EXAM 1 (2) (1).docx

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Obstetric

Pediatric

Cardiothoracic

Neuro

Outpatient surgery

Ketamine clinic

Office Based

Pain management

Critical care

History

1864 Morton delivered the first ether anesthetic

WW2 is when more modern day practices were established

Alice Magaw is known as the 1st nurse anesthetist

Considerations Influencing Anesthetic Technique

Patient safety

Patient comfort

Provider Preference

Coexisting disease

Surgical site

Positioning

Elective vs Emergence

Airway

Duration of surgery

Patient age

Recovery time

PACU discharge criteria of facility

Ideal Anesthetic Technique

Optimal patient safety

Patient satisfaction

Excellent operating conditions for surgeon

Allows for rapid recovery

Avoid postoperative side effects

Low cost

Early transfer or discharge from PACU (costs)

Types of Anesthesia

General Anesthesia Care

Definition

Drug induced depression of the CNS resulting in the loss of response to
perception of all external stimuli

ASA continuum of sedation

"is a drug-induced loss of consciousness during which patients are not
arousable, even by painful stimulation"

General Anesthetic Types

Inhalation only

typically used in pediatric cases

Intravenous only (TIVA)

used in neuro-monitored cases

Combination Inhalation/IV

most common --- induction with IV & maintenance with inhalation

Components of anesthetic state

Unconsciousness

no measurement --- only inference through EEG & BIS monitoring

Amnesia

typically achieved with the use of benzodiazepines

Analgesia

not always required, i.e. cases with local blocks

Immobility

does not paralysis, simply means no longer responsive to stimuli

Attenuation of autonomic responses to noxious stimuli

Phases of General Anesthesia

Induction

Definition

administering anesthetic drugs (Inhaled of IV) to induce a state of
anesthesia

inducing a state of unconsciousness

Typically called "Induction of General Anesthesia"

Pre-Induction Monitors

routine monitoring includes EKG, NIBP, pulse-ox, CO2, temperature

standard monitors should be used as minimum standard for **all
anesthetic techniques**

AANA Standard IX / ASA Standard II

held to these standards regardless of location within the hospital

Special monitors

Arterial lines when a consistent and continuous monitoring of BP is
needed

CVP when there is a risk for bleeding or CVP value is needed to guide
intra-op fluid management

Other examples: BIS, cerebral oximeter, TEE, SWAN, flo-trac, etc

Pre-Induction Pre-oxygenation

The percent of O2 at room air is 21%

Oxygen application prior to the initiation of induction sequence should
be performed

Purpose - to replace nitrogen in patients functional residual capacity
(de-nitrogenation)

Why? Buys us time as providers to secure airway and reduce apnea

Have patient breath 100% oxygen via face mask (ensure seal) for a period
of 3-5 minutes OR instruct patient to take 8 vital capacity breaths

**Intravenous Induction of Anesthesia**

A single ideal intravenous anesthesia induction drug has yet to be
developed

Desirable properties for induction agents:

Rapid and smooth onset and recovery

Analgesia

Minimal cardiac and respiratory depression

Antiemetic actions

Lack of toxicity or histamine release

Advantages pharmacokinetics and pharmaceutics

IV induction produces a rapid onset of unconsciousness

Commonly used anesthetic drugs:

Propofol (most commonly used) sedative hypnotic (GABA)

Thiopental (barbiturate)

Brevital (barbiturate)

Commonly used in electro-convulsion therapy as it does not effect the
seizure threshold

Etomidate sedative hypnotic (GABA)

Ketamine (IV/IM) NMDA receptor antagonist - dissociative

Opioids

Benzodiazepines

Generally used for adult patients or patients with a preexisting IV

Choice of agent used dependent upon patient comorbidities and
situational needs

**Standard Induction Sequence**

Room setup & Perform machine check

Confirm checklist "sam tide"

Suction, airway, machine, tape, IV, drugs, equipment

Apply monitors

Position patient

Baseline vital

To provide reference, possible stop point prior to proceeding

Pre-oxygenation

Administration of induction agents (IV/Inhalation/Combination)

Eyelid reflex = protective reflex

Mask ventilation

Neuromuscular blocking agent

IF you are planning to use an LMA or perform a MASK case --- no
paralytics will be given

Airway instrumentation

**Rapid Sequence Induction of Anesthesia**

"Intravenous injection of anesthetic to produce unconsciousness followed
immediately by a neuromuscular blocking drug that produces rapid onset
of skeletal muscle paralysis"

Room setup & Machine check

Confirm checklist "samtide"

Suction, airway, machine, tape, IV, drugs, equipment

Apply monitors

Position patient

Baseline vitals

To provide reference, possible stop point before proceeding

Pre-oxygenation

Administration of induction agents (IV/inhalation/combo)

Cricoid pressure applied prior to loss of consciousness

Used to close the esophagus to lessen the chance of aspiration ---
pressure should be maintained until confirmation of CO2 detection for 3
consecutive breaths

Eyelid reflex

Neuromuscular blocking agent

Airway instrumentation - always ETT

What situation would necessitate an RSI?

Full stomach or any other concern for aspiration

Weight-loss drugs that cause delayed gastric emptying

Acute abdomen --- appendicitis, bowel perf, small bowel obstruction

**Inhalation Induction**

Most common method for inducing children in North America who are
scheduled for an elective case

Why? No IV, pt uncooperative, less traumatic

Also known as mask induction

Oxygen + volatile agent or oxygen + nitrous oxide + volatile agent

Nitrous speeds up the onset of volatile agent

Volatile anesthetics:

Isoflurane (lipid soluble & slow)

Desflurane (irritating)

Sevoflurane (most common, non-pungent and non-irritating)

Steps:

Prime circuit

Monitors (pulse ox is most important)

Mask application - administration of O2/sevo or O2/N2O/sevo

Loss of consciousness

Maintain ventilation

Remain VIGILANT by monitoring for adequate ventilation (whether
spontaneous or controlled)

PIV placement

+/- IV induction

+/- paralytics

Airway instrumentation (LMA/ETT)

Verify placement

**Post-Standard Induction**

Assess LOC and loss of lid reflex

Tapes eyes closed

Provide positive pressure ventilation

Via face-mask

Asses ease/difficulty of ventilation

Can determine extubation technique

Maintain oxygenation = LIFE

+/- administration of paralytics

Airway instrumentation

Laryngeal mask airway (no paralytic)

Endotracheal tube

Endobronchial tube (one lung ventilation)

DO NOT perform post induction ventilation during RSI

Maintenance

Defined as "the management of physiological function and the maintenance
of surgical anesthesia following induction and until emergence"

Goals - maintain surgical anesthesia, maintain physiologic homeostasis,
monitoring is needed to ensure that these goals are met

Requires Vigilance

Provide: Unconsciousness, amnesia, analgesia, immobility, muscle
relaxation, and control of the sympathetic nervous system response to
noxious stimuli

Valley of Anesthesia - the time after induction but before incision

Accomplished by a combination of drugs

Inhaled and IV - with or without neuromuscular blocking agents
(procedure dependent)

Drugs administered on basis of specific goal relevant to pharmacologic
effect

Prevention of intraoperative awareness

**Maintenance of Physiologic Homeostasis**

Maintain euvolemia for normotensive patients

Patients with long standing uncontrolled HTN will require higher MAP ---
goal in to keep MAP within 20% of baseline

Fluid management: Traditional vs Goal Directed

Replace fluid: NPO, bowel prep?

Monitor/chart/estimate and replace blood loss

Monitor urine output

Titrate, administer, and redose medications as necessary

Maintain positioning and monitor pressure points

Nerve injury prevention

Maintain and monitor adequacy of ventilation

Prevent hypothermia

Maintenance monitoring

**Stay vigilant** of oxygenation, vitals signs, anesthetic depth, level
of muscle relaxation, positioning''

**Stages of General Anesthesia** (Intro to Anesthesia Ch 16)

Stage I: Analgesia

Begins with administration of induction agents

Ends with loss of consciousness ness

Patients response to pain is altered

Encompasses all staged of sedation up to general anesthesia

Stage II: Delirium

Begins with loss of consciousness

Period of involuntary movement

Signs:

Irregular respirations

Periods of apnea, breath holding

Dilated pupils and divergent gaze

Tachycardia

Hypertension

Delirium

This stage is usually skipped in IV induction

Most important during emergence --- NEVER pull tube during stage 2
(highest risk for laryngospasms)

Stage III: Surgical Anesthesia

Begins with onset of regular breathing

Ends with loss of spontaneous respirations

Deep sleep not subject to rousing

Consists of four planes

Most surgical procedures can be safely performed in planes 1 and 2

Plane 1 - loss of lid reflex, respirations regular and deeper than
normal pupils reactive, swallowing, retching, vomiting reflexes
disappear and reappear in that order, respiratory response to skin
incision is decreased, decreased muscle tone

Plane 2 - starts when eyeballs become concentrically fixed, regular
respirations with decreased tidal volume, respiratory response to skin
incision disappears, moderate loss of muscle tone, reflex closure of
vocal cords begins to disappear, pupils unreliable

Plane 3 - begins with decrease in inter-coastal muscle activity, ends
with inter-coastal activity absent and respirations is completely
diaphragmatic, diaphragmatic breathing (can be seen as jerking
movement), pupils continue to dilate

Plane 4 - begins with complete loss of inter-coastal activity, ends with
loss of spontaneous respiration, pupils completely dilated, non
responsive to light, all muscle tone lost

Stage IV: Overdose AKA respiratory paralysis

Cessation of respiration due to concentration of anesthetic agent

Ends with circulatory collapse

Should be lightened IMMEDIATELY

Emergence

"Is a transition process where a patients goes from general anesthesia
to awake and spontaneously breathing"

Critical period of recovery from general anesthesia with the return of:

Consciousness

Neuromuscular conduction

Airway protective reflexes

A plan for emergence should begin on first patient contact and be
developed based on the patient's commorbidities and surgeon's needs

**Preparation**

Estimate remaining duration of surgical procedure

Decrease anesthetic depth (if planning for awake extubation)

Assess level of paralysis

TOF/Acceleromyography

Administer reversal

When appropriate for procedure (deep fascia closed)

TOF of at least 2, preferably 3-4 twitches

Adequate recovery from NMBA should be established prior to extubation,
TOF ratio \>90% --- after reversal

Awareness possible --- in awake extubation

Administer medication to prevent PONV

Pain management

Opioids

Requirements based upon patient weight, procedure, physiological status,
and opioid tolerance

Respiratory rate can be a useful indicator of adequate analgesia

Diffusion hypoxia

Occurs when N2O has been used

N2O diffuses rapidly from blood into alveoli replace with RA if no on
100% O2

Administer 100% O2 for 5-10 minutes to prevent hypoxia

Suction oral/pharyngeal cavity

Place oral pharyngeal or nasal pharyngeal airway

**Evaluation of signs and stages of anesthesia during emergence**

Stage III - deep extubation

Stage II - excitement

DO NOT EXTUBATE

Irregular breathing

Possible agitation

High risk for laryngospasms and regurgitation

Stage I - awake extubation

**Awake Extubation Criteria**

If high risk for aspiration or difficult intubation --- only extubate
the patient when fully awake

Patent must be conscious and responding to simple
commands such as "open you eyes" or "squeeze my hand"

Ensure adequate reversal of NMBA

The ability to perform basic actions are not reliable assurance of NMBA
recovery --- make the patient left their head off the table and hold it

Must be hemodynamically stable and normothermic

Adequate spontaneous ventilation with a regular rate, RR \>8 and TV \>
6-8 ml/kg

**Deep Extubation Criteria**

Chosen when the presence of an ETT is to be avoided during emergence to
prevent bucking and straining (open belly/big abdominal surgeries)

Anesthetic Stage III

Adequate reversal of NMBA

Hemodynamically stable and normothermic

Adequate spontaneous ventilation with regular rate, RR\>8, and TV 6-8
ml/kg

Technique - maintain anesthetic depth, suction airway, place OPA, assess
for breath holding, extubate, place face-mask to assess for continued
adequate ventilation

Monitored Anesthesia Care (MAC)

Monitored Anesthesia Care does not describe the continuum of depth of
sedation, rather it describes "a specific anesthesia service in which an
anesthesiologist has been requested to participate in the care of a
patient undergoing a diagnostic or therapeutic procedure"

If the patient **loses consciousness and the ability to respond
purposefully**, the anesthesia care is a general anesthetic,
irrespective of whether airway instrumentation is required.

**All monitoring standards must be maintained**

The provider of monitored anesthesia care must be prepared and qualified
to convert to general when necessary

May require varying levels of sedation, analgesia, and anxiolytics

Desired end points to provide comfort, maintain cardiopulmonary
stability, improve operating conditions and prevent recall of.
Unpleasant perioperative events

Ideally patient should be able to communicate during the procedure

Therapy should be administered to treat pain, anxiety, and agitation

Combination of local/MAC are common

**During monitored anesthesia care the anesthesia provider performs a
number of services**

Diagnosis and treatment of clinical problems that occur during the
procedure

Support of vital functions

Administration of sedatives, analgesics, hypnotics, anesthetic agents,
or other medication as necessary for patient safety

Psychological support and physical comfort

Provision of other medical services as needed to complete the procedure
safely

Local anesthetic

Which drug

Characteristic

Recommended dose

Max dose

Concentrations

With/without preservatives

**Who is not a good candidate??**

Children, confused, uncooperative, unable to follow commands, patients
with tremors, patients who are unable to lie flat

"An analysis of the ASA Closed Claims Project database focusing on MAC
likewise revealed that over-sedation and respiratory collapse most
frequently led to claims

**To avoid be VIGILANT, have airway equipment present & be prepared to
convert to general**

ASA Publication on Sedation

Minimal sedation (anxiolytics)

A drug-induced state during which patients respond normally to verbal
commands

Cognitive function and physical coordination may be impaired --- airway,
reflexes, ventilatory, and cardiovascular functions are unaffected

Moderate sedation/Analgesia (Conscious Sedation)

Drug-induced depression of consciousness during which patients respond
purposefully to verbal commands, either alone or accompanied by light
tactile stimulation

No interventions are required to maintain a patent airway and
spontaneous ventilation is adequate.

Cardiovascular function is usually maintained

Reflex withdrawal from a painful stimuli is NOT considered a purposeful
response

Deep sedation/analgesia

Drug-induced depression of consciousness during which patients cannot be
easily aroused but respond purposefully following repeated of painful
stimulation.

The ability to independently maintain ventilatory function may be
impaired

May require assistance in maintaining a patent airway and spontaneous
ventilation may be inadequate

Cardiovascular function is usually maintained

Monitoring should be on dedicated limbs

ETCO2 can be monitored via NC, however ETCO2 does not measure quality of
ventilation in an open system --- need a sealed mask to adequately
monitor ventilation

INTRODUCTION TO REGIONAL ANESTHESIA

History

The original application of modern local anesthesia is credited to Carl
Koller, who demonstrated topical anesthesia of the eye with cocaine in
1884

In late 1884, William Halstead used cocaine for intradermal infiltration
and nerve blocks including facial nerve, brachial plexus, pudendal and
posterior tibial nerve

Spinal anesthesia is credited to Augustus Bier and Theodore Tuffier who
in 1898 injected cocaine into the spinal column as a surgical anesthetic
technique

NEUROAXIAL ANESTHESIA

definitions

placement of local anesthetic adjacent to the spinal cord

Local anesthetics work by blocking signals to and from the nerve --- act
through sodium channels to interrupt conduction of the nerve fiber

Can be used with or without general anesthesia (spinals are more likely
to be used as primary mode of anesthesia)

Performed as a single injection (typically spinal) or with a catheter to
allow intermittent boluses or continuous infusions (epidural)

**Role in Practice**

Many operations performed below the neck can be performed under
neuroaxial anesthesia --- except those operations that have the
possibility of impairing ventilation and that may require an ETT

Why use regional?

It has been shown that general anesthesia patients have a greater
percentage of adverse in-hosptial outcomes than those that received
neuroaxial anesthesia

Used in a variety of cases, also used to treat acute and chronic pain

Typically used as primary mode of anesthesia in procedure performed
below the umbillcus

**Advantages** --- in relation to general anesthesia

Studies have shown regional anesthesia to:

Decrease intraoperative blood loss

Decrease incidence of venous thrombosis & pulmonary embolism

Decrease cardiac complications (high risk patients)

Decrease bleeding & transfusion requirements

Increase vascular graft patency

Earlier return of GI junction/lower incidence of postoperative ileus

Reduction of parenteral opioid requirements

Blunt the body's stress response to surgery

Spinal advantages takes less time to perform than epidurals; more rapid
onset, associated with less pain during procedure

ANATOMY

VERTEBRAL COLUMN (Nagelhout p 677-679)

Composed of vertebral bones (33) and intervertebral disks (24) that
connect the vertebrae anteriorly

Vertebrae (33)

7 cervical

12 thoracic

5 lumbar

5 fused sacral

4 fused coccyx

Provides structural support for the body, protection for the spinal cord
and nerves, and allows mobility

Anteriorly --- concave in thoracic and sacral vertebrae (primary
curvature formation that is developed in-utero) & convex in cervical and
lumber regions (secondary formation from bearing of weight)

Abnormal curvatures

Scoliosis - lateral curvature (most common)

Kyphosis - excessive posterior curvature (thoracic hump)

Lordosis - excessive hollowing of the lumbar vertebrae

Kyphoscoliosis - concomitant lateral bending and rotation of the
vertebral column

It is important to determine if the patient has a history of abnormal
curvatures or perform an adequate assessment to identify

Vertebral body is supported anteriorly and posteriorly by longitudinal
ligaments

Supported posteriorly (dorsal) by

Supra-spinous ligament

Interspinous ligament

Ligament flavum

Final barrier to a needle before it enters the spinal canal (vertebral
foramen)

Tougher than the interspinous ligament and east to identify with an
epidural needle

VERTEBRA

Vertebral foramen stacked vertically forms the vertebral column (spinal
canal)

Features:

Large anterior cylindrical vertebral body

Vertebral Foramen can be defined as:

Anteriorly by vertebral body

Laterally by pedicles (2), transverse processes (2), superior articular
process & mammillary process, inferior articular process

Posteriorly by lamina (2) & spinous process

Articular processes are covered in hyaline cartilage because they
articulate (touch) other bones creating a facet joint

C2-C6 have a bifid spinous process, C7 is normal


LUMBAR

THORACIC


SACRUM & COCCYX

CERVICAL

SPINAL CANAL & SPINAL CORD

Spinal canal contains the spinal cord with its coverings (meninges),
fatty tissue, and venous plexus

Meninges (3 layers) --- pia mater (innermost), arachnoid mater, and dura
mater (outermost)

Cerebral spinal fluid is found between the pia and arachnoid mater in
the subarachnoid space which is continuous with the brain

The spinal cord extends from the foramen magnum to the level of L1 in
adults and L3 in children (bc the vertebral column growth is more rapid
that the spinal cord)

Miller "spinal cord ends at the lower border of L1 in adults

Nagelhout "from medulla oblongata to the level of L2 vertebra, below L2
in 1% of adults and rarely to L3"

Needle puncture below L1 usually avoids potential trauma to the spinal
cord

There are 31 spinal nerves:

8 Cervical - C1-C7 nerves will exit above it's corresponding vertebrae,
C8 has to exit below

12 Thoracic

5 Lumbar

5 Sacral

1 Coccyxgeal

Spinal enlargements of the spinal cord are found in certain areas

Cervical (C4-T1) --- nerves for upper extremities

Lumbar (L2-S3) --- nerves for lower extremities

MENINGES

Protective covering for the spinal cord and nerve roots

Non-nervous - no conduction

Dura Mater

Outermost layer

Composed of dense fibrous tissue with few elastic fibers

Attached superiorly to the foramen magnum & inferiorly at its ends at
the S1 or S2 vertebra

Latin for "tough mother"

Arachnoid Mater

Closely adherent to the thicker & denser dura mate

Thin, spiderweb like covering forming the middle layer

Beneath this layer is the subarachnoid space (CSF is found here)

Pia Mater

Innermost layer

Thin and in direct contact with the outer surface of the spinal cord

SPINAL CORD AND SPINAL NERVES

The end of the spinal cord tapers to the canus medullaris and nerve
pathways continue in a collection of rootlets called the cauda equina
"horse's tail" contained within the lower dural sac (L1-L5)

The filium terminale (an extension of the pia mater) penetrates the dura
and extends to the periosteum of the coccyx to
create a tether

Anterior and posterior nerve roots at each level join and exit the
spinal canal through the intervertebral foramina to form the spinal
nerve

Spinal nerves: Cervical region exit above the corresponding vertebrae
except cervical nerve 8 (exits below C7 vertebra) --- Starting at T1
they exit below their corresponding vertebrae

Dural sac and subarachnoid space usually extends to S2 in adults and
often S3 in children

**Dorsal & Ventral Nerve Roots**

Anterior/Ventral root is responsible for motor (efferent) &
Posterior/Dorsal root carry sensory (afferent)

The roots conjoin as they exit the vertebral foramen to create the
spinal nerves

Local anesthetics exert action on the nerve roots as they exit the cord
affecting both sensory and motor

"Because the spinal cord ends at L1, lower lumbar and sacral nerve
extend for some distance within the spinal canal as the cauda equina
before exiting the intervertebral foramina to the sacral epidural space"

All spinal anesthetics are placed below L1 into the dural sac at the
level of the cauda equina

Epidural anesthetics can be placed as any level of the vertebral column
(aside from the sacrum)

SPACES

Epidural space

A potential space outside the dural sac but inside the vertebral canal

Contains epidural veins, fat, lymphatics, segmental arteries and nerve
roots

Bordered by the dura anteriorly and the ligamentum flavum posteriorly

Often described as a "discontinuous space" (contact may be interrupted)

Largest at the midline of the lumbar region (3-5mm) --- thoracic
(2-3mm), cervical (1.5-2mm)

Subarachnoid space

Continuous with the central canal of the spinal cord and the ventricles
of the brain

Filled with CSF

Epidural neuroaxial anesthesia

The administration of local anesthetic solution in the space outside of
the dura layer (i.e. epi-dura) can be approached at any spinal level ---
even cervical (higher the level = higher the risk = more precision
required)

Spinal neuraxial anesthesia

Local anesthetic solution is injected into the subarachnoid space and is
always approached below the level of L1

Blocks neural conduction in the nerve roots in the area of its spread in
the cerebrospinal fluid

LAYERS

When a needle is advanced from a posterior approach from skim the spinal
cord the layers are:

Skin

Subcutaneous tissue

Supra-spinous ligament

Interspinous/Intra-spinous ligament

Ligamentum flavum

Epidural space --- STOP HERE FOR EPIDURAL

Dura mater

Subdural space

Arachnoid mater

Subarachnoid space --- STOP HERE FOR SPINAL

Pia mater

Spinal cord

Distance from skin to epidural space is between (2.5-8 cm) --- on
average about 5 cm

BLOOD SUPPLY

3 arteries that supply the spinal cord (2 posterior, 1 anterior)

Anterior artery is the primary blood supply to the lower 2/3 of the
spinal cord

The great ventral radicular artery (Artery of Adamkiewicz - T8-T11) is
the main blood supply to the anterior spinal artery (do not stop/alter
blood flow here)

If blood flow is interrupted, anesthetic can be interrupted

MECHANISM OF ACTION

Principle site of action for neuraxial blockade is the nerve root

Spinal Anesthesia

LA is injected into the CSF

Allows for relatively small dose (\ pooling -\> decreased venous return -\>
decreased cardiac output

Blocks above T4 result in:

Direct interruption of cardiac accelerator fibers which arise at T1-T4,
when blocked may cause bradycardia

Sympathetic blockade is unavoidable & can ultimately lead to cardiac
arrest

SPINAL BLOCK

Also known as subarachnoid blockade

LA injected into the subarachnoid space & mixes with CSF

Usually administered as a single injection

Onset of action/blockade is almost immediate

NEEDLES

Pencil point tips

Less traumatic - will spread fibers

Sprotte & Whitacre

Cutting point tips

More traumatic - will cut fibers

Quincke & Atraucan

Large gauge = Less traumatic

High risk for posterior puncture HA:

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