Humidification Delivery

Objectives - Operate a large volume nebulizer; provide active humidification; provide passive humidification; explain goals of cool vs warm humidification; identify humidification systems utilized in respiratory care.

Humidification Systems Overview

Airway region	Active humidity	Passive humidity
Small airways	Aerosolized water (passover, wick, large volume jet nebulizer)	—
Large airways	Passover, wick, large volume jet nebulizer	Heat moisture exchanger (HME/artificial nose)

Focus Points

Identify isothermic saturation boundary principles
Identify goals and purpose of devices used to deliver humidification to large and small airways
Match appropriate oxygen delivery devices with the correct humidifier:
- High flow
- Low flow
- Invasive and non-invasive ventilation
Describe bland aerosol delivery via LVN

Humidity Definitions

Humidity — water in a gaseous state
Absolute humidity — actual content of water vapor in a gas measured in milligrams per liter
Relative humidity — amount of water vapor in a gas compared to the maximum amount possible, expressed as a percentage
Potential humidity — maximum amount of water vapor a gas can hold at a given temperature

Normal Humidification Pathway

Nose: Increases humidity and temperature of inhaled air to 50% of BTPS.

BTPS = body temperature 37°C, ambient pressure, and gas saturated with water vapor (relative humidity).

Upper airway/trachea: Increases heat and humidity of inhaled air to 32–34°C and 100% RH.

Isothermic saturation boundary (ISB): Inhaled gas achieves BTPS conditions (37°C and 100% RH) below the ISB.

Isothermic Saturation Boundary (ISB)

Point in the airways where gas reaches BTPS (37°C and 100% RH)
Location: 5 cm below the carina at room temperature; approximately the second/third bronchial divisions
ISB location/position fluctuates:
- Varies with physical exertion; breathing rate affects temperature
- Inspired air temperature affects position (cold air)
- Exercise-induced asthma (EIA) affects the location of ISB

Purpose for Humidity

Reduce humidity deficit:

Airways exposed to dry inhaled gases
Leads to thickened (inspissated) secretions
Decreases secretion mobility

Reduce temperature deficit:

Airways exposed to cold air increase mucus production

Humidity and temperature deficits result in mucus thickening and airway obstruction.

Medical Gas and ISB Principles

Medical gas has zero percent humidity; humidity must be added to all medical gases
Humidification methods and devices must provide greater than 60% humidity to the upper airways and below to avoid lung injury

ISB principles:

Inspiration: temperature and RH increase
Exhalation: temperature and RH decrease
Below the ISB: temperature and relative humidity remain constant (37°C — BTPS)

Patients with Artificial Airways

Trach and ET tubes bypass the upper airways.

Humidification and heat must be added to inhaled gases
Cold and dry air exposure reduces ciliary motility
Airways become irritated, increasing mucus production
Secretions become inspissated (thickened from dehydration — mucus plug formation)

Humidifier Equipment

Factors for Humidifier Effectiveness

Temperature
Surface area
Time of contact
Thermal mass

Types of Humidifiers

Category	Examples
Passive	Heat moisture exchangers (HME), aka artificial nose
Active	Bubble humidifier, passover, wick

Passive Humidifiers: Heat and Moisture Exchanger (HME)

Function: Captures exhaled heat and humidity from the patient and returns heat and humidity during inhalation.

Patient hydration status directly affects humidity delivered.

HME Types

Type	Efficiency
Simple condenser humidifiers	50%
Hygroscopic condenser humidifiers	70%
Hydrophobic condenser humidifiers	~70%, anti-bacterial, higher WOB

HME Indications

Short-term use for transporting mechanically ventilated patients
Skilled nursing facilities for up to 1 week
Tracheostomy patients transported off mechanical ventilation
Reduced bacterial colonization in ventilator circuits

HME Contraindications

Thick, copious, or bloody secretions (active humidity indications)
Body temperature below 32°C (89.6°F)
Minute ventilation greater than 10 L/min
Pediatric or neonatal patients (increases dead space)
COPD patients — increases airway resistance, WOB, and air trapping; worsens acidosis

Active Humidifiers

Bubble Humidifier

Used with low flow oxygen devices
Gas directed below the surface of water via a capillary tube
Diffuser breaks gas into smaller bubbles, increasing surface area and effectiveness

Heated Active Humidity

Used with patients with artificial airways (endotracheal/tracheal tubes).

Influence of temperature:

Temperature is the most significant influence on evaporation
Warm air holds more water vapor than cool air
Heated water: more molecules escape the water surface (evaporate)
As air flows through the heated chamber, humidity is added from the humid environment and contact with the warm water surface

Pass-Over Humidifier

Gas flows through a heated chamber; humidity is added from the humid environment and contact with the warm water surface.

Temperature at 37°C provides 44 mg H2O/L humidity
Temperature at 31°C provides 30 mg H2O/L humidity
Used for invasive and non-invasive mechanical ventilation
BTPS target: 44 mg/L at 37°C

Passover humidifier variations:

Type	Delivery
Heated humidifiers	Optimal temperature and humidity (44 mg H2O/L at 37°C)
Cool humidifiers	Minimal efficiency at lower temp and humidity (20 mg H2O/L at 22°C)
Non-disposable humidifiers	Refilled with sterile water; sterilized and reused after patient use
Disposable humidifiers	Prefilled with water; discarded after patient use

Wick Humidifier

Invasive and non-invasive mechanical ventilation
Gives the most humidity
Examples: Concha Therm, wick humidifier systems, wick canister

Bland Aerosol Therapy

Aerosol — solid or liquid particles suspended in a gas.

Large Volume Nebulizer (LVN)

For LVN as a high-flow oxygen delivery device (FiO2 30%–100%, delivery interfaces), see Oxygen Delivery Devices.

In this lesson, LVN is used as a jet nebulizer that delivers aerosolized water particles to the upper airways:

Delivers oxygen at selectable concentrations up to 100% at flow rates greater than 100 L/min
Delivers heated aerosol to patients with artificial airway, such as tracheostomy patients

Cool Aerosolized Water Administration

Indications:

Treat upper airway inflammation from intubation, trauma, croup, or epiglottitis
Promotes localized mucosal vasoconstriction and reduces inflammation
Reduced inflammation relieves upper airway discomfort
Improves airflow through large airway
Reduces work of breathing

Warm Aerosolized Water Administration

Indications:

Prevent injury to large airways from inhalation of improperly conditioned/dry gas
Preserves motility of the mucociliary escalator
Increasing gas temperature increases gas carrying capacity of aerosolized water delivered to large airways
Maintains mucosal hydration when upper airways are bypassed
Important when trach patients are off mechanical ventilation

Bland Aerosol Therapy Indications Summary

Presence of upper airway edema
Laryngotracheobronchitis
Subglottic edema
Post-extubation edema
Postoperative management of the upper airway
Bypassed upper airway (intubated/trach — heated)
Need for sputum specimens or mobilization of secretions

High-Yield Review

Objectives Checklist

Operate a large volume nebulizer
Provide active humidification
Provide passive humidification
Explain goals of cool vs warm humidification
Identify humidification systems utilized in respiratory care

Humidification Systems

Active humidity	Passive humidity
Passover	Heat moisture exchanger (HME/artificial nose)
Wick
Bland aerosol therapy
Bubble humidifier
Large volume jet nebulizer

Key Clinical Points

ISB: gas reaches BTPS (37°C, 100% RH) approximately 5 cm below the carina
Medical gas has 0% humidity; provide greater than 60% humidity to avoid lung injury
Cool bland aerosol: upper airway inflammation and vasoconstriction
Warm bland aerosol: prevent dry gas injury; preserve mucociliary escalator when upper airway is bypassed
HME contraindicated with copious secretions, MV greater than 10 L/min, COPD, and neonatal/pediatric patients