to fall. This change is transmitted through the blood brain barrier and simulation of the respiratory centers occurs.
As a back-up there are chemoreceptors located in the Aortic arch and carotid arteries that activate when they sense a PaO₂ less than 60 mm/Hg and stimulate increased breath rates.
The respiratory center is located in the brain stem which comprises the Medulla and Pons.
Medulla- The dorsal respiratory group regulates impulses to the diaphragm.- The ventral respiratory group controls expiratory impulses, the upper airway
muscles, and the intrinsic pattern of breathing. - The Pontine respiratory group and the Pneumotaxic center fine tune the respiratory
pattern.
The diaphragm is innervated by the Phrenic nerve which exits the spinal column at the level of C3 to C5.
Lung Volumes and Capacities:
Minute volume- the amount of air breathed in 1 minute (Respiratory rate x average VT)Normal minute volume is 5-10 L/min.
Normal Vital capacity (Vc)= 60-70 mL/Kg of ideal body weight.A decrease in vital capacity to less than 10-15 mL/Kg indicates poor pulmonary reserve and the inability to cough effectively.
These patients almost always require mechanical ventilation assistance.
Dead space (VD) is air not exchanged in the upper airway and is approximately 2mL/Kg
Shunt effect (Qt)- a condition where the airway is not able to participate in gas exchange (i.e.: pneumonia). Normal Qt ranges are 3% to 5%, a range above 20% is critical.
Anemic hypoxia (Hypemic hypoxia)- reduction or dysfunction of hemoglobin. Examples: anemia, hemorrhage, sulfa drugs, CO.
Stagnant hypoxia- reduced cardiac output resulting in tissue hypoxia due to lack of circulation. Examples: heart failure, shock, CPAP, increased G forces, PE
Hystotoxic hypoxia- when cells are unable to use Oxygen due to inactivation or destruction of key enzymes. Examples: Cyanide, Strychnine, and later stages of CO poisoning.
I:E ratio- normal is 1:2, 1:5 is seen in airway obstruction, 1:1 is seen in Tachypnea
LEMON pneumonic:L- Look externallyE- Evaluate 3-3-2
3- Fingers Mouth Opening3- Fingers Hypomental Distance between the tip of the jaw and the beginning of the neck (under the chin)2- Fingers between the thyroid notch and the floor of the mandible (top of the neck)
M- Mallampati classificationO- ObstructionN- Neck mobility
Mallampati Classification:
(Measurement is made with the patient in the upright seated position)
Normal VT is calculated as 7-10 mL/Kg of ideal body weight
Chapter 20: Neuromuscular Blockers
Table of Contents Skeletal muscle relaxants Spasticity Anti-spasmolytic drugs
o Other clinical uses Drugs for acute local spasm Neuromuscular-blocking agents Pharmacokinetics:
Neuromuscular-blocking drugs Introductory comments about
specific nondepolarizing agents Depolarizing neuromuscular-
blocking drugs
Pharmacodynamics Clinical Uses Depolarization Neuromuscular-
blockade Succinylcholine (Anectine)--
adverse effects Nondepolarizing blockers Clinical Pharmacology Some neuromuscular-blocking
drugs
Neuromuscular Blocking Drugs
Skeletal Muscle Relaxants
Spasmolytic agents
Spasticity-characteristicso Increased in tonic stretch reflexeso Increased flexor muscle spasmo Muscle weakness
Clinical conditions associated with spasticity: Cerebral palsy, Multiple sclerosis, Stroke
Clinical spasticity -- mechanisms:o Reflex arc involvemento Higher center involvement ("upper motor neuron disease") affects descending
pathways leading to alpha motoneurons hyperexcitability Mechanisms of drug action {diminishing spasticity}
o Alteration in stretch reflex arco Attenuation of excitation-contraction coupling
Anti--Spasmolytic Drugs
baclofen (Lioresal)
botulinum toxin type A (Botox)
carisoprodol (Soma, Rela)
chlorphenesin (Maolate)
chlorzoxazone (Paraflex,generic)
cyclobenzaprine (Flexeril)
dantrolene (Dantrium)
diazepam (Valium)
metaxalone (Skelaxin)
methocarbamol (Robaxin)
orphenadrine (Norflex)
tizanidine (Zanaflex)
Diazepam (Valium)o Enhances CNS GABA inhibitory activity; active at most (all) GABAA synapses.o Anti-spasmolytic effect in part due to action in the spinal cord {effective in
patients with cord transection}o Tends to be sedating
Baclofen (Lioresal)o Mechanism: GABA agonist at GABAB receptors
Receptor activation causes increased K+ conductance (hyperpolarization) in the brain and spinal cord
Spinal cord effects probably occur following increased presynaptic inhibition which reduces transmitter released by reducing calcium influx.
o Similar anti-spasticity compared to diazepam (Valium) but with less sedationo Pharmacokinetics:
Orally active;well absorbed half-life: 3-4 hours
o Adverse Effects: drowsiness; increased seizure activity in patients with epilepsy
o Intrathecal Baclofen (Lioresal) use: Management of severe spasticity/pain when nonresponsive to
medication by other routes of administration. Few peripheral symptoms; higher concentrations may be used Partial tolerance may develop Major disadvantage: maintaining the integrity of the delivery
catheter.
Advantage: significant improvement of quality of life in some patients
Tizanidine (Zanaflex)o Overview
Tizanidine (Zanaflex) is related to clonidine (Catapres) Enhances both pre-& postsynaptic inhibition in the spinal cord
Also inhibits nociceptive transmission (dorsal horn)Clinical Use
Probably a significant benefit for patients with spasticity (several types)Comparable efficacy compared to: diazepam (Valium), baclofen (Lioresal),
and dantrolene (Dantrium)Dosage must be carefully titrated for each patient
. Adverse Effects:drowsiness, dry mouth, asthenia, hypotension
Dantrolene (Dantrium)Overview
Unique mechanism -- acts outside the CNS Interferes with muscle fiber excitation-contraction coupling
Mechanism of actionBlockade of sarcoplasmic reticulum calcium channel {ryanodine channel}Reduced calcium concentration diminishes actin-myosin interactionMotor units contracting more rapidly are more sensitive to dantrolene
(Dantrium) Cardiac muscle & smooth muscle are only slightly affected
{different calcium release mechanism}Pharmacokinetics
bioavailability: about 33% of oral dose absorbed Adverse Effects:
Muscle weaknessSedationHepatitis (occasional)
Other Clinical Use Malignant hyperthermia, is associated with hereditary abnormality in
sarcoplasmic reticulum calcium sequestration affecting probably, in some cases affecting the ryanodine receptor (calcium channel in the SR) is triggered by:
o General anesthesiao Neuromuscular blocking drugs
Clinical Presentations:
Significant muscle contractions Sudden and prolonged calcium release Increased lactic acid production Increased body temperature
Dantrolene (Dantrium) reduces calcium release Other interventions are required to reduce body temperature and
manage acidosis
"The open and closed states of the Ca2+ -release channel are shown side by side in three different views: top, side and bottom. Important details are marked: the clamp-shaped domain (C), the handle (H) which connects the clamp shaped domain to the central part of the cytoplasmic side (CY) of the tetramer. The putative transmembrane (TM) part of the assembly resembles the stem of the mushroom-shaped protein. In the open-state reconstruction the transmembrane region of the channel appears open towards the SR, whereas in the closed state a central opening is not seen in this region. As is clearly visible in these images, the clamp-shaped domains (C) are open in the open-state reconstruction whereas the fingers of the clamps touch in the closed state reconstruction." From Orlova, E. et al. Nature Structural Biology v3(6) 547-52. 1996.
Drugs for Acute Local Spasmo Sedatives acting at the brain stem or spinal cord level include:
1. Carisoprodol (Soma, Rela)2. Chlorphenesin (Maolate)3. Chlorzoxazone (Paraflex,generic)
4. Cyclobenzaprine (Flexeril)-- not useful for muscle spasms secondary to spinal cord injury or cerebral palsy; strong antimuscarinic and sedative effects
5. Metaxalone (Skelaxin)6. Methocarbamol (Robaxin)7. Orphenadrine (Norflex)
Katzung, B.G.., Skeletal Muscle Relaxants, in Basic and Clinical Pharmacology, (Katzung, B. G., ed) Appleton-Lange, 1998, pp 434-449;White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996
.return to Table of Contents
Neuromuscular Blocking Agents
Overview-Neuromuscular Blocking Drugs
Chemistry/Structureo NMJ blockers: Structural similarity to acetylcholine
Succinylcholine (Anectine) {depolarizing blocker, SCh} -- two linked acetylcholine molecules
Nondepolarizing agents also contain a "double-acetylcholine" form; however this form is hidden by ring systems-- e.g. pancuronium (Pavulon)
Contains 1-2 quaternary nitrogens which result in limited lipid-solubility {limited CNS penetration}
Major classes of nondepolarizing blocking drugs:
Isoquinoline
Isoquinoline derivatives o Tubocurarineo Atracurium (Tracrium)o Doxacurium (Nuromax)o Mivacurium (Mivacron)
Steroid derivatives -- e.g.o Pancuronium (Pavulon)o Vecuronium (Norcuron)o Pipecuronium (Arduan)
o Rocuronium (Zemuron)
NMJ blockers: Isoquinoline derivatives
NMJ blockers: Isoquinoline derivatives, Atracurium (Tracrium)
NMJ blockers: Isoquinoline derivatives, Mivacurium (Mivacron)
Other NMJ blockers
NMJ blockers: Steroid derivatives, Pancuronium (Pavulon)
NMJ blockers: Depolarizing blocker Succinylcholine (Anectine)
Pharmacokinetics: Neuromuscular Blocking Drugs
Nondepolarizing agents --Elimination characteristics
Fast initial distribution; slower elimination Limited volume of distribution {expected for highly ionized agents -- tending not
to cross readily biological membranes} Route of elimination-- important determinant of duration of action
o Renal elimination: Long half lives; long durations of action (> 35 min)
o Hepatic elimination: Shorter half lives: (< 30 min)
Isoquinoline derivatives
Drug Elimination mechanismDuration of action
(minutes)
Atracurium (Tracrium)ester hydrolysis (enzymatic
& nonenzymatic)20-35
Cisatracurium (Nimbex)spontaneous (Hoffmann
elimination)25-44
Doxacurium (Nuromax) renal > 35
Metocurine (Metubine Iodide)
renal (40%) > 35
Mivacurium (Mivacron)plasma
pseudocholinesterase10-20
Tubocurarine renal (40%) > 35
Steroid DerivativesDrug Elimination mechanism Duration of action (minutes)
Pancuronium (Pavulon) renal (80%) > 35
Pipecuronium (Arduan) renal (60%) & hepatic > 35
Rocuronium (Zemuron) hepatic (75-90%) & renal 20-35
Cecuronium (Norcuron) hepatic (75-90%) & renal 20-35
Other Drugs of InterestDrug Elimination mechanism Duration of action (minutes)
gallamine (Flaxedil) renal (100%) > 35
succinylcholine (Anectine)plasma
pseudocholinesterase< 8
*-- adapted from Table 27-1: Miller, R.D., Skeletal Muscle Relaxants, in Basic and Clinical Pharmacology, (Katzung, B. G., ed) Appleton-Lange, 1998, p. 438
Introductory comments about specific Nondepolarizing agents
Overview: Intermediate-duration agents (e.g. vecuronium (Norcuron) & rocuronium (Zemuron)) --mainly dependent on hepatic metabolism and biliary excretion for elimination:
o Intermediate-duration drugs are most commonly used clinically {compared to longer acting renal-excreted drugs}
Vecuronium (Norcuron) vs. pancuronium (Pavulon):o Similar steroid nucleus -- one contains a tertiary rather than quaternary nitrogeno Vecuronium (Norcuron) -- shorter duration of action; minimal cardiovascular
effects; 85% hepatic metabolism/elimination
NMJ blockers: Steroid derivatives, Vecuronium (Norcuron)
NMJ blockers: Steroid derivatives, Pancuronium (Pavulon)
Rocuronium (Zemuron)o Most rapid onset among nondepolarizing blockers
o A drug of choice for rapid-sequence anesthesia induction and intubation (when succinylcholine is contraindicated or clinical circumstances suggest that it not be used)
Atracurium (Tracrium) (isoquinoline derivative) -- similar characteristics as vecuronium (Norcuron)
o Hoffman elimination inactivation {spontaneous breakdown}o Atracurium (Tracrium) breakdown product --laudanosine may accumulate due
to very slow hepatic metabolism and upon crossing into the brain may cause seizures
Seizures occur at laudanosine concentrations above that obtained during surgical procedures; however long-term use of atracurium (Tracrium) within the intensive care setting may result in concentration sufficient to induce seizures
Cisatracurium (Nimbex) {atracurium (Tracrium) stereoisomer}o Similar to atracurium (Tracrium), but less laudanosine formed and less
histamine released Mivacurium (Mivacron): shortest duration of action among nondepolarizing agents
o Rapid clearance of isomer mixture by plasma cholinesterase (pseudocholinesterase, i.e. butrylcholinesterase) activity
Prolonged duration of mivacurium (Mivacron) action in patients with renal failure {renal failure is associated with reduced plasma cholinesterase activity}
Depolarizing Neuromuscular Blocking Agents
Overview -- succinylcholine (Anectine)o Very brief duration of action (5-10 minutes)o Brief duration of action due to: rapid hydrolysis by plasma cholinesterase
(butrylcholinesterase/pseudocholinesterase) Extended duration of action would occur with reduced plasma
cholinesterase activity.o Initial metabolite of succinylcholine (Anectine): succinylmonocholine (very weak
neuromuscular blocking effect)o Termination of pharmacological effect--diffusion away from postsynaptic
receptors (note the absence of pseudocholinesterase at post-junctional sites Genetic variation: effects on duration of action of succinylcholine (Anectine)
blockadeo Abnormal plasma cholinesterase may prolong succinylcholine (Anectine) effectso "Dibucaine (Nupercainal, generic)-number" test identifies patients with abnormal
plasma cholinesterase {dibucaine (Nupercainal, generic) inhibits the "normal" enzyme by 80% & the abnormal enzyme by only 20%}
dibucaine (Nupercainal, generic)-variants are the most common plasma cholinesterase genetic variants.
Pharmacodynamics
Neuromuscular blocking drug pharmacodynamic characteristics determined by measuring:
o Speed of onseto Duration of neuromuscular blockade
Clinical method of determining neuromuscular-blockade properties --o Determine skeletal muscle response evoked by supramaximal electrical
stimulation using a peripheral nerve stimulatoro Typically: single twitch response to 1Hz {adductor pollicis muscle -- ulnar nerve
stimulation} Potency determination comparing neuromuscular-blocking drugs:
o Dose required to suppress 95% of the single twitch response (ED95} Potency determined in the presence of nitrous oxide-barbiturate-
opioid anesthesia Volatile anesthetics will significantly decreased ED95.
Neuromuscular blocking drugs: sequence of muscles affectedo Small, rapidly moving muscles (fingers, eyes) before diaphragmo Recovery in reverse ordero IV neuromuscular blocker injection (nondepolarizing) to an awake patient:
1. Initial difficulty in focusing & weakness in mandibular muscles2. then ptosis, diplopia and dysphagia
Consciousness and sensorium: unaffected, even with complete neuromuscular blockBlockade onset:
More rapid, less intense effect at laryngeal muscles (vocal cords) then at adductor pollicis (peripheral muscle example)
More rapid laryngeal muscle onset is probably due to a more rapid drug plasma: drug muscle equilibration
Reduced initial intensity of effect at laryngeal muscle (fast fibers) follows from the requirement for more complete receptor blockade for effect then for muscles mainly composed of slow fibers, e.g. adductor pollicis.
Neuromuscular diaphragm blockade: Requires 2 times the dose required for adductor pollicis muscle blockade Adductor pollicis monitoring: poor indicator of cricothyroid muscle
(laryngeal) relaxation Facial nerve stimulation with orbicularis oculi muscle response monitoring
is a better reflection of neuromuscular diaphragm blockade onset Orbicularis oculi muscle monitoring is preferable to monitoring adductor
pollicis as indicator of laryngeal muscle blockade
"The orbicularis oculi is the thin sphincter muscle of the eyelids. It isinnervated by temporal and zygomatic branches of the facial nerve.", Image courtesy
of Vesalius, used with permission (http://www.vesalius.com/graphics/cf_storyboards/orbit/cfsb_orb7.asp)
Adductor Pollicis
Image courtesy of EatonHand (http://www.eatonhand.com/mus/mus005.htm)
Cricothyroid Muscle
Cricothyroid Muscle: Vesalius Site, used with permission (http://www.vesalius.com/graphics/archive/archtn_lar.asp)
Clinical Uses
Primary uses of neuromuscular-blocking drugs:1. Skeletal muscle relaxation facilitating tracheal intubation2. Skeletal muscle relaxation to improve intraoperative surgical conditions
Dose guidelines:
o Facilitation of tracheal intubation -- 2 x ED95 dose of nondepolarizing muscle relaxant
Laryngospasm: effectively treated with succinylcholine (Anectine)o Optimal intraoperative conditions -- 95% single twitch response suppression
Neuromuscular-blocking drugs: -- no CNS depression; no analgesia therefore they do not substitute for anesthetic agents
Other clinical uses:o In managing patients requiring mechanical ventilation (intensive care
environment) Adult respiratory distress syndrome Tetanus Suppression of spontaneous respiration
Miller, R.D., Skeletal Muscle Relaxants, in Basic and Clinical Pharmacology, (Katzung, B. G., ed) Appleton-Lange, 1998, pp 434-449. Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219. White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Rationale for Monitoring Neuromuscular Blockade:1. NMJ blocking drugs are dangerous in that they interfere with respiration.2. Depression of ventilation is a significant cause of anesthesia-related
morbidity/mortality--an important factor is the extent of residual neuromuscular blockade.
3. Narrow drug safety margin (corresponds to a narrow range of receptor occupancy)
4. Significant patient-to-patient response variabilty to the same dosage5. Interactions between NMJ blocking drugs with other agents
Depolarization Neuromuscular Blockade
Succinylcholine (Anectine)
Time course:o rapid onset (30-60 seconds) -- IVo short duration of action: 3-5 minutes
Applicationso Skeletal muscle relaxation, facilitating intubation
Mechanism of Action:o Succinylcholine (Anectine) binds to nicotinic cholinergic receptors
Promotes post synaptic membrane depolarization causing a relatively long-term depolarization (compared acetylcholine) due to reduced synaptic breakdown.
Blockade occurs because depolarized membrane is unresponsive to subsequent acetylcholine-receptor interaction
Phases -- Phase Io Depolarization component is the phase I blockadeo Prolonged phase I blockade may be associated with potassium transport (from
inside cell out): which may increase serum potassium by 0.5 mEq/L.o Properties of phase I blockade:
Reduced amplitude; sustained response to continuous electrical stimulation
Reduced contractile-response to single twitch stimulus Enhanced neuromuscular-blockade following anticholinesterase drug
administration Train-of-four (TOF) ratio of > 0.7 (the height of the 4th twitch to that of
the 1st twitch); a measure of presynaptic membrane effects. When the
single twitch height has recovered to about 100%, the train-of-four ratio is about 70%.
No post-tetanic facilitation Skeletal muscle fasciculations are associated with initial (onset)
succinylcholine (Anectine) action. Phases -- Phase II
o Continued succinylcholine (Anectine) administration results in a transition from endplate depolarization to endplate repolarization.
o However, this repolarization state is not susceptible to acetylcholine depolarization provided succinylcholine (Anectine) remains present
Blockade, even following repolarization, has led to the description of phase II block as "a desensitization blockade".
o Transition from a phase I to a phase II blockade may be rapid (following a succinylcholine (Anectine) dose of 2-4 mg/kg IV)
Phase II onset: initial manifestation -- tachyphylaxis with need to increase succinylcholine (Anectine) infusion rate or to administer larger doses
Various degrees of phase I & phase II blockade may coexist Mainly phase I: -- anticholinesterases enhance neuromuscular-
blockade Mainly phase II: --anticholinesterases antagonize phase II blockade
Small doses of edrophonium (Tensilon) (0.1-0.2 mg/kg, IV) may be useful in discriminating phase I vs. phase II block
Time course/Duration of Action -- Succinylcholine (Anectine)o Duration of action determined by plasma cholinesterase-mediated
succinylcholine (Anectine) hydrolysis Plasma cholinesterase: hepatic enzyme Initial succinylcholine (Anectine) metabolite: succinylmonocholine (very
weak neuromuscular-blocking)o Plasma cholinesterase activity determines the amount of succinylcholine
(Anectine) reaching the endplate {most succinylcholine (Anectine) is hydrolyzed by plasma enzyme}
o Factors influencing plasma cholinesterase (pseudocholinesterase) activity Reduced hepatic enzyme synthesis The presence of atypical (genetic) plasma cholinesterase which exhibits
reduced succinylcholine (Anectine) hydrolytic capacity Liver disease (severe) Drug effects, e.g. neostigmine (Prostigmin) -- a carbamylating
cholinesterase inhibitor Drugs which may prolong succinylcholine (Anectine) action due to effects on
pseudocholinesterase:o Insecticideso Nitrogen mustard, cyclophosphamide (Cytoxan) -- plasma cholinesterase
inhibitiono Metoclopramide (Reglan) (10 mg IV)o High estrogen levels (parturients)
Resistance to succinylcholine (Anectine)
Genetic: increased plasma cholinesterase activity Obesity -- more plasma cholinesterase activity Pharmacodynamic effects, e.g. myasthenia gravis
In myasthenia gravis: reduced number of nicotinic, neuromuscular junctional receptors -- the target for the drug succinylcholine (Anectine)
Atypical Pseudocholinesterase (plasma cholinesterase) Consequence: prolonged neuromuscular-blockade (1-3 hours) following normal
succinylcholine (Anectine) dosage Dibucaine (Nupercainal, generic)-related cholinesterase variant: most
important Dibucaine is an amide local anesthetic that inhibits wild type plasma
cholinesterase by 80%; however, it inhibits atypical enzyme by only 20%. If dibucaine (Nupercainal, generic) number equals 80: normal
cholinesterase If dibucaine (Nupercainal, generic) number equals 20: homozygous for
atypical cholinesterase -- frequency = 1/3200Clinical consequences of atypical cholinesterase on neuromuscular-blockade duration
1 mg/kg IV succinylcholine (Anectine): > three hours duration 25% recovery of single twitch response following 0.03 mg/kg IV {small dose}
mivacurium (Mivacron): 80minutes For heterozygous atypical plasma cholinesterase patients (frequency: 1/480) --
dibucaine (Nupercainal, generic) number equals 40-60 Moderately prolonged duration-- as long as 30 minutes following
succinylcholine (Anectine) Dibucaine (Nupercainal, generic) analysis only measures enzyme capability for
succinylcholine (Anectine) hydrolysis-- reduced active enzyme {due to affects the liver disease [reduced
synthesis] or enzyme inhibition due to anticholinesterases} will affect succinylcholine (Anectine) duration, but not be detected by dibucaine (Nupercainal, generic) analysis
Miller, R.D., Skeletal Muscle Relaxants, in Basic and Clinical Pharmacology, (Katzung, B. G., ed) Appleton-Lange, 1998, pp 434-449. Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219 White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Succinylcholine (Anectine) side effects
Succinylcholine (Anectine): major side effect categories
hyperkalemia arrhythmias myalgia increased
intraocular pressure
increased ICP (intracranial
pressure)
skeletal muscle contractions
myoglobinuria increased
intragastric pressure
o note: Many succinylcholine (Anectine) side effects may be reduced by prior administration of non-paralyzing doses of nondepolarizing neuromuscular-blocking agents
This pre-treatment does not reduce the extent of potassium release caused by succinylcholine (Anectine)
Small children are extremely sensitive to succinylcholine given that the parasympathetic system develops in advance of the sympathetic system. Should intubation not be successful following a single succinylcholine dose, the tendency to give a second dose should be resisted since the second dose may precipitate cardiac arrest.
o Cardiac arrhythmias: Classification:
sinus bradycardia Junctional rhythm Sinus arrest
Mechanism: Direct activation by succinylcholine (Anectine) of muscarinic,
cardiac cholinergic receptors Cardiac Effects: most likely following a second succinylcholine
(Anectine) dose, administered about five minutes following the initial dosage.
Atropine pre-treatment does not prevent bradycardia following a second succinylcholine (Anectine) dose
Other autonomic effects:
Succinylcholine (Anectine) activates ganglionic cholinergic receptors producing:
Increased heart rate Increased systemic blood-pressure
Hyperkalemia -- following succinylcholine (Anectine) Risk factors:
Muscular dystrophy (clinically unrecognized) Severe skeletal muscle trauma Skeletal muscle atrophy following denervation Unhealed third degree burns Other factors/considerations:
Succinylcholine (Anectine)-mediated potassium release secondary to severe abdominal infection
Potassium release following denervation (begins within four days, may last six months or more)
Pre-treatment with subparalyzing doses of nondepolarizing blockers is not effective in preventing or affecting the extent of potassium release following succinylcholine (Anectine)
Male children with undiagnosed myopathy -- predisposed to succinylcholine (Anectine)-induced:
Hyperkalemia Rhabdomyolysis Cardiac arrest
Muscular dystrophies: Most common form of muscular dystrophy
(frequency 1/3300 male births): Duchenne's muscular dystrophy
Diagnosis not possible until 2-6 years of age Becker muscular dystrophy (X-linked; (frequency:
1/33,000 male births), less common then Duchenne's)
Clinical Implications: Probable small percentage of pediatric
patients present with undiagnosed myopathy -- alternative to succinylcholine (Anectine) use -- a nondepolarizing neuromuscular-blocking agent
Myalgia-- postoperative succinylcholine (Anectine) skeletal muscle effect
Most common localization Neck (pharyngitis) Back Abdominal muscles
Possibly due to succinylcholine (Anectine)-induced skeletal muscle fiber contractions {affect reduced by prior treatment with non-paralyzing doses of tubocurarine} -- vecuronium (Norcuron) when used in place of succinylcholine (Anectine) does not prevent myalgia following laproscopy.
Increased Intragastric Pressure Succinylcholine (Anectine): frequently increases intragastric
pressure Thought to be related to intensity of succinylcholine
(Anectine)-induced muscle fasciculation {intragastric pressure increases prevented by previous administration of nondepolarizing agent}
Associated risk:
Possible gastric fluid passage into esophagus, pharynx, and long
o gastroesophageal sphincter more likely to open at pressures > 28 cm H2O
Rarely seen in children {probably due to limited muscle fasciculation associated with succinylcholine (Anectine)}
Increased Intraocular PressureSuccinylcholine (Anectine): transient increase beginning 2-4 minutes
after administration and lasting about 5-10 minutesPossible risk: in open eye injury (unsubstantiated by research};
however, this concern may limit use of succinylcholine (Anectine) in this patient population
Masseter Jaw Anatomy
images obtain from: http://www.teaching-biomed.man.ac.uk/student_projects/1999/surtees/tester/
mm.htm; Site concerned with "The Structural and Functional Anatomy of Mastication" by Paul Surtees, B.Sc; The Victoria University of Manchester (1999).
permission requested
Excessively-long skeletal muscle contraction -- masseter jaw rigidityo Halothane (Fluothane)-succinylcholine (Anectine) sequence associated
with masseter jaw rigidity/incomplete jaw relaxation in children Considered normal; frequency -- about 4% Clinical Challenge:
Normal response vs. masseter jaw rigidity prodromal for malignant hyperthermia
Miller, R.D., Skeletal Muscle Relaxants, in Basic and Clinical Pharmacology, (Katzung, B. G., ed) Appleton-Lange, 1998, pp 434-449; .Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Non-depolarizing Blocking Drugs
Table of Contents Mechanism of action Cardiovascular effects Myopathy associated with critical
illness Factors altering patient responses
to nondepolarizing drugs Interaction of nondepolarizing
neuromuscular agents with anesthetics
Differential effects based on duration of action
Antibiotic effect on neuromuscular-blockade
Local anesthetics:enhancement of block by nondepolarizing agents
Antiarrhythmic drugs: interaction with nondepolarizing blockers
Diuretics Magnesium Phenytoin (Dilantin) Lithium Cyclosporine (Sandimmune,
Neoral) Ganglionic blocking drugs Hypothermia Burns
Mechanism of Action: Nondepolarizing neuromuscular-blocking drugso Combination with nicotinic, cholinergic receptorso Greater than 80%-90% receptor blockade required for neuromuscular
transmission failure Reflects wide safety margin as well as basis for neuromuscular
blockade clinical monitoring Cardiovascular Effects: nondepolarizing neuromuscular blockers
o Secondary to: Histamine/other vasoactive substance release Effects mediated by cardiac muscarinic cholinergic receptors Effects mediated by autonomic nicotinic cholinergic receptors
o Factors responsible for cardiovascular effect variation between patients: Basal autonomic state
Preoperative medications Choice of agent for anesthesia maintenance Other drugs' presence
o Clinical Significance: cardiovascular effects of nondepolarizing agents are usually not significant
o "Autonomic Margin of Safety": difference between dosage producing neuromuscular-blockade and dosage producing circulatory effects
Relatively low autonomic safety margin -- pancuronium (Pavulon): e.g. ED95 pancuronium (Pavulon) dosage
which produces neuromuscular-blockade highly likely to produce cardiovascular effects (particularly chronotropic changes)
Relatively high autonomic safety margin -- vecuronium (Norcuron), rocuronium (Zemuron), cisatracurium
(Nimbex): wide safety margins, i.e. neuromuscular-blocking doses are much less than doses required to influence cardiovascular status
o Myopathy associated with Critical Illness Definition: patients on nondepolarizing neuromuscular blockers to
facilitate mechanical ventilation during prolonged illness may show skeletal muscle weakness following recovery
Critical illness may be associated with acute injury (multi-organ failure), or asthma
Moderate to severe quadriparesis (+/- areflexia) may be exhibited Weakness time-course: unpredictable Duration: weeks/months following discontinuation of
nondepolarizing agent Probably more common with aminosteroid agent (e.g.
pancuronium (Pavulon) or vecuronium (Norcuron)); has also been observed with atracurium (Tracrium)
Possible increased risk: pre-treatment with glucocorticoids
Factors which alter patient responses to nondepolarizing agents
Drugs
diureticsganglionic blocking
agentsmagnesium
aminoglycoside antibiotics
local anesthetics volatile anestheticsantiarrhythmic
agentslithium
Other Factors Influencing Responses to Nondepolarizing Agents
hypotension altered serum potassium adrenocortical abnormality
burned injury allergic reactions abnormal acid-base
balance
Gender may also influence duration of action; combinations of nondepolarizing neuromuscular-blocking agents may result in different effects than agents used separately
Volatile Anesthetics: interactions with neuromuscular, nondepolarizing agentso Dose-dependent increases in magnitude + duration of neuromuscular-blockade
{nondepolarizing agents}-- decreasing neuromuscular blocker dose requiremento Most prominent with:
Isoflurane (Forane) Desflurane (Suprane) Sevoflurane (Sevorane, Ultane)
o Intermediate effects with: halothane (Fluothane)
o Least effect with: nitrous oxide-opioid combinations
o Differential effects based on duration of action of neuromuscular blocking drug:
Less reduction in blocker dosage as a result of volatile anesthetic use with intermediate-duration agents:
Atracurium (Tracrium) Vecuronium (Norcuron) Rocuronium (Zemuron) Cisatracurium (Nimbex)
Greater reduction in blocker dosage as a result of volatile anesthetic use are required with long acting agents:
Pancuronium (Pavulon) Doxacurium (Nuromax) Pipecuronium (Arduan)
Advantage of using intermediate-duration neuromuscular-blocking agents:
Reduced effects on dosage by volatile anesthetics allows "more predictable degree" of skeletal muscle block {in the Absence of and exact information about brain anesthetic partial pressures}
Mechanism of volatile anesthetic effect on nondepolarizing neuromuscular-blocking drugs:possible causes --
1. Anesthetic-induced CNS depression -- with secondary decrease in skeletal muscle tone
2. Decreased postjunctional synaptic membrane sensitivity to depolarization
o Volatile anesthetics decreased twitch response (50% reduction) at higher MAC values, i.e. {1.25-1.75 MAC enflurane (Ethrane); 2.8-3.7 MAC halothane (Fluothane)}
Antibiotic effects on neuromuscular-blockade {nondepolarizing agents}
o Some antibiotics increase the effect of nondepolarizing neuromuscular blockerso Aminoglycoside antibiotics are most likely to produce this increased blocking
effect
Some aminoglycosides
Streptomycin Gentamicin (Garamycin) Tobramycin (Nebcin)
Amikacin (Amikin) Kanamycin (Kantrex)& Neomycin Spectinomycin (Trobicin)
Local Anesthetics (low-dose): enhancement of blockade by nondepolarizing agentso Higher local anesthetic doses: complete neuromuscular blockadeo Local anesthetics may:
Inhibit acetylcholine release "Stabilize" postsynaptic membrane {making depolarization more difficult} Direct muscle fiber depression
Cardiac antiarrhythmic agents/nondepolarizing neuromuscular blocker interactions
o Lidocaine (Xylocaine) (IV): may increase preexisting blockade Clinical context: lidocaine (Xylocaine) administration during general
anesthesia {protocol includes neuromuscular-blockade} recovery.o Quinidine gluconate (Quinaglute, Quinalan)
Increased blockade {for both nondepolarizing & depolarizing drugs} Probable mechanism: attenuation of acetylcholine release Clinical Context: quinidine gluconate (Quinaglute, Quinalan)
administration during recovery from general anesthesia {protocol includes neuromuscular blockers}
Diuretics -- furosemide (Lasix)o Increases neuromuscular-blocking by nondepolarizing agentso Probably due to reduced acetylcholine releaseo Related issues:
Hypokalemia associated with chronic diuretic use: Decreases pancuronium (Pavulon) dose requirements Increases neostigmine (Prostigmin) dosage required for
neuromuscular blockade antagonism Magnesium:
o Accentuates neuromuscular-blockade by nondepolarizing drugs; to a lesser degree also accentuates blockade by succinylcholine (Anectine)
o Interaction may be more pronounced with magnesium & vecuronium (Norcuron) than with other agents
o Clinical Context: Observed as enhancement of neuromuscular blockade {nondepolarizing
agent mediated} when magnesium is administered to patients treated with magnesium for pregnancy-caused hypertension (toxemia of pregnancy)
Phenytoin (Dilantin):o Patients chronically treated with phenytoin (Dilantin) are resistant to
neuromuscular-blockade produced by nondepolarizing agentso Mechanism: pharmacodynamic {higher neuromuscular blocker-plasma
concentration are required to produce a given level blockade in patients treated with phenytoin (Dilantin) than to produce same level of blockade in untreated patients}
Lithium: (used to treat bipolar disorder) -- possible enhanced neuromuscular-blockade by both depolarizing & nondepolarizing drugs
Cyclosporine (Sandimmune, Neoral) -- possible prolongation of neuromuscular-blockade by nondepolarizing drugs
Ganglionic blocking drugs (e.g., mecamylamine (Inversine)) may affect duration of neuromuscular-blockade by:
o Reduced skeletal muscle blood flowo Plasma cholinesterase in additiono Reduced post-junctional, nicotinic cholinergic receptor sensitivity
Hypothermia:o Increased neuromuscular-blockade duration (pancuronium (Pavulon) &
vecuronium (Norcuron)) Mechanism: decreased hepatic inactivating enzyme activity (temperature
dependency); decreased biliary & renal drug clearanceo Increased neuromuscular junctional sensitivity to pancuroniumo Increased duration of atracurium (Tracrium) action {also reduces infusion rate
necessary to maintain stable neuromuscular-blockade} Atracurium (Tracrium) effect: probably caused by decreased rate of
Hoffmann elimination & reduced ester hydrolysis Burns:
o Prolonged resistance to nondepolarizing neuromuscular blockers Starts about 10 days following injury Peaks about 40 days later Declines after about two months {may last considerably longer > one-
year}o Mechanism: -- probably pharmacodynamic {higher plasma drug
concentration required to cause a given extent of twitch suppression compared to similar extent in non--burn patients}
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996; Miller, R.D., Skeletal Muscle Relaxants, in Basic and Clinical Pharmacology, (Katzung, B. G., ed) Appleton-Lange, 1998, pp 434-449.
return to Table of Contents
Clinical Pharmacology
Role of neuromuscular blockade in anesthesia.
Primary uses of neuromuscular-blocking drugs:1. Skeletal muscle relaxation facilitating tracheal intubation2. Skeletal muscle relaxation to improve intraoperative surgical conditions
o Dose guidelines: Facilitation of tracheal intubation -- 2 x ED95 dose of nondepolarizing
muscle relaxant Laryngospasm: effectively treated with succinylcholine (Anectine)
Optimal intraoperative conditions -- 95% single twitch response suppression
o Neuromuscular-blocking drugs: -- no CNS depression; no analgesia therefore they do not substitute for anesthetic agents
o Other clinical uses: in managing patients requiring mechanical ventilation (intensive care
environment) Adult respiratory distress syndrome Tetanus Suppression of spontaneous respiration
Miller, R.D., Skeletal Muscle Relaxants, in Basic and Clinical Pharmacology, (Katzung, B. G., ed) Appleton-Lange, 1998, pp 434-449.Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219. White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Reversal of non-depolarizing blockers: Antagonist-assisted reversal of neuromuscular blockade produced by nondepolarizing neuromuscular-blocking agents
Antagonist-assisted neuromuscular-blockade reversal:o Edrophonium (Tensilon), neostigmine (Prostigmin), or pyridostigmine
(Mestinon)-- effective by increasing acetylcholine availability of neuromuscular junction {secondary to acetylcholinesterase inhibition}
Physostigmine (Antilirium): not used because dosage requirement is excessive
o Anticholinesterase agents are usually administered during spontaneous neuromuscular-blockade recovery
Recovery rate is the sum of (1) spontaneous recovery from the blocking drug and (2) the activity of the pharmacologic antagonist (anticholinesterase drugs)
Therefore: pharmacologic antagonism is more effective for short-or intermediate-acting neuromuscular-blocking drugs (undergoing plasma hydrolysis or Hofmann elimination) compared to long-acting nondepolarizing neuromuscular-blocking agents
o Special Considerations: use of muscarinic antagonists with anticholinesterases in Reversal of Neuromuscular Blockade
Reversal of nondepolarizing neuromuscular-blockade: necessitates only nicotinic cholinergic effects of anticholinesterases agents
Minimizing muscarinic receptor-mediated effects of anticholinesterase drugs is beneficial an accomplished by a concurrent administration of atropine or glycopyrrolate (Robinul) (antimuscarinics)
The antimuscarinic agent should have a more rapid onset than the anticholinesterase drugs -- reducing drug-induced bradycardia
if edrophonium (Tensilon) (0.5 mg/kg) is used; atropine 7 ug/kg is appropriate
a higher dose atropine (10-15 ug/kg) has been recommended, particularly if opioid-based maintenance anesthetic has been used
if neostigmine is used (slower onset of action compared edrophonium (Tensilon)), then atropine or glycopyrrolate (Robinul) and may be administered as the antimuscarinic agent;
Concurrent administration of these drugs results in an initial tachycardia because of atropine's more rapid onset
Factors influencing the speed and extent of neuromuscular blockade reversal by anticholinesterase agents
Intensity neuromuscular-blockade when reversal is initiated (train-of-four visible twitches)
Which nondepolarizing neuromuscular-blocking drug is being reversed is a factor
Edrophonium (Tensilon): less effective than neostigmine in reversing deep neuromuscular blockade (twitch height < 10% of control) produced by continuous atracurium (Tracrium), vecuronium (Norcuron), or pancuronium (Pavulon) infusions.
Edrophonium (Tensilon), probably better than neostigmine (Prostigmine for reversing atracurium (Tracrium) blockade
Neostigmine (Prostigmin), probably better than edrophonium (Tensilon) for reversing vecuronium (Norcuron) blockade
Prevention/inhibition of anticholinesterase-mediated antagonism of neuromuscular-blockade -- Possible factors
Certain antibiotics Hypothermia Respiratory acidosis (PaCO2 >50 mm Hg Hypokalemia/metabolic acidosis
Reversal of phase II block (following prolonged/repeated succinylcholine (Anectine)): may be reversed with edrophonium (Tensilon) or neostigmine (Prostigmin) in patients with normal plasma cholinesterase
In patients with atypical plasma cholinesterase, phase II block reversal may not be reliable, requiring mechanical ventilation until blockade subsides.
Stoelting, R.K., "Anticholinesterase Drugs and Cholinergic Agonists", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, 224-237.
Neuromuscular blockade: depolarizing agent followed by nondepolarizing agent (Succinylcholine (Anectine), then nondepolarizing agent)
o Clinical Context1. Initial administration of succinylcholine (Anectine){1 mg/kg, IV}--
supporting tracheal intubation2. Subsequent administration nondepolarizing agent
Greater neuromuscular-blockade in this case (even if evidence of succinylcholine (Anectine) effect has significantly diminished)
Counterintuitive effect: since the drug effects should be antagonistic
Duration of action of nondepolarizing agents (atracurium (Tracrium) or vecuronium (Norcuron))is not affected -- just the initial increased response
At lower succinylcholine (Anectine) doses (0.5 mg/kg)-- no initial enhancement of vecuronium (Norcuron) mediated neuromuscular-blockade.
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219
Combinations of Neuromuscular-blocking agentso Neuromuscular-blockade enhancement due to drug combinations:
Example-- Different major site of action {postsynaptic vs. presynaptic} Pancuronium (Pavulon) + metocurine (Metubine Iodide) or
tubocurarine shorter duration than with pancuronium (Pavulon) alone
Vecuronium (Norcuron) + tubocurarine Combinations of nondepolarizing agents -- same degree of blockade with
smaller dose of each drug Benefit: fewer dose-related side effects
Example: BP/heart rate effects of pancuronium (Pavulon) + metocurine (Metubine Iodide) < with pancuronium (Pavulon) monotherapy
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219
Gender and neuromuscular-blockadeo Differential drug sensitivity due to gender:
Pancuronium (Pavulon) Vecuronium (Norcuron) Rocuronium (Zemuron)
o Women: require 22% less vecuronium (Norcuron) than men to obtain the same
degree of neuromuscular junctional blockade 30% more sensitive to rocuronium (Zemuron) than men.
o Clinical significance: Normal rocuronium (Zemuron) dose should be reduced in women
compared to meno Possible mechanism: men have a greater skeletal muscle mass percentage--
requiring a higher neuromuscular-blocking dosage
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219
return to Table of Contents
Some Neuromuscular blocking drugs Doxacurium (Nuromax) Pancuronium (Pavulon) Pipecuronium (Arduan) Intermediate Acting Agents
o Atracurium (Tracrium) o Cisatracurium (Nimbex) o Vecuronium (Norcuron) o Rocuronium (Zemuron)
Metocurine (Metubine Iodide) Gallamine (Flaxedil) Succinylcholine (Anectine) Tubocurarine (generic) Short-acting nondepolarizing
agent: Mivacurium (Mivacron)
Doxacurium (Nuromax)o Overview: Doxacurium (Nuromax)
Nondepolarizing agents; ED95 -- 30 ug/kg Time to onset: 4-6 minutes Duration of action: about 60-90 minutes Renal clearance (similar to pancuronium (Pavulon)) Extended duration in elderly patients No histamine release; no cardiovascular effects
o Drug interactions: Volatile anesthetics
Reduce doxacurium (Nuromax) dose requirements by 20%-40% compared to blocking doses for nitrous oxide-fentanyl (Sublimaze) anesthesia
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219
Pancuronium (Pavulon)o Overview: pancuronium (Pavulon)
Commonly used long-acting nondepolarizing agent Low-cost advantage Cardiovascular side effects {doxacurium (Nuromax) & pipecuronium
(Arduan) -- similar to pancuronium (Pavulon) but without cardiovascular side effects}
Pancuronium (Pavulon) and related agents have replaced older, long-acting nondepolarizing drugs such as:
tubocurarine metocurine (Metubine Iodide) gallamine (Flaxedil)
No enhancement of histamine release No autonomic ganglia blockade
o General properties: pancuronium (Pavulon) nondepolarizing agent: ED95 = 70 ug/kg onset: 3-5 minutes duration: 60-90 minutes Pancuronium (Pavulon) block enhanced by respiratory acidosis which
opposes neostigmine (Prostigmin) antagonismo Pharmacokinetics: pancuronium (Pavulon)
Renal excretion: 80% of dose excreted unchanged Renal dysfunction: pancuronium (Pavulon) clearance may decrease by
33%-50% Hepatic metabolism (10%-40%)-with at least one potent metabolite Pancuronium (Pavulon) elimination halftime: affected by hepatic
cirrhosis/total biliary obstruction Aging: decreased pancuronium (Pavulon) plasma clearance
Mechanism: -- probably reduced renal functiono Cardiovascular Effects: pancuronium (Pavulon)
Slight increase (10%-15%): Heart rate Mean arterial pressure Cardiac output
Mechanism: Atropine-like effect on cardiac, muscarinic cholinergic receptors Sympathetic, autonomic nervous system activation
Adverse Effects: Increased incidence of cardiac arrhythmias following pancuronium
(Pavulon) (but not succinylcholine (Anectine)) in patients treated chronically with digitalis glycosides
Increased cardiac arrhythmias may occur due to enhanced sympathetic nervous system activity
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Pipecuronium (Arduan)o Overview: pipecuronium (Arduan)
nondepolarizing neuromuscular for; ED95 -- 50-60 ug/kg time to onset: 3-5 minutes duration of action: 60-90 minutes Enhanced potency increased/duration of action shortened in infants
{relative to adults or children} No histamine release; no cardiovascular changes associate with
pipecuronium (Arduan) administrationo Pharmacokinetics:
similar to pancuronium (Pavulon) in terms of renal clearance Hepatic cirrhosis -- no effect on pipecuronium (Arduan)
pharmacodynamics/ pharmacokinetics
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Introduction: Intermediate-acting Nondepolarizing Blockers
Overview: Intermediate-acting Nondepolarizing Blockerso Atracurium (Tracrium), vecuronium (Norcuron), rocuronium (Zemuron),
cisatracurium (Nimbex)o Efficient clearance mechanisms (reduced likelihood of significant accumulation
following repeated administration) Useful; but more expensive alternatives to succinylcholine (Anectine) &
pancuronium (Pavulon) Particularly useful for tracheal intubation/skeletal muscle relaxation for
short procedures (e.g. outpatient) Properties:
o Intermediate-acting agents (compared to long-acting agents): Similar time to onset {exception: roncuronium (Zemuron) -- rapid onset,
similar to succinylcholine (Anectine)} Duration of action -- about one-third of long-acting agents 30%-50% more rapid recovery rate Minimal/absent cardiovascular effects
o Intermediate duration -- due to rapid/efficient plasma clearance Special considerations:
o Rocuronium (Zemuron)-- rapid onset (similar to succinylcholine (Anectine)) Rapid onset -- within one-minute; good choice for tracheal intubation
facilitationo Method for accelerating onset for other "intermediate acting" agents
Use a small, subparalyzing dose (about 10% of ED95); followed about four minutes by the larger dose (2-3 X ED95)
Divided dose technique = priming principal (neuromuscular-blockade:two-step process)
1. Initial binding of spare receptors (no clinical effect)-- but reduces safety factor for neuromuscular transmission.
2. Deeper blockadeo Priming dose technique may be less valid now with the availability of single,
large IV roncuronium (Zemuron) dose -- providing rapid onset -- no risk of drug-induced weakness in awake patients
Antagonism of blockade cause by intermediate-acting nondepolarizing drugs:o anticholinesterase agents -- effective (within 20 minutes of administration of the
paralyzing intermediate-acting nondepolarizing drug dose) Pharmacologic antagonism (administration of anticholinesterase drugs)
coupled with rapid clearance of the blocker results in enhanced, recovery rates
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Atricurium (Tracrium)o Overview:atracurium (Tracrium)
Nondepolarizing, neuromuscular blocker (multiple isomers) ED95: 0.2 mg/kg Time to onset: 3-5 minutes Duration of action: about 20-35 minutes Site of action:
Presynaptic & postsynaptic membrane nicotinic receptors Degradation: spontaneous, in vivo (Hofmann elimination)
More stable in acid pH (storage --pH 3.25-3.65) Should not mix atracurium (Tracrium) with alkaline drugs
(e.g. barbiturates) or expose to solutions of more alkaline pH
alkaline pH: accelerated breakdowno Clearance-- two mechanisms
Hofmann elimination -- nonenzymatic; accounts for one-third of the degradation
Hydrolysis catalyzed by plasma esterases (nonspecific, i.e. not plasma cholinesterase); accounts for about two-thirds of degraded atracurium (Tracrium)
C learance not dependent on hepatic or renal function Clearance not affected in patients with atypical cholinesterase
o Laudanosine -- major metabolite of both catabolic atracurium (Tracrium) pathways
CNS stimulant --even with long, continues atracurium (Tracrium) infusions in the surgical setting--laudanosine concentrations remain below those apparently required for cardiovascular/CNS action; in the ICU setting with longer durations seizure potential becomes much more likely
o Cumulative effects No significant cumulative effect due to rapid clearance from plasma
(hydrolysis + Hofmann elimination)o Cardiovascular Effects:
With these background anesthetics: nitrous oxide, fentanyl (Sublimaze), halothane (Fluothane), isoflurane (Forane)
no BP/heart rate change associated with rapid IV atracurium (Tracrium) up to (2 X ED95)
With nitrous oxide-fentanyl (Sublimaze) anesthesia, IV atracurium (Tracrium) (3 X ED95): slight increase in heart rate (8%); decreased in mean arterial pressure (20%)
Cardiovascular effects: transitory (< 5 minutes) Facial/truncal flushing may be due to histamine release (no
circulatory effects if patients are pretreated with H1/H2 receptor blockers)
H 1/H2 receptors may be activated by prostacyclin (not histamine)o Special Patient Populations
Pediatric patients Similar atracurium (Tracrium) doses in adults and children (2-16
years old) when doses are calculated using mg/m2 rather than on a mg/kg basis.
Infants -- 1-6 months: require about 50% of the atracurium (Tracrium) dose given to older children
continuous infusion rate (to maintain steady-state blockade): 25% less during the first month of life
Elderly patients
Increasing age: no effect on atracurium (Tracrium) continuous infusion rate required for constant degree of neuromuscular-blockade
Mechanism -- age independence of Hofmann elimination & plasma ester hydrolysis inactivation processes {renal/hepatic state independent}
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Cisatracurium (Nimbex)o Overview: cisatracurium (Nimbex)
nondepolarizing neuromuscular blocker ED95: 50 ug/kg
Time to onset: 3-5 minutes Duration of action: 25-30 minutes Similar pharmacological profile to atracurium (Tracrium) compared
atracurium (Tracrium) Cisatracurium (Nimbex)(Tracrium) onset slightly slower Cisatracurium (Nimbex) much less likely to cause histamine
release, compared atracurium (Tracrium) Spontaneous neuromuscular blockade recovery not affected by
prolonged infusion (80 hr) to patients requiring ventilation in the intensive care environment-- by contrast to vecuronium (Norcuron)
Recovery: accelerated by the use of anticholinesterase agentso Clearance: cisatracurium (Nimbex)
Hofmann elimination (77% cisatracurium (Nimbex) clearance) 16%: renal
Neuromuscular-blockade characteristics not affected by hepatic or renal dysfunction
Cisatracurium (Nimbex) pharmacokinetics: not appreciably affected by advanced age (slight delay in time to onset)
o Cardiovascular Effects: cisatracurium (Nimbex) No histamine-releasing effects (by contrast yo atracurium (Tracrium)) Large doses (8 X ED95, IV) do not typically induce cardiovascular changes Less change in cerebral hemodynamics compared to equal potent
atracurium (Tracrium) dosage
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Vecuronium (Norcuron)o Overview: vecuronium (Norcuron)
Nondepolarizing neuromuscular blocker ED95: 50 ug/kg Time to onset: 3-5 minutes Duration of action: 20-35 minutes Structurally resembles pancuronium (Pavulon) -- vecuronium (Norcuron)
reduced anti-vagal properties compared to pancuronium (Pavulon) Unstable in solution; supplied as lyophilized powder
o Clearance Overview
hepatic metabolism & renal excretion metabolites generally much less active than vecuronium
(Norcuron) More lipid-soluble compared pancuronium (Pavulon) -- promotes
biliary excretion & significant hepatic uptake Rapid hepatic uptake may be responsible for short duration of
action
Reduced renal function Vecuronium (Norcuron) action prolonged in patients with renal
failure -- increased concentration of metabolites also contribute to prolonged skeletal muscle paralysis following long-term vecuronium (Norcuron) infusion
Reduced liver function When used in patients with hepatic cirrhosis, vecuronium
(Norcuron) at 0.2 mg/kg IV, longer duration of action (longer elimination halftime); not observed that the 0.1 mg/kg IV dose level
In patients with cholestasis, undergoing biliary surgical procedures: vecuronium (Norcuron) duration of action is increased (at the 0.2 mg/kg IV dosage)
o Cardiovascular Effects Minimal even at 3 X ED95, with rapid IV administration No vagolytic action apparently no/minimal histamine release possible vagotonic vecuronium (Norcuron) effect if administered nearly
concurrently with potent opioids (e.g. sufentanil (Sufenta)) vagotonic action may be serious -- promoting sinus nodal exit
block & cardiac arresto Use in pediatric patients
Vecuronium (Norcuron) potency {during nitrous oxide-halothane (Fluothane) anesthesia}: similar in --
infants (7-45 weeks) children (1-8 years) adults (18-38 years)
Onset of action: more rapid in infants compared to adults; (infants have high cardiac output -- promoting rapid onset)
Duration of action: longest in infants; shortest in children-- (infants have less/immature enzyme systems -- increased volume of distribution)
o Use in Elderly patients With increased age: decreased continuous infusion rate required to
maintain a given level of block Mechanism:
Age-related hepatic blood flow decrease; Age-related decreased renal blood flow; Age-related reduced hepatic microsomal enzyme system
activity (possibly) With increased age: prolonged recovery time if vecuronium (Norcuron)
was administered by continuous infusion (recovery from individual IV doses of vecuronium (Norcuron): not age sensitive)
o Use in Obstetric patients Clinically significant fetal effects not observed with nondepolarizing
neuromuscular-blocking drugs.
Vecuronium (Norcuron) clearance: increased during late pregnancy; possibly due to enhance microsomal enzyme activity {by progesterone}
Vecuronium (Norcuron)-induced neuromuscular blockade: prolonged immediately postpartum
o Obesity: Vecuronium (Norcuron) duration of action (but not atracurium
(Tracrium)) prolonged in obese (> 130% of ideal body weight) compared with nonobese adults
o Malignant Hyperthermia Not associated with vecuronium (Norcuron) or atracurium (Tracrium)
administration in animal models In a patient susceptible to malignant hyperthermia and therefore
pretreated with dantrolene (Dantrium): duration of vecuronium (Norcuron) action prolonged
Mechanism: Dantrolene (Dantrium) may prolonged action of neuromuscular-blocking agents secondary to dantrolene (Dantrium)-mediated impairment of presynaptic calcium release
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Rocuronium (Zemuron)o Overview: rocuronium (Zemuron)
Nondepolarizing agent; ED95 -- 0.3 mg/kg Time to onset: 1-2 minutes Duration of action: 20-35 minutes reduced potency (relative to vecuronium (Norcuron)) probably responsible
for relatively rapid onset [lower potency requires higher dose {more molecules administered} -- more molecules increased the likelihood of initial blockade]
o Time to onset: Clinical implications -- Time to onset of maximal single twitch depression (following 3-4 X
ED95): similar to time to onset for succinylcholine (Anectine) (when mg/kg, IV)
Rocuronium (Zemuron): only nondepolarizing agent which may substitute for succinylcholine (Anectine) when:
Succinylcholine (Anectine) is contradicted Rapid onset is required to promote tracheal intubation Differences between rocuronium (Zemuron) & succinylcholine
(Anectine) Laryngeal muscles more resistant to rocuronium
(Zemuron) than adductor pollicis: large dose rocuronium (Zemuron) effects resemble succinylcholine (Anectine) at adductor pollicis but will be delayed relative to succinylcholine (Anectine) effects at laryngeal adductors.
o Duration of action: Similar to other intermediate-acting agents-- at normal doses With large dose rocuronium (Zemuron) --3-4 X ED95-- to achieve onset
rates similar to succinylcholine (Anectine)-- duration is prolonged (more similar to long-acting nondepolarizing drugs, e.g. pancuronium (Pavulon))
Large IM doses (rocuronium (Zemuron)) -- 1-8 mg/kg given to infants/children to support rapid tracheal intubation results in relatively long durations (sixty minutes) -- This long duration may limit clinical utility.
o Effects on muscle groups Laryngeal adductor muscles and diaphragm: more resistant to rocuronium
(Zemuron) than adductor pollicis muscles Therefore, complete single twitch response suppression of adductor
pollicis is not sufficient to ensure paralysis of laryngeal muscles and diaphragm.
Maximal paralysis of laryngeal muscles may not be recognized if suppression of adductor pollicis single twitch response is being monitored as the clinical sign for optimal conditions supporting intubation.
Direct laryngoscopy for intubation performed at peak laryngeal muscle paralysis may result in abdominal muscle/diaphragmatic motion when the tracheal tube is positioned -- because the diaphragm and abdominal muscles are not yet fully paralyzed:
This condition is undesirable especially in those cases when pulmonary aspiration gastric contents is considered a risk.
o Pharmacokinetics -- Clearance: Rocuronium (Zemuron)
-- up to 50% excreted in the bile {animal studies} -- > 30% renal excretion (in 24 hours)
Liver disease: possible increased drug effect duration due to increased volume of distribution
Elderly patients: similar time to onset (compared to young adults) prolonged duration (compared to young adults)
o Cardiovascular Effects -- No histamine released (as with other non-polarizing agents) Small anti-vagal effect -- may be useful in certain surgical procedures
which cause vagal stimulation (e.g. opthalmological, laproscopic procedures)
Bradycardia (reflex) may occur with atracurium (Tracrium) or vecuronium (Norcuron) in patients undergoing these procedures
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Short-acting nondepolarizing neuromuscular blocker: Mivacurium (Mivacron)
Overview: mivacurium (Mivacron)o Only clinically useful nondepolarizing agent classified as short actingo ED95: 80 ug/kgo Time to onset: 2-3 minuteso Duration of action: 12-20 minutes (about 2 X longer than succinylcholine
(Anectine); about 30%-40% that of intermediate-acting neuromuscular-blocking agents)
o mivacurium (Mivacron): no malignant hyperthermia likely (based on swine model)
o Pancuronium (Pavulon), then mivacurium (Mivacron) leads to prolonged mivacurium (Mivacron) duration of action
Muscle effects: mivacurium (Mivacron)o Mivacurium (Mivacron) (2 X ED95):
Maximal depression (single twitch) of orbicularis oculi prior to maximal depression at adductor pollicis {different from succinylcholine (Anectine) which produces maximal depression at the sites concurrently}
Loss of orbicularis oculi function (but not adductor pollicis) correlates with maximal laryngeal adductor muscle and diaphragm paralysis
Clearance: mivacurium (Mivacron)o Short duration of action due to: plasma cholinesterase-mediated hydrolysis
Hydrolytic rate for mivacurium (Mivacron) about 90% that observed for succinylcholine (Anectine)
o Mivacurium (Mivacron) hydrolysis decreased with increased duration of action in the presence of atypical plasma cholinesterase
In patients with atypical plasma cholinesterase: mivacurium (Mivacron) blockade is intense in prolonged
Effective antidote: administration of human plasma cholinesterase {anticholinesterase agents appear ineffective}
o Renal status: renal excretion -- minor pathway for mivacurium (Mivacron) clearance
o Hepatic status: Patients with liver cirrhosis may experience prolonged mivacurium
(Mivacron) blockade if the liver disease is associated with reduced plasma cholinesterase activity
Increase volume of distribution associate with liver disease because reduced neuromuscular-blockade
o Pharmacological Antagonism: May not be needed given rapid spontaneous recovery from mivacurium
(Mivacron) blockade Anticholinesterase agents (e.g. neostigmine (Prostigmin)) because
they inhibit plasma cholinesterase may interfere with normal recovery mechanism
Moderate mivacurium (Mivacron)-mediated blockade may respond to neostigmine (Prostigmin)
Deep mivacurium (Mivacron)-mediated blockade maybe antagonized by edrophonium (Tensilon)
Cardiovascular Effects: mivacurium (Mivacron)o minor at doses up to 2 x ED95
o rapid IV administration of 3 x ED95 may provoked a decrease in BP (10%-20%), secondary to histamine release
Stoelting, R.K., "Neuromuscular-Blocking Drugs", in Pharmacology and Physiology in Anesthetic Practice, Lippincott-Raven Publishers, 1999, pp 182-219; White, P. F. "Anesthesia Drug Manual", W.B. Saunders Company, 1996.
Review Class
[ - will be on the test]
Propofol will be on test
Ketamine will be on the test
Timing and waveforms in IABP:
Inflate at the dicrotic notch and deflate just prior to the next systole (the end of the R wave)
Not Bad: Late inflation and early deflation (may be used safely if you have an eratic rhythm)
Bad: Early inflation and late deflation
CO= SV x HR (rate, preload, afterload, contractility)
normal CO = 4-6
CI= 2.4 (<2.2 is treatable)
Think of right heart and left heart as 2 separate organs
CO preload, afterload, contractilitycomplication of PCWP measurement (embolism, infection, rupture)
Invasive lines:Components: transducer, flush system (300mmHg), stop cock, central line
Zero the system (open to atmosphere) Level- (phlebostatic axis, RA- 4 ICS, mid clavicular)
Dampening (over and under dampening)
Common overdamping caused by a near empty flush bag
PACING:V-O-O (pacing without sensing or inhibiting)V-V-I (vent. Paced, vent sensed, a spike inhibits the next pace)
Not enough energy= failure to paceSensitivity- lower= more sensitive, high less sensitiveAbsolute and relative refractory periods
universal donor- Type OUniversal recipient- Type AB
AB- has all usual antigensO- has no antigens
IABP:RupturePlatelet damageMisplacement (high=CVA Sx – occludes Left breachial cephalic, Left..)(Low, decreased renal output, decreased GI motility, abdominal pain)
right atrial pressure questions
Remember to keep the arterial lines safe and patent, don’t forget patient safety
From the board:RA- 2-6PAP- 20-30 / 10-15SBP- 120 / 60SVR- 800-1200 / 71 (600)
a child cannot be rewarmed more than 1degree an hour
When pregnant females get dehydrated they release ADH (but it pitosin is also released along with it out of default)
Pediatric maintenance fluid replacement:4cc- 1st 10kg2cc- 2nd 10kg1cc- remaining weight
20mg/kg is a pediatric fluid bolus (trauma, vomiting, etc.) kids can usually handle excess fluids well
double fluids for dehydration
Magnesium given IV causes decreased DTR (Mg toxicity may hinder diaphragm movement)
Calcium Gluconate is given for Mg Toxicity
Normal urine output for:Child= 1cc/kg/hrInfant= 2cc/kg/hr (kidneys aren’t as developed and are more at risk for dehydration)
CVP= Preload
ABG questions on last test (a lot of them)
10-15 cc/kg for Vt (UMBC standard)
Goal of CCT- to maintain the same care between facilities
Ground- <50 miles
Helo- 10-150 milesFixed wing- >150 miles
Staffing: RN, FP-CAnd poss. RRT, MD, …
what patients DO NOT meet criteria for a CCT
EMTALA- facility must do a screening and stabilization prior to transport
lab data- CBC, Chem7,
Treatment of hyper K:Pretreat with calcium (to stabilize cardiac membraine)BicarbInsulin R/ GlucoseAlbuterolDialysisKay-exelate (potassium binder that acts in the gut)= GI will become mobile!
ABG values:
Bilirubin- byproduct of RBC degradation
Amylase/ Lipase- Pancreases
CPK/ CK- (CKMB is fractionated for myocardial distress)
CBC Na, K, Cl, Creat.ABG
Shock:Distributive (septic, anaphylactic, Neurogenic)Obstructive Cardiogenic
Management- fix the causeSeptic- surgery is a treatment for septic shock
Neurogenic shock- lack of sympathetic tone, fix with a pressor (epi, neo, dopamine, levophed)
Colloids- large particles, used to draw fluid into vascular space (albumin, blood) (is manitol???)
Breathing management:
CMV- controlled mandatory ventilation, (total control)AC- assist control, (set RR but able to breathe over at a set Vt)SIMV- Sync Intermittent Mandatory Vent (may breath over with regard to rate and Vt) (will insure a
minimum rate and volume)Pressure control- gas delivered to a set pressure (at the PIP) (PIP is usally less than 40)
Minute Vol- regulates CO₂ (low Minute Vol >CO₂PEEP- alveolar recruitmenmt, more gas exchangeFlow rate- I:E ratio (PEEP and expiratory time have no direct corolation)
High PEEP may decrease preload via compressing the venicava, correct this by increasing fluid if you cant lower PEEP
Wean PEEP slowly, don’t be afraid to increase PEEP
Vt= 10-15 cc/kg (UMBC standards) (6-10cc/kg is currently used in clinical setting)
Chest tubes:
Decrease air in the plural space, drain fluid
Water seal unit: 3 sections, collection, water seal, suction (water column/ 20 mm, H₂O) (add water to increase suction... in older units)
If chest tube is pulled out, seal the site, monitor for Pneumothorax
clamp the chest tube IS THE WRONG ASNWER!!!!
If water seal is broken during transport, place the tube in a bottle of saline
Suctioning:Is a sterile technique
RSI:Prepare- (meds drawn up, 2 ETT, back-up tube, 10cc syringe on the tube), make sure the suction works
Airway assessmentPreoxygenate- NRB 1-2 min, BVM with Oxygen (cautiously)
Premedicate- atropine, lidocaine, sedative (ketamine, atomadate, propofol, fentynal)Paralytic- succinicoline 1-2mg/kg, (2mg in kids) (the only depolorizing paralytic, onset 30 sec,
duration 5 min). (increases free Potassium, patient with neuromuscular diseases may have a lower uptake in the neurons, may have paralysis up to days), contraindication burns and crush injuries, malignant hyperthermia (Dantraline is a treatment for..), increased interoccular pressure
Pass the tube and confirmPost intubation care- analgesia and sedation
Ketamine- cuses hypotension, (My Cousin Caity Has Asthmia)
study the big medications, study the classes (classs I Na Channel blockers, II Beta, III Potassiun, IV Ca, V nucleoside- Adenocard) (the periodic table- Na, Boron, K, Ca, …)Trebutuline, Ketamine (ketamine is only listed in the pediatric section)
ICP monitoring:0-15 is normal rangeMAP-ICP=CPP (CPP should be >70)Monro-Kellei doctrine- if the patient has a inter-ventricular catheter you can decrease the 10% of fluid,
but there is a high risk of infectionAxis to level the cranial catheter is the tragus of the earICP Waves: (remember this is seen in trending over time, hours)A waves- high with a plateu, sustaining with >60 mm/Hg, seen in brain herniationB waves- sharp pulsations,up to 50mm/Hg high pressure increases, poor compensation
B waves need to be treated before this point optimally.C waves- rhythmic, small amplitude, 4-8/min, clinically insignificant
Neuro assessment- the key is to continuously recheck, DTR (graded 0-4, 2 is normal)
Pupilary assessment-
Vital signs-
Inline position of the neck may decrease drainage and flow of CSF (C-Collar)
To manage ICP:
OxygenSedation (will lower ICP)Manitol (crystallizes very easy, use filtered needle)
levophed for sepsis, dopamine is never the first answer for CC transports
TEST:
Final exam is 110 questionsPassing is 70% Avg. score is 75-80%BRING #2 PenileMay write on the exam sheetMay leave for bathroom one at a timeStandard calculators may be usedNo time limitRetest may be taken twiceUsually testing is done by 11amMissing 1 cert, may take exam but cannot see results, missing 2 certs, may NOT take the exam
© 2010 M.N. LaBarbera