Psychotherapeutic Drugs Lecture 5 & 6 PDF

Summary

These lecture notes cover psychotherapeutic drugs, their effects on various mental illnesses like schizophrenia, mania, and depression. The notes describe the drugs' palliative effects and treatment approaches. They also detail different antipsychotic classifications, mechanisms of action, and common adverse effects.

Full Transcript

Psychotherapeutic Drugs
Psychotherapeutic drugs are described for their effects
of relieving symptoms of mental illness that include
Schizophrenia

Mania

Depression
Anxiety

Drugs for these disorders are Palliative i.e. alleviate
without curing
Psychotherapeutic Drugs
These drugs are for major mental illnesses and not for
trivial indications where simpler drugs do equally as
well

Commencing treatment
Minimise side effects
Allow gradual build up to an optimal dose

Treatment
May be long term or intermittent depending on
the severity and type of condition

Compliance
Psychotherapeutic Drugs
Many medically used drugs can produce psychiatric
symptoms at therapeutic doses (rare) and when abused.

Examples
Depression

Methydopa (Aldomet ®), Clonadine (Catapress®) and
some beta blockers e.g. propanalol (Inderal®).
Psychosis, euphoria, depression

Corticosteriods e.g. Betemethasone (Celestone
Chronodose® inj)
Confusion disorientation, depression

Atropine, Benztropine
Antipsychotics
Antipsychotics
Used primarily in the management of psychotic
disorders to ameliorate abnormal behaviour, thoughts
and perceptions.

These medications have sedating and tranquilising
effects that make them useful in severely agitated or
disturbed patients
Antipsychotics
Amisulphride (Solian®) Olanzapine (Zyprexa®)
Aripiprazole (Abilify®) Paliperidone (Invega®)
Chlorpromazine (Largactil®) Pericyazine (Neulactil®)
Clozapine (Clopine®) Quetiapine (Seroquel®)
Droperidol (Droleptan®) Risperidone (Risperdal®)
Flupenthixol (Flunaxol®) Trifluperazine (Stelazine®)
Fluphenazine (Modecate®) Ziprasidone (Zeldox®)
Haloperidol (Serenace®) Zuclopenthixol (Clopixol®)
Classification
Traditionally antipsychotics have been classified as typical or
1st generation (older) or atypical or 2nd generation (newer)

Not a useful classification as both groups
Similar modes of action
Similar side effect profiles

Older medications were classified according to chemical
structure, however not helpful for the newer antipsychotics

In clinical practice – termed as high potency and low potency
Mechanism of action
Antipsychotic action involves blockade of CNS
dopamine receptors in the mesolimbic pathways

All effective antipsychotics block D2 receptors.
The affinity for these receptors correlates with
the effective dose of the drugs
Mechanism of action
Many antipsychotics also block serotonin 5HT2A and
5HT2C receptors

and may antagonise other receptors
α1 - adrenoreceptors

Histamine H1 receptors

This does not effect their efficacy in psychotic illness
but can produce unwanted side effects
Receptor affinities of some
antipsychotics

Note: some older FGA show some preference for D2 over D1
Some of the newer SGA agents are highly selective for D2
Indications
Acute and chronic psychosis

Acute mania & maintenance of bipolar disorder

Organic psychosis (e.g. dementia – associated agitation)

Severe behavioural disturbances in children

Tourette's syndrome & other chorea's

Some other indications
Adjunct in anaesthesia e.g. Droperidol
Adjunct in treatment of alcoholic hallucinations e.g. Haloperidol
Intractable nausea & vomiting e.g. Haloperidol, Droperidol
Intractable hiccup (if non-drug treatment fails) e.g.
Chlorpromazine
Common adverse effects
All antipsychotics have
Anticholinergic effects some degree of
Blurred vision anticholinergic activity
EXCEPT
Dry Mouth Amisulphride
Constipation
Aripiprazole
Paliperidone
Urinary hesitance or retention Risperidone
Ziprasidone
Sedation

Orthostatic hypotension – due to the blockade if the Alpha-
receptors which may lead to syncope and falls

EPSE

*as with all medications there are individual differences in
tolerability and occurrence of adverse effects
Common adverse effects

http://www.uspharmacist.com/content/c/10207/?t=alzheimer%27s_and_dementia,psychotropic_disorders
Common adverse effects
Extrapyramidal effects (EPSE)

Acute dystonia

Muscle spasm of face, neck, tongue, jaw and/or hands

Hyperextension of the neck & trunk, arching of the back

Can interfere with walking, talking or swallowing

Dystonia's include
Torticollis
Carpopedal spasm
Trismus
Perioral spasm
Oculogyric crisis
Common adverse effects
Drug induced Parkinsonism

Similar to Parkinson’s Disease
Shuffling gait
Drooling
Tremor
Increased rigidity (cogwheel) or
Bradykinesia
Akinesia has also been reported

Usually develops after week-months of treatment
Usually reversible

Treated with anticholinergics or using an alternative
medication
Common adverse effects
Akathisia

Motor restlessness

Person feels unable to sit/stand still, feels
urgent need to move, pace, rock or tap foot

Can also present at apprehension,
irritability & general uneasiness

Often confused with worsening agitation

More common in females

Usually occurs 2-3 days (up to several
weeks) after starting treatment and may
subside spontaneously
Common adverse effects
Tardive Dyskinesia

Characterised by abnormal movements of
the mouth, face, tongue
Lip smacking
Tongue darting, licking movements
Constant chewing movements
Sucking
Grunting
Sometimes abnormal movements head,
neck trunk or limbs
May appear after medium to long term
treatment
May be irreversible/no cure
Common adverse effects
Endocrine effects

More common in women

Due to dopamine receptor blockade – leads to  prolactin release
which may cause
Gynecomastia
Galactorrhoea
Amenorrhoea
Anovulation
Impaired spermatogenesis
 libido
Impaired sexual arousal
Impotence
Anorgasmia
Common adverse effects
Effect due to hyperprolactinaemia
Dose dependent
Associated with all antipsychotic drugs except
Aripiprazole
Clozapine
Quetiapine

Hyperprolactinaemia more likely with
Amisulphride
Paliperidone
Risperidone
Typical antipsychotics
Common adverse effects
Weight Gain

Most antipsychotics can cause weight gain
Especially – Clozapine, Olanzapine and Quetiapine

Less in – Amisulpride, Aripiprazole, Ziprasidone

http://primarypsychiatry.com/augmentation-strategies-in-the-treatment-of-major-depressive-disorder/
Common adverse effects
Metabolic Syndrome

Schizophrenia and other mental illnesses are an
independent risk factor for diabetes

Most antipsychotics increase this risk

Clozapine and Olanzapine are especially associated
with
Abnormal glucose tolerance
 Serum lipids
Infrequent or rare adverse effects
Neuroleptic Malignant Syndrome

Rare
Coarse tremor
Catatonia

Potentially fatal

Characterised by
Fever (>38oC)
Marked muscle rigidity
Altered consciousness
Autonomic instability (tachycardia, tachypnoea, urinary &faecal
incontinence
 serum creatine kinase concentrations and leucocytosis
Infrequent or rare adverse effects
ECG changes

Some antipsychotics can prolong the QTc interval which can
lead to life threatening arrhythmias (torsades de pointes)
Especially: Amisulphride, Droperidol, Haloperidol, Ziprasidone

Certain individuals are more susceptible
Age/gender (female)
Left ventricular failure
Recent cardio conversion
Electrolyte imbalances
Hypomagnesaemia
Hypokalaemia
Hypocalcaemia
Hepatic dysfunctions https://www.kg-ekgpress.com/ecg_web_brain_DEMO_-_chapter_7_-_qt_interval/
Pharmacokinetics
Most antipsychotic drugs are
Highly lipophilic

Highly protein bound

Relationship between plasma
concentration and effect is highly
variable – therefore need to tailor
the dose
40% non response rate
Some have erratic and
unpredictable absorbency

Diagram shows range of peak plasma concentrations v’s dosages in 14 patients
Note: one patient showed no response
Pharmacokinetics
Most antipsychotic drugs
enter foetal circulation and
breast milk, therefore
should be avoided in
pregnancy
Neonatal side effects
include
Dystonic reactions
Sedation
Withdrawal

Most have long half lives
(t1/2)
Dosage forms
Tablets
Capsules
Liquid preparations
Depot injections
Fluphenazine (Modecate®)
Haloperidol (Haldol®)
Fluphenthixol (Fluanxol Depot®)
Zuclopenthixol;
Zuclopenthixol Acetate (Clopixol Acuphase®)
Zuclopenthixol deconoate (Clopixol depot®)
Parenteral
Haloperidol
Droperidole (Droleptan®)
Chlorpromazine (Largactil®)
Dosage forms
Clozapine
Used in treatment of patients non responsive to,
or intolerant of other antipsychotics

Able to relieve +ve and –ve symptoms

Antagonist at D1, D2, D4 and 5HT2 receptors

Cancause profound orthostatic hypotension
accompanied by cardiac or respiratory failure.

Therefore need medical supervision &
resuscitation facilities when started
Clozapine
Associate with severe side effects;
Blood Dyscrasias
Other side effects
Hyperpyrexia (5%)
Nausea and vomiting
Drowsiness (40% of treated people)
Tachycardia
Hypersalivation (can cause aspiration pneumonia)
Weight gain
Seizures
Priapism
Clozapine
Precautions;
Parkinson’s disease
Epilepsy
Respiratory failure
Hypothyroidism
Shock
Closed angle glaucoma, increase intraocular pressure,
GI obstruction
Urinary retention
Low WCC or previous blood abnormality
Elderly require lower starting doses
Anticholinergic Drugs
Anticholinergic Drugs
Anticholinergic drugs can be used to treat a variety of
conditions.

Many different types of anticholinergic drug, but they
all work by blocking the action of acetylcholine, a type
of neurotransmitter. Blocking this neurotransmitter
inhibits involuntary muscle movements and various
bodily functions.

Anticholinergics are regularly used in
psychiatric practice to counteract the extrapyramidal
symptoms secondary to antipsychotic drugs

Some extrapyramidal side effects (e.g. drug induced
Parkinsonism, akinesia, dystonia) may be decreased
by anti-parkinsonian drugs with anticholinergic action
Anticholinergic Drugs
Anticholinergic drugs block muscarinic receptors &
reduce relative excess of cholinergic activity that
accompanies dopamine deficiency

Drugs Include
Benztropine
Benzhexol

Biperidin

Orphenadrine
Antidepressants
Monoamine theory of depression
States that depression is caused by functional deficit of
monoamine transmitters at certain sites in the brain, while
mania results from a functional excess

Early observations found that
Depletion of monoamines NA and 5HT in the neuronal
synapses of the brain cause depression
Drugs that ↑ the availability of these monoamines would be
effective in relieving depression
Monoamines & their metabolites are reduced in depressed
patients

*Interestingly, the direct biochemical effect of antidepressants is
rapid BUT the antidepressant effects can take weeks to develop
Antidepressants
Monoamine theory of depression
Tricyclic antidepressants (TCAs)

Monoamine Oxidase Inhibitors (MAOIs)

Selective Serotonin Reuptake Inhibitors (SSRIs)

Other antidepressants
Duloxetine (Cymbalta®)
Mianserin (Lumin®)
Mirtazapine (Avanza®)
Moclobemide (Aurorix®)
Reboxetine (Edronax®)
Venlafaxine (Efexor®)
Sites of action of antidepressants
Selectivity of monoamine uptake inhibitors
for Noradrenaline (NA) & Serotonin (5HT)
Tricyclic antidepressants
Mode of action:

Block amine pump i.e. block
the neuronal reuptake of
noradrenaline and serotonin
into presynaptic terminals.

Also block other receptors
Alpha1 adrenergic
Histaminergic
Cholinergic
Serotonergic
Tricyclic antidepressants
Indications:

Major depression

Nocturnal enuresis, urge
incontinence

Adjunct in pain management

ADHD (third line treatment)

Migraine prophylaxis

Clomipramine also indicated for
Obsessive-compulsive disorder
Cataplexy associated with
narcolepsy
Tricyclic antidepressants
Common adverse effects
these appear early by therapeutic response is usually delayed

Anticholinergic effects Sedation
Dry mouth Due to H1 block
Blurred vision Tolerance develops with time
 Lacrimation Orthostatic hypotension
Constipation (esp. in elderly) Due to α1 block
Urinary hesitance or retention Others
 GI motility Loss of libido and other sexual side
effects
Anticholinergic delirium
Tremor
Confusion
Dizziness
Agitation
Anxiety
Common adverse effects - TCAs
Infrequent adverse effects - TCAs
Cardiovascular effects
Slowed cardiac conduction Especially in high doses
T wave inversion pr flattening
Arrhythmias
Sinus Tachycardia

Others
Hyperglycaemia
Gynaecomastia in males
Breast enlargement & galactorrhoea in females
Manic episodes
TCA Overdose
Cardiovascular toxicity
Leading cause of death in OD
Death have occurred in children with
low doses

TCAs have a direct cardiac
depressing action similar to class 1
antiarrhythmics

Cardiac toxicity & hypotension –
difficult to manage

ECG
QRS complex is prolonged
QT interval is prolonged due to
prolongation of the QRS complex
Withdrawal Syndrome
TCAsmust be withdrawn slowly to avoid
discontinuation syndrome

May develop Cholinergic rebound
Runny nose
Hypersalivation
Diarrhoea
Abdominal cramping
Sleep disturbances
Monoamine Oxidase Inhibitors (MAOI)
Include
Phenelzine (Nardil®)
Tranylcypromine (Parnate®)

Mode of action
Bind irreversibly to
monoamine oxidase
(enzyme), responsible for
the breakdown of the
biogenic amine
neurotransmitters;
Noradreanline
Dopamine
Serotonin
Monoamine Oxidase Inhibitors (MAOI)
Indications:
Major depression (2nd Line)
Some anxiety disorders (including phobic and panic disorders (2nd Line)

Common Adverse effects
Orthostatic hypotension
Weight gain
Sleep disturbances (especially insomnia – not given after 3pm)
Agitation
Impotence
Rare
Hypertensive Crisis
Monoamine Oxidase Inhibitors (MAOI)
The most important side effect is HYPERTENSIVE CRISIS (which may
result in death)

A sudden paroxysmal rise in in BP may occur
It is usually associated with foods containing tyramine (or some
drug interactions)

The metabolism of some amine drugs e.g. Sympathomimetic
drugs, is inhibited by MAOIs; may lead to a dangerous rise in BP
which may lead to intracranial bleeding and death.

Sympathomimetics are found in many cough mixtures and
decongestants including nasal drops
Phenyephrine e.g. Demazin®
Pseudoephedrine e.g. Sudafed®
Dextromethophan e.g. Benadryl dry®
Monoamine Oxidase Inhibitors (MAOI)
Foods rich in tyramine may elicit the reaction
Tryamine found in many foods (Particularly foods that contain
aged proteins)
Matured cheese
Yeast extracts e.g. Vegemite
Pods and broad beans
Fermented or aged foods such as salami, pate, dried sausage
Red wine, beer
Sour cream
Soy bean extracts e.g. Tofu
Causes release of certain biogenic amines in the body
Since MAOIs inhibit the breakdown of the amines →↑ BP
→Death
Danger of interaction persists 2-3 weeks after MAOI
discontinued
Monoamine Oxidase Inhibitors (MAOI)
Moclobemide (Aurorix®)
Competitively & reversibly inhibits monoamine oxidase
Not related to other antidepressants

Original MAOIs act non-selectively on MAO-A and MAO-B
Irreversible inhibition

Moclobemide is relatively selective for type A Monoamine
oxidase

Moclobemide  the metabolism of Noradrenaline, serotonin &
dopamine   concentrations of these neurotransmitters.
Moclobemide (Aurorix®)
Indications
Mood disorders, panic disorders and social phobia

Advantages
Not sedative
Low tryamine diet not usually required
Relatively nontoxic in overdose & less likely to cause
sexual dysfunction than MAOIs

Common side effects
Nausea, dry mouth, constipation, diarrhoea, anxiety,
restlessness, insomnia, dizziness & headache.
Selective Serotonin Reuptake Inhibitors
(SSRIs)
Include
Citalopram (Cipramil ®)
Escitalopram (Lexapro®)
Fluoxetine (Lovan®, Prozac®)
Fluvoxamine (Faverin®, Luvox®)
Paroxetine (Aropax®)
Sertraline (Zoloft®)

Mode of Action
Selectively block the reuptake of serotonin into presynaptic
terminals.

Have little affinity for
dopamine, acetylcholine, histamine or adreno-receptors
Selective Serotonin Reuptake Inhibitors
(SSRIs)
Indications
Mood disorders (Major Depression)
Anxiety disorders (OCD, Panic disorder)
Bulimia nervosa
Premenstrual dysphoric disorder

Common side effects
Nausea, diarrhoea, tremor, agitation, headache, sweating,
insomnia, drowsiness, weight loss or gain, sexual
dysfunction, rhinitis

* Less cardiovascular, anticholinergic & sedating
adverse effects than TCAs
SSRI comparative information
Selective Serotonin Reuptake Inhibitors
(SSRIs)
Serotonin Syndrome
Serotonin toxicity due to  serotonin concentrations at
synapse  hyper-stimulation of 5HT receptors

Symptoms – a clinical triad of abnormalities

Cognitive effects
Mental confusion, hypomania, hallucinations, agitation

Autonomic effects
Fever, hypertension, tachycardia, nausea

Somatic effects
Muscle twitching, hyper-reflexia
Serotonin Syndrome - (SSRIs)
May occur if
Changing antidepressants with inadequate ‘washout’ period
High dose of single drug
When more than one serotonergic agent used together

Serotonin toxicity
Warrants stopping implicated agent promptly
May be serious
Deaths have occurred

Potential interactions
Numerous and difficult to predict
May inhibit liver cytochrome P450 enzyme that metabolises
many drugs e.g. Fluoxetine inhibits CYP2D6 which effects the
metabolism of metoprolol etc.
Selective Serotonin Reuptake Inhibitors
(SSRIs)
Should not be given with
reversible or irreversible MAOIs
May cause serotonin toxicity

If transferring from SSRI to
reversible MAOI must let at
least 5 half lives elapse before
MAOI started
Selective Serotonin Reuptake Inhibitors
(SSRIs)
Taper slowly over several weeks

Symptoms of withdrawal
Nausea
Dizziness
Anxiety
Paraesthesia
Agitation
Sweating
Tremor
Confusion
Electric shock like sensations

Withdrawal symptoms more likely with Paroxetine & least
likely with Fluoxetine
Mianserin
Indication - Major depression
Tetracyclic antidepressant that shares most TCA
properties

Mode of action
Antagonist
α1-adrenergic
H1 – histaminergic
Serotonin receptors
Has little anticholinergic effect

Common side effects
Sedation, dry mouth, dizziness, vertigo
Can cause weight gain, blood dyscrasias (neutropenia,
agranulocytosis)
Mirtazapine (Avanza®,
Mirtazon®)
Indication - Major depression
Closely related to Mianserin in structure so should be
avoided in patients intolerant to Mianserin
Mode of action
Blocks post-synaptic serotonin 5HT2A, 5HT2c and 5HT3
receptors
Blocks pre-synaptic central α2-adrenergic inhibitory
receptors

Common side effects
Sedation, weakness, increased appetite, weight gain,
peripheral oedema
Reboxetine (Edronax®)
Indication - Major depression

Mode of action
Inhibits noradrenaline reuptake
Weakly inhibits serotonin reuptake

Common side effects
Urinary retention, insomnia, constipation, dry mouth,
headache, paraesthesia,  in diastolic BP,  heart
rate, sweating
Venlafaxine (Efexor®)
Indications - Major depression, generalised anxiety,
social phobia, panic disorder

Mode of action
Inhibits serotonin and noradrenaline reuptake

Common side effects
Sweating, dizziness, anorexia, anxiety, nausea, rash,
tremor, vomiting, hypertension

More toxic than SSRIs in overdose – may cause
arrhythmias, ECG changes & seizures, fatalities have
occurred
Adverse effects of Antidepressants
Adverse effects of Antidepressants
General Principles
Evidence suggest that all are approximately equal in efficacy
but response can vary markedly in patients

First line drugs
TCAs
SSRIs
Mirtazapine Moclobemide

TCAs, MAOIs and Venlafaxine more toxic in overdose than
other first line treatment

TCAs & Mirtazapine often cause weight gain

Some improvement in symptoms in 1-3 weeks but full
antidepressant effect in 6-8 weeks
Drugs used in Bipolar disorder
Drugs used in Bipolar disorder
Mood stabilisers
Lithium
Only specific anti-mania drug known
Is drug of choice for treatment & prophylaxis of acute mania
Carbamezepine, Sodium Valporate

Antipsychotic drugs (may be used alone or in combination with
BDZ)
Note: Haloperidol, Zuclopenthixol, Olanzepine and Quetiapine
approved for use in acute mania

If patients unresponsive to drug treatment – electroconvulsive
therapy may be useful
Lithium – adverse effects
Common
Metallic taste
Diarrhoea
Epigastric discomfort
Polyuria
Weight gain
Oedema
Skin reactions e.g. acne
Hypothyroidism

Infrequent
Nephrogenic diabetes insipidus with polydipsia and polyuria

Rare
Hyperthyroidism
Lithium - Overdose
Warning symptoms of lithium intoxication include;
Extreme thirst, frequent urination, nausea and vomiting
 anorexia
Diarrhoea
Drowsiness
Ataxia
Tinnitus
Blurred vision Dysarthria
Course tremor

Treatment
Not specific antidote for lithium poising
Lithium treatment should be stopped and steps taken to reverse
toxicity
Serum levels monitored
Lithium
Cause of high blood levels
Excessive dosage
 lithium excretion
 Sodium
 Sodium loss – vomiting, diarrhoea, fever, Thiazide diuretics
(e.g. chlorothiazide, hydrochlorothiazide)
Dehydration

Drug Interactions
Blood levels or lithium are increased by;
Thiazide diuretics, anti-inflammatory drugs and ACE inhibitors
Blood levels are decreased by;
Sodium salts (e.g. Sodium bicarbonate – found in indigestion
medications e.g. Salvital, ural, citravescent)
Hypnotics and Sedatives
Hypnotics and Sedatives
Medications to treat insomnia and anxiety
Difficulty falling asleep or in staying asleep or
disturbed sleep patterns → insufficient sleep

Drug used to treat insomnia
Hypnotics

Anxiety may be due to
A physical disorder (e.g. hyperthyroidism) or
Use of legal or illicit drugs (e.g. corticosteroids, cocaine)

Drugs used to treat symptoms of anxiety
Anxiolytics (or sedatives)
Sedatives & Hypnotics
Examples
Benzodiazepines
Zolpidem
Zopiclone
Chloral hydrate
Ethanol
Barbiturates

Sedationis a side effect of may drugs that are
not general CNS depressants:
Classical antipsychotics
Antihistamines
Gamma-Aminobutyric Acid (GABA)
GABA is main inhibitory transmitter in brain
Occurs fairly uniformly throughout brain tissue (very
little in the peripheral tissues)

Formed from glutamate
by the enzyme glutamic acid decarboxylase (GAD)
This enzyme is found only in GABA-synthesising
neurons

http://what-when-how.com/molecular-biology/gamma-aminobutyric-acid-gaba-molecular-biology/
Gamma-Aminobutyric Acid (GABA)
Action of GABA is terminated
mainly by uptake into the nerve
terminals but also by
deamination
By GABA-transaminase (inhibited
by Vigabatrin which is used in
epilepsy)

GABAA receptors are the target
of a number of important
centrally acting drugs including
Benzodiazepine
Barbiturate

http://what-when-how.com/molecular-biology/gamma-aminobutyric-acid-gaba-molecular-biology/
Benzodiazepine – Mode of action
Benzodiazepines
Promote the binding of major inhibitory neurotransmitter
GABA in the GABAA subtype of GABA receptors
Bind with high affinity to an accessory site
(Benzodiazepine BNZ receptor) on the GABAA receptor in
such a way that they
Promote the binding of GABA &
Enhanced the GABA-induced ionic currents through the chloride
channels

http://www.arnoldgroup.org/Research-GABA%20Receptor.html
Benzodiazepine – Mode of action
Benzodiazepines appear to  the efficiency of GABA
minergic synaptic inhibition by facilitating the frequency of
opening of GABA-activated chloride ion channels
Results in a  in the firing rate of critically important neurons in
may regions of the brain.

Benzodiazepines do not substitute for GABA i.e. they are not
GABA-receptor agonist

http://www.arnoldgroup.org/Research-GABA%20Receptor.html
Benzodiazepines
Indications
Anxiety

Insomnia

Panic disorders

Acute behavioural disturbance

Seizures

Muscle spasms

Acute alcohol, barbiturate and benzodiazepine withdrawal

Sedation procedures
Comparative information
Benzodiazepines can be categorised into different groups
Very short acting (HL< 6 hours) Medium acting (12-24 hours)
Midazolam (Hypnoval®)  Bromazepam (Lexotan®)
Triazolam (Halcion®)  Lorazepam (Ativan®)

Short acting (HL 6-12 hours) Long acting (HL > 24 hours)
Alprazolam (Xanax®)  Clobazapam (Frisium®)
Oxazepam (Murelax®,  Cloanazepam (Paxam®,
Serepax®) Ribotril®)
Temazepam (Normison®,  Diazepam (Valium®)
Temaze®)  Flunitrazepam
(Hypondorm®)
 Nitrazepam (Aldorm®,
Mogodon®)
Benzodiazepines
Withdrawal Symptoms
Anxiety
Insomnia
Nightmares
Irritability
Dysphoria
Sweating
Hallucinations
Tremors
Tachycardia
Hypertension
Psychosis
Seizures
Benzodiazepines
Withdrawal Symptoms
Shorter acting BDZ are more likely to lead to acute withdrawal
Symptoms
High doses of BDZ used over a prolonged period can lead to more
severe symptoms after discontinuation (agitation, depression,
panic, & myalgia)

Some symptoms
May be similar to original complaint
May continue for weeks/months

BDZ best reserved for short term use
2 – 4 weeks
Should be part of broader treatment plan

Long term use can result in tolerance and dependence
Drug seeking behaviour, craving etc.
Drug interactions
Additive CNS depression with drugs that act as CNS
depressants;
Alcohol

Antihistamines

Antidepressants

Antipsychotics

Opioid analgesics
Benzodiazepine receptor antagonist
In overdose
BDZ → prolonged sleep, without serious depression of
respiration or cardiovascular function

When taken with other CNS depressants
Can cause severe, sometimes life threatening respiratory
depression
Non-Benzodiazepine Anxiolytics
Buspirone (Buspar®)
Partial agonist at the 5HT1A receptor

Indication - Anxiety

Alternative where long term treatment is needed and BZD not
desirable – less potential for dependence
Concurrent use of BDZ  the efficacy of Buspirone

Does not prevent BDZ withdrawal

Optimal effect may take 2 weeks

Common side effects – light headedness, dizziness, nausea,
headaches, nervousness, excitement

NOTE: Need to avoid grapefruit – may  risk side effects
Non-Benzodiazepine Anxiolytics
Zolpidem (Stilnox®)
Indication – Short term treatment of insomnia
Potentiates the inhibitory effect of GABA
Is not a BDZ
Adverse effects
Common – diarrhoea
Rare – paradoxical symptoms e.g. worsening insomnia,
irritability, agitation

Its
Potential for tolerance, dependence or abuse is
not clear
Non-Benzodiazepine Anxiolytics
Zopliclone (Imovane®, Imrest®)

Indication – Short term treatment of insomnia

Potentiates the inhibitory effect of GABA in the
brain

Adverse effects
Common – taste disturbance (bitter), dry mouth

Should be used short term
Non-Benzodiazepine Anxiolytics
Diphenhydramine (Snuzaid Gels®, Unisom®,
Sleepgels®)
Over the counter, 50mg nocte
Injection of content of capsules (drug mis-users) may
cause phelebitis, infection, more serious local effects

Promathazine

Doxylamine
 Anticonvulsants
(also known as antiepileptics)
Anticonvulsants
Anticonvulsants (Antiepileptic's) are used to control or prevent
seizure disorders while minimising unwanted side-effects
Aim for monotherapy (one medication)

introduced slowly

Trial and error (75% seizure free while 25% resistant)

Desirable features
highly effective with low toxicity

long-acting and non-sedating

not highly protein-bound

inexpensive

not resulting in tolerance
Anticonvulsants
Mechanism of action;

Enhance GABA inhibition (e.g. benzodiazepines) or inhibit GABA
transaminase (Vigabatrin, Tiagabine and Topiramate)

Inhibit sodium channel function to stabilise the cell membrane
(Phenytoin, Carbamazepine, Sodium Valproate and Lamotrigine)

Inhibit calcium channel function or ‘calcium conductance’
(Ethosuximide)

Raise brain levels of GABA (Gabapentin)
Anticonvulsants
Efficacy
Different medications are more effective for treating specific
seizures
Anticonvulsants
Side effects

Behavioural and cognitive effects
Anticonvulsants
Other common side effects
Depression of cardiovascular and respiratory system

Enhance metabolism of Vitamin D – reduced bone mineral
density

Gastrointestinal effects

Haematological effects
Lithium
NOTE: Long term use of lithium in therapeutic concentrations
thought to cause histological and functional changes in
kidney. Therefore should perform renal and thyroid function
tests at baseline, then every 3-6 months
Patient education
Need to watch for signs of Lithium toxicity (e.g. extreme
thirst and frequent urination, nausea and vomiting),
especially during illness, excessive sweating or low fluid
intake. If occurs – stop treatment STAT
In general do not cease treatment abruptly – withdraw
gradually to avoid relapse
Take with food and consume more fluid (non-alcohol) during
hot weather to avoid toxicity.
Definition
Head injury
Broad category that may involve damage to other
structures such as the scalp and skull

Traumatic Brain Injury

An insult to the brain caused by mechanical force.

The spectrum of Intracranial Injury results from:
Direct Forces = Object Striking or penetrating
cranium
Indirect Forces = Acceleration/Deceleration or
Rotational Mechanism
Traumatic brain injury
The brain is susceptible to injury by trauma, ischemia, tumours,
degenerative processes, and metabolic alterations.

Brain injuries are classified as:

Non-traumatic (i.e., stroke, infection, tumour, or seizure).

Traumatic (i.e., epidural hematoma, subdural haematoma,
concussion, or diffuse axonal injury)

Brain damage can result from the effects of ischemia, excitatory
amino acids, oedema, and increased intracranial pressure
(ICP).

Brain injuries can cause a change in the level of consciousness
and alterations in cognition, motor, and sensory function
Classification of Traumatic Brain Injury

Blunt / Penetrating (Closed / Open)

Severity

Focal / Diffuse

Primary / Secondary
Brain injury
Primary brain injury

Primary damage resulting from these external forces

Diffuse axonal injury

Focal contusion

Haematomas, or bleeding, in or around the brain

Secondary brain injury

Occurs hours or days after initial traumatic event.

Injury may result from impairment or local decline in cerebral
blood flow.
Secondary brain injury
Systemic and intracranial effects that follow the initial injury.
Survival of severe brain injury is dependent on avoiding or minimizing the
secondary insults to the brain.

Systemic effects include:
Hypotension/hypertension
Hypoxia
Anaemia
CO2 changes
Electrolyte/glucose/acid-base abnormalities

Intracranial effects include:
Ischemia
Oedema
Hydrocephalus
Infection
Seizure
Haemorrhage
Traumatic brain injury
The brain is enclosed in the protective confines of the
rigid bony skull.

Although the skull generally affords protection to the
soft tissues of the CNS from external forces, it also
imposes risks as a source of injury from internal forces.

The bony structures of the skull can induce traumatic
and ischemic brain injuries when intracranial tissues
increase in volume (swelling or bleeding) or shift
(swelling or mechanical trauma).
Fractures of the skull can compress sections of the
nervous system and cause penetrating wounds
Sequelae of Head Injury
The prognosis for concussion (mild TBI) is generally good if
appropriately managed.

However, there are a variety of short – long-term sequelae.

Second impact syndrome

Post-concussion syndrome

Post-traumatic epilepsy
Sequelae of Head Injury
Second Impact Syndrome

Rare, Controversial entity

Athlete who has sustained a mild concussion who subsequently
suffers a second head injury before the symptoms from the first have
resolved

Patients subsequently develop rapid diffuse cerebral edema (within 2
min), increased ICP, and eventual herniation, coma, and death

The first head injury is postulated to cause a disruption of the normal
cerebral vascular autoregulation that causes increased cerebral
blood flow, making the brain vulnerable to the second impact, when
the rapid malignant swelling occurs

Return-to-play guidelines have been developed to prevent this type
of secondary injury
Sequelae of Head Injury
Post-Concussive Syndrome
Constellation of symptoms that develops within 4 weeks of the
injury and may persist for months (90% at 1 month, 25% at 1
year)
Treatment is generally symptomatic

Post-traumatic Epilepsy
Seizure activity > 7 days from traumatic injury
Head trauma is the cause of long-term epilepsy in 3% of patients
with epilepsy
Incidence is highest in patients with a compound skull fracture,
intracranial hemorrhage, or presence of early acute symptomatic
seizure (presence of all 3 factors increases risk by 50-80%)
Cannot be prevented with prophylactic use of anticonvulsants
Skull Fractures
Skull Fracture = High Degree of Energy
Classification:
Location
Pattern of fracture
Open vs. Closed
Location may indicate an underlying injury
Depressed skull fracture - Often tear underlying
dural tissue
Fracture over pteryion - Middle Meningeal Artery =
epidural haematoma
Fracture over dural sinus - Subdural Hematoma

Skull fracture increases the risk of intracranial bleeding
Skull fractures
A linear skull fracture is a
break in the continuity of the
bone.

A comminuted skull fracture
refers to a splintered or
multiple fracture line.

Compound fracture (Open
fracture)

When bone fragments are
embedded into
the brain tissue, the fracture is
said to be depressed.

A fracture of the bones that
form the base of the skull is
called a basilar skull fracture
Fractures in young children

Image source: http://caringforspecialneedskids.com/infant-
skull-fracture/
Types of skull fractures
Linear Fractures:
The most common simple type.

Seen in the temporal parietal region.

Often accompanied by an overlying haematoma.

They require no specific treatment and will heal well.
A very small minority may develop into a "growing skull fracture"
Types of skull fractures
Depressed skull fractures
May be seen with or without a cut on the scalp

Part of the skull is actually sunken in from the trauma.

If the inner part of the skull is pressed against the brain,
surgical intervention is needed to help correct the deformity.

Image source:
http://slu.adam.com/content.aspx?prod
uctId=617&pid=1&gid=000060
Types of skull fractures
Basal skull Fractures:
Serious type of skull fracture, involving a break at
the base of the skull.
These may be difficult to see radiologically,
although the clinical suspicion should be high if
"battle's sign" / "raccoon eyes" or a CSF leak is
present.
Types of skull fractures
Diastatic Fractures:
These are caused by the traumatic separation of
the sutures most commonly lambdoidal.

Growing Fractures:
Seen in the toddler age group. Is generally
"diastatic" and it grows as the brain herniates,
through the torn dura up into the fracture site.
Generally present some time after the initial
injury, usually as a persistent swelling or
pulsatile mass.
There is almost always underlying parenchymal Head CT revealing an old
brain damage, with associated neurological skull fracture with herniation
of the underlying cortex in a
symptoms. 14th month female
Requires surgical repair of the dura.

Image source:
https://adc.bmj.com/content/101/Suppl_1/A193.2
Focal brain injury
Coup/Contrecoup injury
In a head injury, a coup injury occurs under the
site of impact with an object, and a contrecoup
injury occurs on the side opposite the area that
was impacted.

Focal injury at gray matter closest to the brain
surface generates localized brain oedema and
disruption of normal neurological function.

Size of contusion defines the extent of the injury
Concussion
Symptoms can last for days, weeks, or even longer.
Common symptoms after a concussive traumatic brain injury are headache,
loss of memory (amnesia), and confusion.
The amnesia usually involves forgetting the event that caused the concussion.

Signs and symptoms of a concussion may include:
Headache or a feeling of pressure in the head
Temporary loss of consciousness
Confusion or feeling as if in a fog
Amnesia surrounding the traumatic event
Dizziness or "seeing stars"
Ringing in the ears
Nausea
Vomiting
Slurred speech
Delayed response to questions
Appearing dazed
Fatigue
Haematomas
Arise from vascular bleeding/injury

Occur in various compartments
depending on the location of the
ruptured vessel

Epidural, subdural and subarachnoid
spaces and in the brain tissue itself
(intracerebral haematoma).
Haematomas
Type Epidural Subdural
Location Outer layers of the dura mater, Between dura mater & pia
between the meninges & skull arachnoid mater.
Increased risk in elderly and
chronic alcohol use due to
decreased brain volume

Vessel involved Middle Meningeal Artery (36%) Bridging Veins

Symptoms w/ LOC + Lucid Intervals followed Gradually increasing headache
by deterioration and LOC again & confusion.
Classic presentation = 47% of
cases

CT scan image Lenticular Shape on CT Hyperdense crescent shaped
lesion
Haematomas

Epidural hematoma (EDH) Subdural hematomas (SDH)

http://www.unipa.it/~sparacia/rimg/caso1.jpg
Wikipedia
Epidural (extradural) haematoma
Usually occur in injury where the skull is fractured between in inner
bones of the skull and the dura
Usually from a tear of an artery (middle meningeal artery).
Brief post-trauma LOC - followed by a lucid interval (may last a few
hours), then rapid progression to unconsciousness
Focal symptoms - Ipsilateral (same side) pupil dilatation and
contralateral (opposite side) hemiparesis (from uncal herniation)

Treatment
Depends on location

Surgical ligation

Treatment aimed at reducing ICP

Seizure control
Subdural haematoma
Develops between the dura and arachnoid (subdural space) as
a result of a tear in small bridging veins that connect veins on
the surface of the cortex to dural sinuses
Subdural haematoma
Classified according to an approximate time before the
appearance of symptoms
Acute - within 24 hours

Subacute – 2 to 10 days

Chronic – several weeks
Acute subdural haematoma
Acute subdural haematomas progress rapidly – high mortality
due to secondary brain injury related to oedema and increased
ICP.

Presentation
Similar to epidural haematoma except for no lucid interval.

Treatment
Depends on size
Surgical evacuation
Prevention of secondary brain injury (ICP, Oedema, Seizures
etc.)
Chronic Subdural Haematoma
Presentation
Generally occurs in the elderly- head trauma may seem minor

Long-term alcohol use may be another risk factor

Starts as acute SDH - small clot covered by membrane- dark
fluid- like “motor oil”
Symptoms (minor): headache, confusion; progress to seizures,
hemiparesis & coma

Treatment
Evacuate clot

Prevent and manage secondary brain injury
Intracerebral haemorrhage
Intracerebral haematoma
bleeding into the brain tissue resulting
from contusions or blood vessel injury
(Craft et al, 2019)
Single or multiple – any lobe of the brain
(frontal and temporal lobes most common)
Occur as a result of severe motion during
traumatic head injury
More frequent in older people, and chronic
alcohol use (fragility of blood vessels)
Signs and symptoms depend on size and
location
Increased ICP if large and encroaching
vital structures
Treatment can be medical or surgical
Subarachnoid haemorrhage
Disruption of subarachnoid vessels
Common in moderate to severe brain injury
Worse prognosis
Twice as likely as other head injured patients to suffer death,
persistent vegetative state or severe disability

Image 2.
http://www.virtualmedstudent.com/links/neurologic
al/subarachnoid_hemorrhage.html
Diffuse injuries
Diffuse axonal injury -Widespread damage to the white
matter.

Results from shaking effect & associated with acceleration and
deceleration injury.

Ischemic brain injury from insufficient blood supply to the brain.
Is the leading cause of secondary brain injury.

Vascular injury usually causes death soon after injury.

Swelling commonly seen after TBI can lead to increased cranial
pressure
Diffuse Axonal Injury
Rotational Mechanism
Widespread shearing strain at the deep cerebral white matter that disrupts
normal axonal organization resulting in disruption of axonal fibers and
myelin sheaths
Generalized edema occurs after an injury, typically within 6 hours without
any focal lesion on CT imaging
Secondary Brain Injury
Indirect result of injury.

Arises from complications of injury

Systemic or Intracranial processes that contribute to the
primary brain injury cycle and result in greater tissue injury
Ischemia
Cerebral hypoxia
Hypotension
Cerebral oedema
Alternations in cerebral blood flow
Raised ICP
Herniation
Hypercapnia
Alterations in the release of neurotransmitters (Excitotoxicity)
Hydrocephalus
Image: https://www.barnesjewish.org/Newsroom/Publications/Innovate-
Physician/Innovate-Trauma-Level-1/Winter-2013/Preventing-Secondary-Brain-
Injury-in-the-Battlefield
Secondary Brain Injury
Systemic Insults

Hypoxia (PaO2 < 60 mmHg)
Mortality of TBI pts with hypoxia = doubled
40% of TBI ED patients exhibit hypoxia during the course

Hypotension (SBP < 90 mmHg)
Present in 33-35% of TBI patients
Results from hemorrhagic shock, cardiac contusion, tension pneumothorax, etc.
Hypotension → ↓Cerebral Perfusion→↑Cerebral Ischemia →↑Doubles Mortality

Anemia Blood Loss (↓Oxygen Carrying Capacity)
Secondary Brain Injury
Systemic Insults - Continued

Hypo/Hypercapnia
Hyperventilation is commonly used in neurological patients to
decrease elevated intracranial pressure
Hypocapnia may be induced in order lower ICP by decreasing the
Cerebral Blood Volume
It induces cerebral arterial vasoconstriction
However may cause regional ischemia
Therefore -restrict to short-term use & restore normocapnia as soon
as is feasible

Zhang, Z., Guo, Q., & Wang, E. (2019).
Secondary Brain Injury
Other Systemic Insults
Seizures
Electrolyte Abnormalities
Coagulopathy
Infection
Hyperthermia
Iatrogenic (Under-resuscitation)

Intracranial Insults
Severe intracranial hypertension, cerebral oedema & presence of
extra-axial lesions also worsens the outcome.

Patient comorbidities also impact the extent of secondary injury such as
patient age, other co-existing injuries and alcohol intoxication.
 Cycle of ICP
leading to
reductions in
cerebral contributes to decreases
Increased
perfusion ICP
pressure
Space occupying
lesions Cerebral
Hydrocephalus
Cerebral hemorrhage
blood flow

exacerbates decreases

Cerebral Perfusion
oedema pressure

manifests as
decreases

Blood flow
to the
Swelling affected
area of the
brain
results in

Infarction causes
of brain Ischemia
tissue
From: Craft, Gordon & Tiziani (2012) leads to
Brain injury
Brain is protected by the rigid confines of the skull and
the cushioning by cerebrospinal fluid (CSF).

However brain is still vulnerable to injury

Metabolic stability is maintained by:

Blood brain barrier

Autoregulatory mechanisms
Hypoxic and ischemic brain injury
The ability of cerebral circulation to deliver oxygen in sufficiently high
concentrations to facilitate the metabolism of glucose and generate
adenosine triphosphate (ATP) is essential to brain function
 Hypoxia – deprivation of oxygen with maintained blood flow

 Ischemia – greatly reduced or interrupted blood flow, thus
reducing delivery of oxygen & glucose and removal of metabolic
wastes.
Focal V Global ischemia
Focal ischemia Global ischemia
Region of the brain is under Blood flow to entire brain is
perfused (ischemia stroke) compromised.
Collateral perfusion may to Inadequate to meet metabolic
maintain a low level of metabolic needs.
activity
However, interruption delivery of Severe and prolonged ischemia
glucose under anaerobic conditions leads to infarction or death of cells
may lead to additional lactic acid of the brain.
production and depletion of ATP
stores. Reperfusion of injured tissue can
lead to secondary brain injury.
Global ischemic injury
Neurological deficits vary widely.

The symptoms of cerebral ischemia include:
weakness in one arm or leg
weakness in one entire side of the body
weakness on both sides of the body
dizziness, vertigo, double vision
difficulty speaking
slurred speech
loss of coordination

If the period of extensive:
Coma, fixed dilated pupils, and abnormal posturing.
May be a gradual improvement, but permanent deficits may persist.
Excitotoxic Brain Injury
Excitatory amino acids
Some neurological disorders (stroke, hypoglycaemia, and
trauma, Huntington’s, and Alzheimer's) are characterized by
overstimulation of amino acids – particularly glutamate

Excitotoxicity – excessive activity of excitatory
neurotransmitters and receptor-mediated activity (receptor-
operated ion channels)
 Excitatory amino acids
Glutamate

The role of the glutamate–N -methyl-D -aspartate (NMDA) receptor in brain cell injury.

Image: Porth, 2014
Normal Cerebral Autoregulation
Cerebral Autoregulation
Protective mechanism to maintain a tightly controlled
environment where fluctuations in systemic arterial pressure
or intracranial pressure do not have a large impact on
cerebral blood flow.

Maintained by intact blood brain barrier, a specialized set of
endothelial cells with tight junctions.

Disruption of the blood brain barrier by traumatic injury may
impair normal cerebral autoregulation.
Normal Cerebral Autoregulation
Cranial Vault - fixed in size by outer rigid skull, it contains
80% brain tissue (consumes 20% of the body’s oxygen supply and
15% of cardiac output)
10% blood
10% Cerebrospinal fluid (CSF)

The metabolic stability required by its electrically active cells is
maintained by a number of regulatory mechanisms, including the
blood-brain barrier and autoregulatory mechanisms that ensure
adequate blood supply.

Normal fluctuations occur with respiratory movements, coughing, and
sneezing.
Cerebral blood flow
If blood pressure falls below 60mmHg, cerebral blood flow is
compromised.

Blood flow increases rapidly and overstretches the cerebral
vessels.

At least three metabolic factors affect cerebral blood flow: carbon
dioxide, hydrogen ion, and oxygen concentration.

Decreased oxygen concentration also increases cerebral blood
flow.

Decreased oxygen saturation increases cerebral blood flow, as
does an increased carbon dioxide level.

The body attempts to compensate by increasing blood flow to the
area.
Vascular autoregulation
Multiple factors can initiate these vasodilation or vasoconstriction
cascades

Systemic arterial pressure

Systemic blood volume

Blood viscosity

Oxygen level delivery

Metabolism

Hypo / hypercapnia

Pharmacologic agents
Increased Intracranial Pressure
Increased ICP is a common pathway for brain injury from
different types of insults and agents.

ICP is the pressure within the intracranial cavity and is
determined by.
Pressure–volume relationships among the brain tissue, CSF, and
blood in the intracranial cavity;
Monro-Kellie hypothesis, which relates to reciprocal changes
among the intracranial volumes;
Compliance of the brain and its ability to buffer changes in
intracranial volume.

Excessive ICP can obstruct cerebral blood flow, destroy brain
cells, displace brain tissue (herniation), and damage delicate
brain structures.
Intracranial pressure
The pressure-volume relationship between ICP, the volume of
CSF, blood, and brain tissue, and cerebral perfusion pressure
(CPP) is known as the Monro-Kellie hypothesis.

The Monro-Kellie hypothesis states that the cranial
compartment is incompressible, and the volume inside the
cranium is a fixed volume.

The cranium and its constituents (blood, CSF, and brain
tissue) create a state of volume equilibrium, such that any
increase in the volume of one of the cranial constituents
must be compensated by a decrease in volume of another.
Increased Intracranial Pressure
Medical emergency!

Most frequent cause of death &
disability after severe head injury

Remember Monro-Kellie hypothesis.

The body can temporarily compensate
when the volume of one of components
increases by shifting CSF or altering
blood volume through vasoconstriction.

If pressure is continuous, then unable
to compensate.

Normal ICP 5- 10 mmHg.
https://www.ausmed.com.au/cpd/article
s/increased-intracranial-pressure
Increased ICP
Limited cerebral blood flow due to decreased cerebral perfusion
from increased pressure.

Brain is being squeezed & which leads to ischemia

Swelling and oedema (if not treated) will lead to herniation
(displacement).

When CPP falls too low the body will try to compensate by
increasing systolic BP to increase blood flow to the brain. BUT this
makes things worse.

At this point, arteries will dilate due to the retention of carbon
dioxide. Causes more blood flow to the brain BUT will compress
veins and limit blood flow to the heart.

Therefore leads to more swelling and a further increase in ICP.
Signs & Symptoms of Increased ICP
Changes to the mental state
Restlessness, confusion, difficulty following instructions.
Changes to consciousness - Unconscious LATE sign.
Seizures
Headache
Changes to optic & oculomotor nerve may cause, papilledema,
changes to pupil size & response
Emesis (vomiting) without nausea projectile
Deterioration of motor function
Posturing. Decerebrate or decorticate posturing or flaccid
Reflex positive Babinski (toe fan out…abnormal)

Cushing’s Triad: LATE SIGN…herniation of the brain stem
Rising systolic pressure
Widening pulse pressure
Bradycardia
Cushing’s Triad
Cushing’s Triad = Acute entity is seen in severely head injured patients with
significant increased intracranial pressure and impending herniation.

Seen when increased ICP decreases the cerebral blood flow significantly.

A response is triggered that increases arterial pressure in order to overcome
the increased ICP

Characterized by:
Progressive Hypertension
Bradycardia
Irregular or impaired respiratory pattern

Image: https://www.pinterest.com.au/pin/374291419013800228/
 Increased Intracranial Pressure
Maintain or control cerebral perfusion
Increase Decrease rates (CPP) and control ICP
in ICP CPP
Decrease cerebral edema, lower
volume of CSF, or decrease cerebral
blood flow.

(Farrell & Dempsey, 2013)

Increase
in edema Decrease
& pressure CBF
on tissue

Increased
Ischemia
Nursing Interventions
Focus on preventing further increased ICP and monitoring ICP (if a
monitoring device is inserted).

Position head of the bed: 30 to 45 degree

Prevent HYPOXIA and HYPERCAPNIA
When blood oxygen levels drop or carbon dioxide levels increase,
vasodilation occurs and this increases intracranial pressure.
Monitor blood gases, oxygen level, suctioning as needed only (no
longer than 15 seconds…increase ICP) hyper-oxygenated before and
after.
Mechanical ventilation to keep PaCO2 low 30-35. Vasoconstriction
helps decrease ICP by decreasing blood flow.
Nursing Interventions
Monitor and manage fever
A high temp increases ICP, cerebral blood flow & metabolic needs of
the patient.
Keep patient cool (reduces metabolic needs) but prevent shivering,
(increases metabolic needs & ICP)

Monitor systems
Glasgow Coma Scale
Neuro obs
Monitor ICP (ventriculostomy (external ventricular drain).

Avoid straining activities. (vomiting, coughing, sneezing, stressful
activities, agitation)

Unconscious patient care
Treatments
Barbiturates

Decrease brain metabolism which decreases ICP

Vasopressors/IV fluids or antihypertensives
Maintain SBP greater than 90 but less than 150.

Anticonvulsants

Hyperosmotic drugs to manage oedema
Mannitol
Must be done carefully and watch BP & renal functioning.

Loop diuretics

Corticosteroids
Intracranial Monitoring
Indications
Severe TBI with GCS < 9 with
abnormal CT scan.
Intubated patients with moderate or
severe head injury with significant
intracranial findings on CT
Brain Herniation
Excessive ICP can obstruct cerebral blood flow, destroy brain cells, displace brain
tissue (herniation), and damage delicate brain structures.

Protrusion (herniation) of brain tissue through one of the rigid intracranial barriers
(tentorial notch, falx cerebri, foramen magnum).

Brain herniation is classified based on the structure through which tissue is herniated:
Brain Herniation
Signs and Symptoms

Abnormal posturing - a characteristic positioning
of the limbs indicative of severe brain damage
Low level of consciousness (GCS 3-5)
One or both pupils may be dilated and fail to
constrict in response to light.
Vomiting can also occur due to compression of
the vomiting center in the medulla oblongata
Cerebral oedema
Increased brain tissue volume secondary to abnormal fluid
accumulation

May or may not increase ICP

Impact on the brain depends on the compensatory
mechanisms

Two types - vasogenic and cytotoxic edema

Treatment
Conservative if no increase in ICP
Localized edema often responds to corticosteroids or osmotic
diuretics
Cerebral Oedema
Cytotoxic Oedema Vasogenic edema

Actual swelling of the brain cells, When the integrity of the blood
increasing intracellular fluid brain barrier is disrupted
Impaired function of allowing fluid to escape into the
sodium/potassium pump extracellular fluid surrounding
brain cells - usually in white
Inadequate removal of
matter.
anaerobic metabolites e.g. lactic
acid, results in extracellular Occurs in tumors, prolonged
acidosis ischemia, haemorrhage and
brain injuries
Cell membrane rupture
damages neighboring cells -
leads to stupor, coma or
cerebral infarction
Cerebral oedema
 Hydrocephalus
Abnormal increase in CSF volume in any part of the
ventricular system

Due to decreased absorption or overproduction of CSF

Two types
Communicating

Noncommunicating

Porth, C. M. (2008).
(2005). Pathophysiology: Concepts of altered health states (8th
(7th ed.).
Communicating hydrocephalus
Occurs when full communication
occurs between the ventricles and
subarachnoid space

Caused by overproduction of CSF
(rarely), defective absorption of
CSF (most often), or venous
drainage insufficiency
(occasionally).

http://emedicine.medscape.com/article/1135286-overview
Noncommunicating hydrocephalus
Occurs when CSF flow is obstructed
within the ventricular system or in its
outlets to the arachnoid space,
resulting in impairment of the CSF
from the ventricular to the
subarachnoid space.

Commonly caused by obstruction by
a lesion

Image shows Horizonatal section of the brain from a patient who died of
a brain tumour that obstructed the aqueduct of Sylvius shows marked
dilation of the lateral ventricles.
Head Injury in children
Head injury is the leading cause of death in children > 1 year of
age

Head injury is the 3rd most common cause of death in children

Ratio of head injury, boys to girls is 2:1

Ratio of fatal head injury, boys to girls is 4:1.

(PCH, 2018)

Infants: commonly due to falls from heights, e.g.. from a bed,
couch, pram, change table, or downstairs.

School-aged children, sporting activities (Luckhoff & Starr,
2010)
Head Injury in children
Newborns Delivery head injury Caused by head compression and traction through
Intracranial haemorrhages the birth canal (vaginal delivery) with obstetric
Cephalic hematoma instruments.
Subgaleal haematoma A low birth weight and hypoxemia are risk factors
(extracranial) for intracranial haemorrhage.

Infants Accidental head injury Caused by inappropriate childcare practices.
Abusive Head Trauma If mechanism of injury is not clear, careful
consideration for diagnosis of child abuse is
required.

Toddlers & Accidental head injury Caused by accidents increase as children develop
school motor ability.
children With increase in use of child safety seats, the
severity of injury and the mortality has dropped.
Pedestrian injury also increases in this age group.

Adolescents Bicycle and motorcycle-related Awareness of prevention must be raised.
accidents Trainers and players those involved in contact
Sports-related head injuries sports - require education about concussion.

Injury characteristics according to age and development.
Table from Araki, T., Yokota, H., & Morita, A. (2016). Pediatric traumatic brain injury: characteristic
features, diagnosis, and management. Neurologia medico-chirurgica
Head injury in children
A child's behavior and symptoms after a head injury depend upon the type and
extent of the injury.

The most common signs and symptoms include:

Lacerations

Scalp swelling

LOC Return to play
Headache Children and adolescents who have sustained a
concussion are at risk for a serious or even fatal
Vomiting complication if they have a second head injury
within a short time after the first injury. e.g..,
second impact syndrome.
Seizures If suspected of having a concussion should be
removed from play (e.g., if
Concussion playing a team sport) and monitored for signs of
brain injury.

Patient education: Head injury in children and
adolescents (Beyond the Basics) - UpToDate
Assessment of head injury - Children
Examination CNS
 Full neurological examination.
Head
Penetrating injury
Depressed skull fracture Investigations
Large bruising or swelling X-ray skull
Panda eyes CT spine
Battles sign Bloods
Fundi
Papilloedema not seen acutely
Retinal haemorrhage in NAI
Pupillary reaction - equal, reactive, size

https://pch.health.wa.gov.au/For-health-professionals/Emergency-Department-
Guidelines/Head-injury
Assessment of head injury - Children
Mild head injury Moderate head injury Severe head injury

95% of HI are mild GCS 9-13 GCS < 9
GCS 14-15 AVPU = V AVPU = P or U
AVPU = A 3 or more vomits Seizures
No LOC Brief seizure after head injury Focal neurological deficit
Normal neurological Amnesia of event Raised ICP
examination LOC < 5 mines Penetrating head injury
Large scalp laceration, bruise or
abrasion (> 5cm in < 1 year old)
Drowsy
Features of basal skull fracture
Blood behind tympanic
membrane
CSF leak from ear/nose
Raccoon eyes
Battles sign
Open or depressed skull
fracture
High energy mechanisms

https://pch.health.wa.gov.au/For-health-professionals/Emergency-Department-Guidelines/Head-injury
Head injury in the elderly
Evaluation and diagnosis of TBI are challenging in older persons, especially
those with pre-existing dementia or cognitive disorders.

A pre-existing alteration in consciousness may confuse the diagnosis.

Common symptoms of brain injury—such as balance impairment, depression,
and cognitive deficits—may be misattributed to other causes, especially when
elderly patients experience a non-witnessed fall

The frequent use of anticoagulants for comorbid conditions leads to an
increased risk of haemorrhage, even with low-velocity head trauma.

High suspicion for intracranial haemorrhage

Some patients may present days or weeks after trauma, such as may occur
with subdural haemorrhage.

Filer, W., & Harris, M. (2015). Falls and traumatic brain injury among older
adults. North Carolina medical journal, 76(2), 111-114.
Assessment
Glasgow Coma Scale
Originally designed for measure 6 hours after injury to provide long-term
prognostic information about mortality and disability
Now, standardized to measure 30 min after injury and repetitive
measurements throughout patient’s stay
Should be performed after adequate resuscitation b/c scale is sensitive to
hypotension, hypoxia, intoxication, and pharmacologic interventions
Current Classification
GCS 14-15 - Mild Head Injury
GCS 9-13 - Moderate Head Injury
GCS < 9 - Severe Head Injury
Assessment
Neurologic Exam

Pupillary Size + Reactivity
Fixed Dilated Pupil - Ipsilateral Intracranial Hematoma
Bilateral Fixed + Dilated - Poor Brain Perfusion, bilateral
Uncas herniation or severe hypoxia
Indicative of very poor neurological outcome

Neurological Posturing
Decorticate Posturing - Upper extremity flexion with lower
extremity extension
Cortical Injury above the midbrain Image:
http://prehospitalresearch.eu/?p
Decerebrate Posturing - Arm extension and internal rotation =1683

with wrist flexion
Indicative of brainstem injury
Very poor predictor of outcome
Mild head injury
Clinical features- Signs and symptoms (early/late)
Signs and Symptoms of Head Injury
Cognitive Somatic Affective
Confusion Headache Emotional Lability
Anterograde amnesia Fatigue Irritability
Retrograde amnesia Disequilibrium Sadness
Loss of consciousness Dizziness
Disorientation Nausea/vomiting
Feeling “zoned out” Visual disturbances
Feeling “foggy” Photophobia
Vacant stare Phonophobia
Inability to focus Difficulty sleeping
Delayed verbal/motor Ringing of the ears
response
Slurred or incoherent speech
Excessive Drowsiness
Mild Head Injury Management
Symptomatic treatment and prevention of secondary injury

Appropriate management depends on an assessment of the risk of
neurological decompensation and risk factors for intracranial haematoma.

Risk factors for intracranial haematoma
Coagulopathy, Drug/Alcohol Intoxication, Previous neurosurgical
procedures, Pre-trauma epilepsy, or older age (> 60 y/o)

Low-risk patients can be d/c with instructions –if GCS is normal, neuro-
exam is normal, normal CT & no predisposition bleeding.

All patients with mild traumatic brain injury should be observed for 24 hours
after that injury (either inpatient or outpatient). Don’t have to keep the
patient awake.
Mild Head Injury Management
Discharge Instructions Warning Signs after
Appropriate follow-up instructions should be Discharge
provided both verbally and written Inability to awaken the patient
instructions. Decreased/ Altered mental
No need to awaken the patient every 2 hours status
Severe or worsening headache
Patients who return to ED due to persistent Somnolence or confusion
symptoms should undergo careful repeat
Restlessness, Unsteadiness
neurological evaluation but little data
supports repeat CT Scanning Seizure activity
Visual difficulties
“Return to play” guidelines Change in behavior
Return to sporting activities in a step-wise Vomiting, fever, neck stiffness
fashion
Urinary or bowel incontinence
Should not return to sporting events if they
Weakness or numbness
are still symptomatic
Moderate/ Severe Head Injury
Moderate Severe
GCS = 9-13 GCS < 9
Early aggressive treatment is required with
airway control, resuscitation, admission to
ICU setting
Outcome is poor with mortality as high as
60%

Clinical presentation varies widely Exam typically with abnormal exam, often
evidence of external trauma, abnormal
Specialized Subset = “Talk and Die pupillary exam and neurological deficits
Syndrome”

Cushing’s Triad
Moderate/ Severe Head Injury Management
General Principles
All moderate and severe head injured patients should undergo CT
imaging
Stabilisation and prevention of secondary insults is the mainstay of
treatment

Airway Management
Prevention of hypoxia and hypoventilation key to preventing
secondary insults
Patients with GCS < 9, should have endotracheal airway placed
Special attention should be paid to maintaining cervical spinal
immobilisation
Moderate /Severe Head Injury Management
Haemodynamic Assessment
Hypotension (SBP < 90) should be aggressively treated as a significant cause of
the worse outcome
Rarely, hypotension is due to head injury itself & other traumatic injuries should be
investigated
Treatment of hypotension is directed at the maintenance of cerebral perfusion
Hypotonic fluids are contraindicated
Typically isotonic fluids are used (NS)

Prevention of secondary brain injury by avoiding hypoxemia (O2 saturation 90

PaCO2 35-40

Systolic BP > 90

Head up 30°
Nursing interventions and management
Summary

Supportive care

Prevention of secondary brain juries

Restore homeostasis.

Mild TBI - serial neurological exams may be required for the first few days, with
neurology follow-up.

Moderate TBI- serial exams and cardiovascular monitoring may be required for
close observation.

Severe TBI - serial exams &
Cardiovascular monitoring
Intracranial monitoring
EEGs for potential seizure activity

Hickman, R., Alfes, C. M., & Fitzpatrick, J. (Eds.). (2018).
Nursing interventions and management
Outcome goals

Stabilisation of primary injury

Minimise secondary brain injury

Protect airway and adequate ventilation

Minimise metabolic needs of the brain

Maintain nutritional support

Seizure precautions

Mean arterial pressure sufficient to provide cerebral perfusion (CPP = 60–
70 mmHg)

ICPs maintained within normal limits

Normoglycemia, fever prevention, and normocarbia.
Anticholinergic Drugs
Peripheral side effects
Dryness of the mouth
Urinary hesitancy / constipation worsened
Dilation of pupils
Worsening of glaucoma
Central side effects
Dizziness
Euphoria
Hallucinations
Delirium (important in elderly)