Spirometry & Post-Bronchodilator Studies

Objectives — Perform spirometry; evaluate flow-volume loops; follow user maintenance and quality-control procedures; interpret spirometry values and peak flow; and perform post-bronchodilator testing when indicated.

Pulmonary Function Test Overview

Pulmonary diagnostic testing includes:

Pulmonary Function Tests (PFTs)
Spirometry
Lung volumes
DLCO
Bronchoprovocation
CPX
Bronchoscopies
Sleep studies

This lesson focuses on spirometry and post-bronchodilator studies.

Spirometry

Definition

Spirometry is the measurement of air entering and leaving the lungs.

It includes measurements of several values of forced airflow and volume during inspiration and expiration.

Pattern Memory Aids

Pattern	Memory aid	Disease/process examples
Volume problem	PAINT	Pulmonary, Alveolar, Interstitial, Neuromuscular, Thoracic
Flow problem	CBABE	Cystic fibrosis, Bronchitis, Asthma, Bronchiectasis, Emphysema

In general:

Reduced volume suggests a possible restrictive pattern.
Reduced flow suggests a possible obstructive pattern.

Indications, Contraindications & Hazards

Indications

Establish baseline pulmonary function
Detect disease
Follow the course of a disease or monitor treatment
Evaluate impairment
Test patients with dyspnea to see if symptoms are cardiac or pulmonary related
Pre-operative evaluation
Identify the high-risk smoker

Contraindications

Hemoptysis of unknown origin
Pneumothorax
Unstable cardiovascular status, including recent MI or PE
Thoracic, abdominal, or cerebral aneurysms
Recent eye, chest, or abdominal surgery

Hazards

Syncope or dizziness
Paroxysmal coughing
Nosocomial infections
Bronchospasm
Desaturation due to interruption of oxygen

Equipment

Spirometer Types

Type	Description
Volume-sensing spirometer	Measures volume directly; primary advantage is better long-term accuracy if calibration is not done regularly
Flow-sensing spirometer	Includes pneumotachometers; measures flow and derives volume

Additional Equipment

Filter and mouthpiece assembly
Nose clips
Appropriate gas sources

Predicted Reference Values

Spirometry measurements are compared to predicted values according to:

Race
Age
Sex
Height

Predicted values are expected or reference values for lung function tests, usually derived from a large population of healthy individuals.

Predicted percent values compare the patient's actual measurements to predicted values:

Predicted % = (actual value / predicted value) x 100

LLN and Z Scores

LLN means Lower Limit of Normal.

PFT values are considered normal if they are greater than or equal to LLN.

Result	Interpretation
Greater than or equal to LLN	Normal, within range
Less than LLN	Low, below the lower limit of predicted
Greater than ULN	High, greater than the upper limit of normal predicted

The 5th percentile is the value below which 5% of normal reference-set results may be found. If a value falls below the LLN, there is only a 5% chance the result is normal and a 95% chance the result is abnormal.

Pre-Procedure Assessment

Medication Preparation

Withhold bronchodilators before testing when ordered by protocol.

Patient Information

Collect:

Age
Height, or arm span if the patient cannot stand
Sex
Race
Smoking history

Smoking History

Ask about:

Cigarettes
Pipe
Cigar
Marijuana
Cocaine
How long the patient smoked or did smoke
How long ago the patient quit
Whether the patient lives with a smoker

Calculate pack years:

Pack years = packs per day x years smoked

Symptom and Exposure History

Document:

Description of cough and sputum production
Description of dyspnea: at rest, on exertion, or at night
Occupational exposure history, including work in or around mines, quarries, foundries, gases, fumes, or asbestos

Forced Vital Capacity Procedure

The FVC maneuver is performed seated.

Have the patient place a tight seal around the mouthpiece.
Instruct the patient not to obstruct the mouthpiece with the tongue.
Place nose clips.
Record a few tidal breaths.
At end exhalation, coach the patient to inhale maximally to TLC.
Coach the patient to forcefully exhale until completely empty at RV.
Once the patient has completely exhaled, coach the patient to inhale as rapidly as possible back to TLC.
Repeat until 3 efforts have been obtained that meet ATS criteria for acceptability and reproducibility.

Coaching Instructions

Actively coach the subject:

"Lips around the mouthpiece and good tight seal."
"Normal breathing."
"Fill your lungs completely / big deep breath in."
"Blast the air out."
"Keep going, push, push, push."
Continue until a plateau is reached, a minimum of 6 seconds is met, or expiratory time reaches 15 seconds.
"Big deep breath in."

ATS Criteria for Acceptability

Each effort must be free from artifact.

Start-of-Test Errors

Error	Identify by	Coaching correction	Test implication
Sub-maximal blast	Low peaks on the flow-volume curve	Blast harder	Falsely reduced FEV1 and ratio
Excessive extrapolated volume	Hesitation before the initial blast	Blast faster; do not wait after the deep breath	Reduced FEV1 and reduced ratio
Cough in the first second	Cough occurs before FEV1 is complete	Repeat maneuver	Invalid FEV1
Sub-maximal inhalation	Patient does not inhale completely to TLC	Big deep breath in before blasting	Falsely reduced volume

Back Extrapolation

Back extrapolation is used to determine and compensate for hesitation at the start of the test. The software determines time zero when the patient starts exhalation.

Extrapolated volume must be less than:

FVC	Maximum extrapolated volume
FVC less than 2 L	100 mL
FVC greater than 2 L	5%

Middle-of-Test Errors

Variable or inconsistent effort
Partially blocked mouthpiece
Glottic closure or breath hold
Early termination or no plateau
FIVC - FVC greater than 0.100 L or 5% of FVC, whichever is greater

Minimum exhalation time:

Patient group	Minimum exhalation time
Patients 10 years or older	6 seconds
Children 10 years or younger	3 seconds

Patients who are older or obstructed commonly need more than 6 seconds.

End-of-Test Errors

Extra breath
Positive zero-flow error
Negative zero-flow error
Leak

Core Spirometry Values

Forced Vital Capacity (FVC)

FVC is the volume that can be expired as forcefully as possible after maximum inhalation.

Recorded in liters, BTPS
Healthy patients: FVC equals SVC
Obstructive disease: FVC may be less than SVC due to airway collapse and air trapping
Restrictive disease: FVC is reduced due to loss of lung volume

FVC Percent Predicted

FVC % predicted	Severity
Greater than 80%	Normal
66-79%	Mild
50-65%	Moderate
Less than 50%	Severe

Forced Expiratory Volume-Time (FEVt)

FEVt is the volume of gas expired during a given interval from the beginning of the FVC maneuver.

Examples include 0.5, 1.0, and 3.0 seconds.

Recorded in liters, BTPS
FEV1 is the most commonly used timed interval
FEV1 is the best value to grade the severity of airway obstruction

FEV1 Percent Predicted

FEV1 % predicted	Severity
Greater than 80%	Normal
70-79%	Mild
60-69%	Moderate
50-59%	Moderately severe
35-49%	Severe
Less than 35%	Very severe

FEVt/FVC Ratio

The FEVt/FVC ratio is the ratio of FEVt to FVC, expressed as a percentage. It is commonly called the ratio.

FEV1/FVC Interpretation

Ratio finding	Pattern suggested
Greater than 100% or greater than ULN	Restrictive diseases
About 70%	Normal patient
65-70%	Healthy but older patient
Less than 70%	Obstructive diseases

Actual Timed Values

Timed value	Expected portion of FVC
FEV0.5	50-60% of FVC
FEV1	75-85% of FVC
FEV2	90-95% of FVC
FEV3	95-98% of FVC
FEV6	98-100% of FVC

Forced Expiratory Flow 25%-75%

FEF25%-75% is the average flow rate during the middle half of an FVC maneuver.

Recorded in L/sec, BTPS
Good indicator of flow characteristics in the medium and small airways
Normal: 4-5 L/sec
Values as low as 50% predicted may be considered normal
Decreased values are common in early obstructive disease and are seen in asthma and bronchitis

Peak Expiratory Flow Rate (PEFR)

PEFR is the maximum flow rate attained during the FVC maneuver: the peak of the flow-volume loop.

Recorded in L/sec or L/min, BTPS
Sometimes displayed as forced expiratory flow max, or FEF Max
Effort dependent
Decreased values should be evaluated for reproducibility before diagnostic interpretation
Good indicator for patient effort during spirometry

Patients with small-airway obstructive disease may show a relatively normal PEFR. A uniform decrease in PEFR is commonly associated with non-specific upper or large-airway obstruction.

Spirometry Graphic Displays

Flow-Volume Loop

A flow-volume loop displays the flow generated during an FVC maneuver plotted against volume, usually followed by an FIV maneuver.

Axis	Measurement
X-axis	Volume in L, BTPS
Y-axis	Flow in L/sec

Values from the flow-volume loop:

FVC
PIFR, or forced inspiratory flow max
PEFR, or forced expiratory flow max
FEF25%-75%

Evaluate the flow-volume loop for:

Shape of disease patterns
The best loop
PEFR
TET, or total expired time

Volume-Time Curve

A volume-time curve displays volume over time.

Axis	Measurement
X-axis	Time in seconds
Y-axis	Volume in L

Values from the volume-time curve:

VT
FVC/SVC
FEVt

Spirometry Interpretation

Before interpreting, check:

Patient demographics
Acceptability criteria
Reproducibility criteria

Then evaluate:

FEV1/FVC measured value
FEV1
FVC percent predicted
FEF25%-75% percent predicted
Flow-volume loop

Not meeting LLN can determine if the patient has possible signs of restriction, obstruction, or both.

Post-Bronchodilator Study

Objectives

Perform a lung post-bronchodilator study.

Indications

Determine reversibility of airway obstruction
Assess need for additional medication
Diagnose asthma

Contraindications and Spirometry Hazards

Contraindications and hazards are the same as spirometry:

Hemoptysis of unknown origin
Pneumothorax
Unstable cardiovascular status, including recent MI or PE
Thoracic, abdominal, or cerebral aneurysms
Recent eye, chest, or abdominal surgery
Syncope, dizziness, paroxysmal coughing, nosocomial infection, bronchospasm, and desaturation due to interruption of oxygen

Bronchodilator Hazards

Tachycardia
HTN
Tremors
Nausea

Equipment

Bronchodilator
Beta-adrenergic medication, most commonly used
Anticholinergic medication

Medication Withholding Times

Inhaled Bronchodilators

Medication	Withhold
Metaproterenol (Alupent)	4 hours
Albuterol (Proventil, Ventolin)	4 hours
Levalbuterol (Xopenex)	8 hours
Ipratropium (Atrovent)	4 hours
Salmeterol (Serevent)	12 hours
Tiotropium (Spiriva)	24 hours

Mediator Modifiers

Medication	Withhold
Cromolyn sodium (Intal)	8 hours
Nedocromil (Tilade)	48 hours

Post-Bronchodilator Procedure

Perform baseline spirometry according to ATS criteria.
Administer medication per local policy.
Use 4 puffs by MDI per ATS when following the listed protocol.
Wait 15 minutes.
Repeat spirometry according to ATS guidelines.
Calculate percent change using measured FEV1 or FVC.

% change = ((post - pre) / pre) x 100

Interpretation

Significant airway reversibility is:

FEV1 or FVC increase of greater than 12%
And an increase of 200 mL

FEV1 and FEF25%-75% usually show the greatest change, although lung volumes and DLCO may also respond to bronchodilator therapy.

Failure to show a significant response does not exclude a response. Reasons include:

Moderate to severe COPD with patient fatigue
Inadequate disposition of medication

Review

Be able to:

Define spirometry
List indications and contraindications
Identify required equipment
Apply ATS criteria
Interpret FVC, FEV1, FEV1/FVC, FEF25%-75%, and PEFR
Evaluate flow-volume loops and volume-time curves
Perform and interpret post-bronchodilator studies