Clinical Nursing Skills PDF

Summary

This document discusses the assessment of the neurological system, including structures, functions, and implications for nursing practice. It provides an overview of the central and peripheral nervous systems, along with clinical applications.

Full Transcript

CHAPTER 26
Assessment of the Neurological System

FIGURE 26.1 Nurses guide patients through cognitive exercises in order to assess their neurological health. (credit: "NMCSD recognizes
traumatic brain injury month" by Mass Communication Specialist 3rd Class Luke Cunningham/Flickr, Public Domain)

CHAPTER OUTLINE
26.1 Structure and Function
26.2 Physical Assessment
26.3 Recognizing Common Neurological Disorders

INTRODUCTION The neurological system is intricate and complex, and it affects all body functions. Nurses may
encounter an altered functioning neurological system in patients among various practice settings. Neurological
disorders may occur in anyone at any time and vary from mild to life-threatening. Therefore, it is essential for nurses
to understand the neurological system to adequately assess its proper functioning as well as the nursing
implications and interventions related to diagnosis and treatment.

26.1 Structure and Function
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Identify structures of the neurological system
Recognize functions of the neurological system
Recall effects of impaired function of the neurological system

The nervous system is the command center of the body. Many of the crucial jobs the nervous system undertakes
1204 26 Assessment of the Neurological System

happen automatically and regardless of our awareness, like a steady heartbeat and breathing pattern. At the same
time, the nervous system is also the seat of our consciousness. It is what allows us to explore the world through our
senses, process the input we get from the world around us and learn from it, and feel emotions in response to our
experiences.

When the nervous system operates as expected, the body is able to function. However, dysregulation within the
nervous system will lead to dysfunction and disturbance in the body, which may have a profound effect on a patient
physically and mentally.

The nurse needs to understand the complex anatomy, structure, and function of the nervous system to fully
appreciate the value of doing a neurological assessment. During the assessment, the nurse collects subjective and
objective data through an interview and detailed physical exam of a patient’s central nervous and peripheral
nervous systems.

Structures of the Neurological System
The neurological system consists of two parts: the central nervous system and the peripheral nervous system. The
nervous system transmits signals between the brain and the rest of the body to control motor, sensory, cognitive,
behavioral, and autonomic activities. In other words, the brain is the powerhouse that controls the ability to move,
see, breathe, and think. In addition, the nervous system monitors bodily processes and responds to stimuli to
maintain homeostasis and direct all physical, physiological, and biological activities.

Central Nervous System
The central nervous system (CNS) includes the brain and spinal cord. This nervous system is responsible for
receiving, processing, and responding to sensory information. The brain is the organ responsible for sensation,
movement, emotions, responses, thought processing, communication, and memory. The spinal cord sends motor
commands from the brain to the peripheral body. The spinal cord also relays sensory information from sensory
organs to the brain (Thau et al., 2022).

Brain
The major regions of the brain are the cerebrum and cerebral cortex, the diencephalon, the brain stem, and the
cerebellum. The largest portion of the brain is the cerebrum (Figure 26.2), and it is composed of the right and left
hemispheres, the thalamus, the hypothalamus, and the basal ganglia. The left and right hemispheres are in constant
communication with each other but are responsible for different behaviors, this is known as brain lateralization
(Figure 26.3). The left hemisphere is dominant for logic, language, and mathematical abilities. The right hemisphere
is more creative and intuitive and is dominant in musical and artistical situations (Thau et al., 2022). The major
communication pathway between the two hemispheres is the corpus callosum.

Access for free at openstax.org
 26.1 Structure and Function 1205

FIGURE 26.2 The cerebellum and the different lobes of the cerebrum. (attribution: Copyright Rice University, OpenStax, under CC BY 4.0
license)

FIGURE 26.3 The left and right hemispheres are connected via nerve fibers. The left hemisphere controls the right side of the body, and the
right hemisphere controls the left side of the body. (attribution: Copyright Rice University, OpenStax, under CC BY 4.0 license)

The cerebrum is covered by the cerebral cortex, a wrinkled outer layer of gray matter. The cerebral cortex is
responsible for higher functions such as emotions, memory, and consciousness and is divided into the lobes
described in (Table 26.1) (Thau et al., 2022).
1206 26 Assessment of the Neurological System

Lobe Location Function

Frontal Front of the Concentration, information storage (memory), abstract thought, and motor
brain function. The frontal lobe is also responsible for a person’s affect personality,
judgment, and inhibitions.
Broca’s area is located in this lobe and is essential for language and motor control
of speech.

Occipital Posterior to Responsible for visual interpretation and memory
the parietal
lobe

Parietal Posterior to Analyzes sensory information and relays the interpretation to other cortical areas,
the frontal and is essential to a person’s body awareness (size and shape discrimination,
lobe position in space, and right-left orientation)

Temporal Inferior to Plays a role in memory of sound and understanding music and language. The
the frontal auditory receptive areas are also contained in this lobe. Wernicke’s area is found
and here and plays a role in language comprehension (both written and spoken).
parietal
lobes
TABLE 26.1 Location and Function of the Lobes of the Cerebral Cortex

The diencephalon, or the interbrain, contains the hypothalamus and thalamus (Figure 26.4). It acts as a primary
relay and processing center for sensory information and autonomic control. The hypothalamus plays a role in the
endocrine system by regulating the pituitary secretion of hormones that affect metabolism, stress response,
reproduction, and urine production. It also helps regulate homeostasis such as thirst, sleep, hunger, and
temperature regulation. Other parts of the hypothalamus play a role in memory and emotion for the limbic system.
The thalamus processes, prioritizes, and relays motor and sensory information in collaboration with the cerebellum.
The basal ganglia, masses of nuclei located in the deep cerebral hemispheres, are responsible for fine motor
movements and coordination (Thau et al., 2022).

FIGURE 26.4 The diencephalon contains the thalamus and hypothalamus. (attribution: Copyright Rice University, OpenStax, under CC BY

Access for free at openstax.org
 26.1 Structure and Function 1207

4.0 license)

The brain stem includes the midbrain, pons, and medulla. The midbrain connects the pons and the cerebellum with
the cerebral hemispheres. The midbrain also contains motor and sensory pathways and serves as the center for
visual and auditory reflexes. The pons, located in front of the cerebellum between the midbrain and the medulla, is
the bridge between the two halves of the cerebellum. The pons contains sensory and motor pathways. Portions of
the pons help regulate respirations. The medulla contains reflex centers for respiration, heart rate, blood pressure,
coughing, vomiting, sneezing, and swallowing. The reticular formation, which is responsible for arousal and the
sleep-wake cycle, begins in the medulla and connects with various higher structures.

The cerebellum is located under the cerebrum and behind the brain stem. It is responsible for fine motor
movements and coordination. It is also responsible for position (postural) sense or proprioception, one’s awareness
of the position of one’s extremities without looking at them. Sensory feedback from the muscles and joints are sent
back to the cerebellum to provide that information.

The brain is protected by the skull, meninges, and cerebrospinal fluid. The meninges consist of three layers: dura
mater, arachnoid, and pia mater. The dura mater is the outermost layer covering the brain and spinal cord. The
arachnoid is the middle layer and contains cerebrospinal fluid in the space below it, also known as the subarachnoid
space. The innermost layer is the pia mater. It covers the brain closely and extends into the folds of the brain
surface.

Spinal Cord
The spinal cord is an extension of the brain stem (the medulla) from the foramen magnum of the skull to the second
lumbar vertebrae; it transmits motor and sensory impulses. The length of the spinal cord is divided into four regions
that correspond to the level at which spinal nerves pass through the vertebrae. In descending order, these are the
cervical, thoracic, lumbar, and sacral regions. Each region has spinal nerves that innervate specific parts of the body.
The spinal cord is protected by bone, meninges, and cerebrospinal fluid.

Neural Pathways
Ascending and descending neural pathways are in communication with the brain. The ascending pathways provide
sensory information from the body to the spinal cord prior to reaching the brain. This information travels upward,
using first-, second-, and third-order neurons. The first-order neurons send impulses to the spinal cord from the skin
and proprioceptors. The second-order neurons then send those impulses to the thalamus and cerebellum. The
third-order neurons then send those impulses to the somatosensory portion of the cerebrum. Those sensations
include pressure, temperature, pain, and body senses (Thau et al., 2022).

The descending pathways are the communication from the brain to lower motor neurons. The lateral and anterior
tracts conduct motor impulses and control voluntary muscle activity. Vestibulospinal tracts are involved in
autonomic functions such as involuntary muscle control, sweating, circulation, and pupil dilation. The corticobulbar
tract is responsible for impulses that control voluntary and facial movements. Lastly, the reticulospinal and
rubrospinal tracts conduct involuntary muscle movement impulses (Thau et al., 2022).

Peripheral Nervous System
The peripheral nervous system (PNS) includes the cranial nerves, spinal nerves, and autonomic nervous system.
The primary function of the PNS is to connect the CNS to the limbs and organs. Peripheral nerves are categorized as
either sensory or motor nerves, or a combination of the two. Sensory nerves transmit impulses from the body to the
brain for processing. Motor nerves conduct motor signals from the brain to the muscles to initiate movement.

Cranial Nerves
Cranial nerves are connected immediately to the brain. These nerves are responsible for motor and sensory
functions of the head and neck. There are 12 cranial nerves (Figure 26.5) and these are numbered, using Roman
numerals, in the order in which they occur from the brain. See Table 26.2 for the cranial nerves and their functions
(Cleveland Clinic, 2021).
1208 26 Assessment of the Neurological System

Nerve Type Function

I (olfactory) Sensory Sense of smell

II (optic) Sensory Sense of vision

III (oculomotor) Motor Regulates eye and lid movements, blinking, pupil constriction

IV (trochlear) Motor Eye movement (up and down or back and forth)

V (trigeminal) Both Corneal reflex, facial sensations, mastication

VI (abducens) Motor Eye movement

VII (facial) Both Facial expression symmetry; upper and lower facial movement; tearing;
salivation; taste; sensations in ear

VIII (acoustic) Sensory Sense of hearing, equilibrium

IX Both Taste, swallowing, pharyngeal muscles, sensation in pharynx and tongue
(glossopharyngeal)

X (vagus) Both Homeostatic control of the thoracic and upper abdominal cavity muscles

XI (spinal Motor Shoulder and neck movement
accessory)

XII (hypoglossal) Motor Tongue movement
TABLE 26.2 Cranial Nerves and Function

FIGURE 26.5 The 12 cranial nerves originate from the nuclei in the brain and are numbered according to their location in the brain.
(attribution: Copyright Rice University, OpenStax, under CC BY 4.0 license)

Spinal Nerves
Spinal nerves are connected to the brain through the spinal cord (Figure 26.6). There are 8 pairs of cervical nerves,
designated C1 to C8; 12 thoracic nerves, designated T1 to T12; 5 pairs of lumbar nerves, designated L1 to L5; 5
pairs of sacral nerves, designated S1 to S5; and 1 pair of coccygeal nerves (Table 26.3). All spinal nerves are

Access for free at openstax.org
 26.1 Structure and Function 1209

combined sensory and motor nerves. Spinal nerves extend outward from the vertebral column to innervate the
periphery while also transmitting sensory information back to the CNS.

Nerves Location Function

C1–C5 Cervical C1: innervation to muscles at base of the skull
C2–C3: sensory and motor control for the back of the head
C3–C5: phrenic nerve arises here and enables breathing by innervating the
diaphragm

C5–C8 and T1 Brachial Motor and sensory innervation of the upper limbs and upper back

T1–T12 Thoracic Cutaneous innervation of the viscera, skin, and musculoskeletal system
Motor innervation of the thorax, deep back, abdominal wall, and intestines

L1–L5 Lumbar Innervates the transverse abdominal region to the anterior leg:
L2–L3 nerves provide sensory information to the area they innervate as
well as the sex organs
L3–L4 nerves are responsible for generating flexion and adduction of the
thighs

L4 and L5 to Sacral Innervate the gluteal nerves to nerves of the feet
S1–S4
TABLE 26.3 Spinal Nerve Location and Function
1210 26 Assessment of the Neurological System

FIGURE 26.6 The spinal nerves are named based on the level they emerge from the spinal cord. (attribution: Copyright Rice University,
OpenStax, under CC BY 4.0 license)

LINK TO LEARNING

Learn more about cranial nerve testing (https://openstax.org/r/77cranialntst) here.

Autonomic Nervous System
The autonomic nervous system is a division of the nervous system that regulates the involuntary body functions in
order to maintain and restore homeostasis such as physiologic processes of respiration, digestion, blood pressure,
and heart rate (Waxenbaum et al., 2024). This nervous system includes internal organs, such as the lungs, heart,
blood vessels, digestive organs, and glands. The major divisions of the autonomic nervous system are the
sympathetic and parasympathetic nervous systems.

Most organs of the body are innervated by the autonomic nervous system. The autonomic nervous system is
regulated by centers in the hypothalamus, brain stem, and spinal cord. The hypothalamus links this system with the
thalamus, pituitary gland, olfactory apparatus, and the cortex. Visceral and control mechanisms found in this region
are essential for defense or attack modes in emotional states, metabolic processes, body temperature regulation,
muscular and glandular activities of the gastrointestinal tract, the sleep cycle, and genital function control
(Waxenbaum et al., 2024).

Access for free at openstax.org
 26.1 Structure and Function 1211

Sympathetic Nervous System
The sympathetic nervous system is the division best known for the “fight or flight” response. When there is a great
emotional response of fear, anger, or anxiety, or even great physical stress, the body responds to sympathetic
impulses. These impulses are designed to expend energy to combat trauma, threats, or stressful situations. Table
26.4 lists how parts of the body respond in a “fight or flight” response (Waxenbaum et al., 2024).

Body Structure Sympathetic Response

Blood vessels Vasoconstriction

Digestive system Blood vessel constriction, anal sphincter contraction, peristalsis inhibition

Eyes Mydriasis (pupil dilation)

Heart Increased heart rate, increased strength of contraction

Liver Facilitates breakdown of glycogen to glucose for energy release

Lungs Bronchodilation

Liver Facilitates breakdown of glycogen to glucose for energy release

Salivary and lacrimal glands Decreased secretions

Skin Vasoconstriction, diaphoresis, arrector pili muscle contraction

Suprarenal gland Epinephrine (adrenaline) release into the blood

Liver Facilitates breakdown of glycogen to glucose for energy release

Urinary system Decreased urine production, bladder sphincter contraction
TABLE 26.4 Sympathetic Responses of Body Structures

Parasympathetic Nervous System
The parasympathetic nervous system is the division best known for the “rest and digest” response. This system
controls most visceral functions and dominates under nonstressful conditions. The parasympathetic nervous system
only innervates the head, viscera, and external genitalia. In general, the structures affected by the parasympathetic
nervous system respond in the opposition to how they respond with sympathetic impulses. For example, heart rate
and force are decreased, bronchioles are constricted, pupils are constricted, and peristalsis is increased. The key
functions of the parasympathetic nervous system promote respiration, digestion, and cardiac relaxation
(Waxenbaum et al., 2024).

LINK TO LEARNING

Watch this video to learn more about the autonomic nervous system and the sympathetic and parasympathetic
divisions (https://openstax.org/r/77autonersys).

Functions of the Neurological System
The nervous system has a complex and multifaceted role in the body. Each facet of the system is involved in
different tasks. However, taking a broader view of its role, one of the most important processes the nervous system
plays a role in is communication and information processing. The system not only facilitates communication within
the body, between systems, but outside of the body, with the external environment.
1212 26 Assessment of the Neurological System

The nervous system takes in information about what is happening around the body in the world (sensation) and
produces a reaction to that input (motor responses). The process of integration combines sensory perceptions and
higher cognitive functions such as memories, learning, and emotion to form a response.

Sensation
We define sensation as receiving information about the environment. In humans, the major senses are taste, smell,
touch, sight, and hearing. Additional sensory stimuli are also provided from inside the body, such as the stretch of an
organ wall or the concentration of certain ions in the blood. Sensation is key for our survival. Think of the importance
of being able to feel pain and temperature; for example, we learn quite young not to touch a hot stove because it will
burn our hand.

The nurse will encounter patients with various sensory challenges or differences—from vision impairment to hearing
loss or even anosmia (loss of sense of smell and taste). It is crucial that the nurse not only understands how to
assess sensory function but understands how its impairment may affect a patient’s ability to function and quality of
life.

Response
When the nervous system has taken in the information from the environment that’s gathered by the senses, it needs
to process it and take action based on what has been perceived. The system will produce a response based on the
stimuli perceived by sensory nerves.

For example, withdrawing a hand from a hot stove is an example of a response to a painfully hot stimulus. The
sensations of heat and pain are gathered from the external source (stimulus) and processed by the nervous system,
and an action is taken in response. In this case, a protective action is taken that helps a person avoid injury (and
perhaps teaches them to avoid a danger).

Responses can be voluntary (e.g., contraction of a skeletal muscle) or involuntary (e.g., contraction of smooth
muscle in the intestine). An involuntary movement, known as a reflex, occur without conscious thought. Voluntary
responses are governed by the somatic nervous system, and involuntary responses are governed by the autonomic
nervous system.

Breathing, digestion, blood pressure, and heart rate are autonomic responses that the nervous system carries out
automatically. Motor responses, like those required to get up from a chair and walk into the kitchen, are intentional,
conscious movements.

Integration
The process of integration occurs when stimuli received by sensory nerves are communicated to the nervous
system, the information is processed, and a conscious response is generated. In this process, the different parts of
the nervous system collaborate to make sense of the information and decide what to do with it.

Here’s an example: A batter in a baseball game does not automatically swing when they see the pitcher throw the
ball. First, they have to consider the trajectory of the ball and its speed, and only then will they start to create the
motor response of a swing. Integration will occur as the batter consciously decides to swing (or not). If the count is
three balls and one strike, the batter may decide to let the pitch go by in the hope of getting a walk to first base. Or,
maybe the batter is afraid to strike out and does not swing. Perhaps the batter is familiar with the pitcher’s
nonverbal cues and is confident to take a swing at an anticipated fast ball. All these considerations are part of the
batter’s integration response and the higher-level functioning that occurs in the cerebral cortex.

Effects of Impaired Function of the Neurological System
The neurological system can become damaged by infection, trauma, degeneration, tumors, blood flow disruption,
structural defects, and autoimmune disorders. These can have both physical and psychosocial effects on a patient.

Impairments in the nervous system can affect any bodily system and, at times, may affect more than one
simultaneously. For example, the global effects of a major stroke can affect a patient’s ability to walk, talk, and
think. Specific conditions or injuries to bodily systems can affect specific senses, like glaucoma leading to blindness.
A severe spinal cord injury may even impair autonomic functions (e.g., respiration). Nervous system impairments
that involve the brain can also manifest in a patient’s emotional and psychological well-being, causing mood

Access for free at openstax.org
 26.2 Physical Assessment 1213

dysregulation, personality changes, and mental health conditions like depression and anxiety. The nurse needs to be
aware of the many ways in which a dysfunctioning nervous system can affect a patient and be equipped to assess
effectively for the different problems that can occur, as well as the far-reaching effects they can cause.

Physical Effects
Physical effects of an impaired neurological system include, but are not limited to, dizziness, loss of balance or gait
issues, dysphagia (difficulty swallowing), muscle weakness, paralysis, loss of senses, headaches, tremors, seizures,
slurred speech, and inabilities to carry out activities of daily living (ADLs). Examples of ADLs include eating,
performing personal hygiene, toileting, getting dressed, walking, and transferring (e.g., from bed to chair).

Any damage to the brain, spinal cord, or nerves can greatly affect a person’s ability to perform various motor
functions. Weakness, paralysis, spasticity, and coordination problems can have a significant effect on a patient’s
ability to function independently and can lead to complications like falls. Sensory impairments not only affect a
patient’s quality of life but can put them in danger (e.g., poor vision or hearing may prevent them from hearing or
seeing an approaching car when they are walking on the street). Dysfunction of autonomic functions can have a
range of effects, depending on the body system affected and the severity of the impairment. For example,
dysregulation of blood pressure can lead to orthostatic hypotension, and issues with the body’s thermoregulatory
system can lead to excessive sweating or feeling constantly cold.

CLINICAL JUDGMENT MEASUREMENT MODEL
Take Action: Safe Patient Environments
When the nurse identifies physical effects of an impaired neurological system, the nurse should promote an
environment that aids the patient with performing ADLs as independently and safely as possible. This may
include ensuring a gait belt is available for ambulating the patient, ensuring a clutter-free environment to reduce
the risk of falling, regular rounding on the patient and assessing for needs while in the room (e.g., call light in
reach, toileting needs, items patient want are in reach, bed alarm is on), food changes if needed due to
dysphagia (e.g., pureed, mashed, soft, liquid), signage reminding patient to call when they want to get up, and
dressing tools (e.g., shoe horn, sock aid). A crucial component the nurse should include in the plan of care is to
educate the patient about these interventions and their importance. Those with cognitive effects may need to be
reminded or have signs posted in their room as well. The family, if present, should also be aware of these
interventions to help promote patient safety as well.

Psychological Effects
Psychological effects of an impaired neurological system include, but are not limited to, depression, changes in
cognition or mental ability, fear of losing control, and anxiety. Depression can be due to damage or impaired
functioning of the nervous system or due to the physical or psychological effects of an impaired nervous system.
Cognitive impairments affect a person’s ability to pay attention, make decisions, have sound judgment, speak and
understand language, plan, reason, perceive things or ideas, and recall memories. This can contribute to depression
and anxiety if the person is able to make the connection that they have lost a function they previously could
perform. Fear of losing control and anxiety are common symptoms of cognitive impairments.

26.2 Physical Assessment
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Perform a comprehensive neurological assessment
Understand abnormalities identified during the assessment of the neurological system
Recall proper documentation of neurological assessment

The neurological exam is a clinical assessment of the functioning of the CNS and PNS. Routine neurological exams
performed by registered nurses during their daily clinical practice include assessing mental status and level of
consciousness, pupillary response, motor strength, sensation, and gait. The Glasgow Coma Scale (GCS) is also
frequently used to objectively monitor level of consciousness in patients with neurological damage such as a head
injury or cerebrovascular accident, or stroke (Figure 26.7). Periodic reevaluations are performed when the patient
1214 26 Assessment of the Neurological System

has experienced an acute injury or illness causing neurological deficits, such as a stroke, which require frequent
monitoring for change in condition.

Comprehensive Neurological Assessment
The comprehensive neurological assessment requires the nurse to collect both subjective and objective data
through an interview as well as a detailed physical exam. This exam is more extensive and performed on patients
with a neurological concern. In addition to the components included in a routine neurological exam, the examiner
may also assess cranial nerves, detailed cerebellar function, deep tendon reflexes, and complete a Mini-Mental
State Exam (MMSE).

Subjective Data
The subjective data are collected during an interview and guide the focus of a physical exam. It is crucial that the
nurse collects a complete health history using effective communication to identify any current or potential issues,
because some issues may only be identified through precise questioning during the interview. For example, the
nurse will want to ask questions regarding loss of sensation, loss of concentration, or dizziness to identify potential
problems (Table 26.5). Follow-up questions may also be required to identify when a patient’s symptoms started and
any associated signs. The nurse may also ask about other signs and symptoms such as headaches, seizures,
confusion, vertigo, recent injury, numbness, tingling, weakness, dysphagia (difficulty swallowing), dysphasia
(difficulty speaking), or loss or coordination.

Interview Questions Follow-up

Are you experiencing any current neurological If the patient is seeking care for an acute
concerns such as headache, dizziness, weakness, neurological problem, use the PQRSTU method to
numbness, tingling, tremors, loss of balance, or further evaluate their chief complaint.
decreased coordination? Note: If critical findings of an acute neurological
Have you experienced any difficulty swallowing or event are actively occurring, such as signs of a
speaking? stroke, obtain emergency assistance according to
Have you experienced any recent falls? agency policy.

Have you ever experienced a neurological condition Describe the condition(s), date(s), and treatment(s).
such as a stroke, transient ischemic attack, seizure, or
head injury?

Are you currently taking any medications, herbs, or Please describe.
supplements for a neurological condition?
TABLE 26.5 Interview Questions for Subjective Assessment of Neurological System

PATIENT CONVERSATIONS

The Older Adult and the Nervous System Interview
Scenario: A nurse is collecting subjective data about a 79-year-old male in the clinic.

Nurse: Hi. My name is Suzie, and I’m the nurse who will be taking care of you today. May I have your name and date
of birth?

Patient: My name is Fred Reid, date of birth January 21, 1944.

Nurse: Great, thank you. What brings you in today?

Patient: I am just here for a check-up. I have been feeling off lately.

Nurse: Okay, can you describe for me what that means?

Patient: Well, I have just been dizzy some.

Access for free at openstax.org
 26.2 Physical Assessment 1215

Nurse: Do you feel light-headed also, and do you notice if it occurs with a particular activity or when you change
positions?

Patient: Mainly when I stand up. I start to lose my balance some.

Nurse: When did this start?

Patient: Oh, maybe a week or so ago.

Nurse: Have you experienced any recent falls or medication changes?

Patient: No falls yet. That is why I am here, so I can try to figure this out and not fall. I did get started on Lasix about
10 days ago.

Nurse: Okay, a common side effect of Lasix is called orthostatic hypotension. It is a condition where your blood
pressure can lower suddenly when standing from a seated or lying position. It can cause light-headedness or a loss
of balance. It is important for you to change positions slowly. So, for example, when you are getting out of bed, you’ll
want to sit up on the side of the bed and wait a minute or so before standing up to give your body time to adjust to
the position changes. You will want to make sure you feel steady before moving, so even if it takes you a few
minutes to get your bearings, that is okay.

Patient: Oh, that makes sense.

Nurse: Yes sir. I will let Dr. Caldwell know, and he may order additional testing regarding this while you are here.

Patient: Okay.

Nurse: Have you experienced any other neurological signs or symptoms, like difficulty swallowing or speaking,
seizures, headaches, numbness, tingling, or tremors?

Patient: No ma’am.

Nurse: Okay, we will review your other body systems and then move into a physical exam if you are ready.

Scenario follow-up: Now that the nurse has completed the nervous system assessment, they can move on to the
other body systems.

Objective Data
The objective data collected during an exam are used to assess the patient’s mental status as well as motor and
sensory function, cranial nerve function, and deep tendon reflexes. In addition, this part of the comprehensive exam
will require the nurse to observe the patient’s posture, ability to walk, and personal hygiene, as well. Table 26.6
describes common objective exams used to evaluate various components of the nervous system.
1216 26 Assessment of the Neurological System

Test What It Assesses How to Perform

Glasgow Mental status/ Scoring tool that assesses eye opening response, verbal response, and
Coma level of motor response (Figure 26.7).
Scale consciousness

National Neurological Tool used to assess for suspected cerebrovascular accident. Uses the
Institutes function (mental mnemonic “BEFAST”:
of status, ability to B: Balance (Is there a sudden loss of balance?)
Health communicate, E: Eyes (Any loss of vision in one or both eyes?)
Stroke motor function) F: Face (Does the face appear uneven, is there any drooping?)
Scale A: Arm (Any weakness or numbness in either arm?)
S: Speech test (Any slurred speech or trouble speaking? Does patient
appear confused?)
T: Time to call for immediate assistance

Mini- Cognitive status 30-point test used to assess for dementia (chronic, irreversible confusion) or
Mental delirium (acute, reversible confusion that may be due to an infection, fever,
State or lack of oxygen). Scoring is as follows: 24–30, no impairment; 18–23, mild
Exam cognitive impairment; and