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Related Concept Videos

External and Internal Respiration01:24

External and Internal Respiration

External respiration occurs in the lungs, and it is the first step in the journey of oxygen inside the body. When we inhale, oxygen enters our lungs and diffuses across the thin alveolar membrane. The alveoli are tiny, air-filled sacs that provide a vast surface area for gas exchange. Oxygen in the alveoli has a higher partial pressure (105 mmHg) than in the adjacent pulmonary capillaries (40 mmHg), establishing a pressure gradient. As a result, oxygen molecules move from the alveoli into the...
Respiratory Volumes and Capacities I01:26

Respiratory Volumes and Capacities I

Assessing the respiratory rate and rhythm for a complete minute is crucial for evaluating the breathing pattern. Even a minor increase in the patient's average respiratory rate, by as little as three to five breaths per minute, is an early and vital indicator of respiratory distress. Patients with a respiratory rate exceeding twenty-four breaths per minute require close monitoring to determine the physiological alterations. This careful observation is essential for prompt recognition and...
Assessment of Diffusion and Perfusion01:17

Assessment of Diffusion and Perfusion

Understanding and evaluating diffusion and perfusion is critical in assessing a patient's respiratory and circulatory health. These processes play key roles in maintaining the body's internal environment, ensuring that tissues receive adequate oxygen while waste products are efficiently removed.
The Role of Diffusion in Respiration
Diffusion is the process by which molecules move from an area of higher concentration to an area of lower concentration. In the respiratory system, this principle...
Respiratory Capacities01:24

Respiratory Capacities

Respiratory capacities are crucial indicators of lung function, representing the maximum amount of air an individual's respiratory system can handle during various breathing phases.
One key metric is the Inspiratory Capacity (IC), which represents the maximum amount of air that can be inhaled with full effort. IC is calculated by summing the tidal volume and inspiratory reserve volume, typically ranging from 2.4 to 3.6 liters.
The Functional Residual Capacity (FRC) represents the air in the...
Physical Assessment of the Respiratory Tract II: Inspection01:27

Physical Assessment of the Respiratory Tract II: Inspection

Physical assessment of the respiratory tract through inspection is a crucial step in understanding the patient's respiratory health. It provides insights into the functioning of the respiratory system, the musculoskeletal structure, and even the patient's nutritional status. This comprehensive approach involves observing several vital aspects: chest configuration, breathing patterns, respiratory rates, skin color, and use of accessory muscles.
Chest Configuration
The chest configuration can...
Respiratory Volumes and Capacities01:22

Respiratory Volumes and Capacities

The respiratory system is responsible for the intake of oxygen and the expulsion of carbon dioxide from the body. Respiratory volumes describe the volume of air in the lungs at different phases of the respiratory cycle. Tidal volume is the air breathed in and out during normal, quiet breathing. Inspiratory reserve volume is the air that can be forcefully inspired beyond the tidal volume. In contrast, expiratory reserve volume refers to the air that can be expelled from the lungs after a normal...

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Dual Test Gas Pulmonary Diffusing Capacity Measurement During Exercise in Humans Using the Single-Breath Method
08:44

Dual Test Gas Pulmonary Diffusing Capacity Measurement During Exercise in Humans Using the Single-Breath Method

Published on: February 2, 2024

Long-term intersession variability for single-breath diffusing capacity.

Matthew J Hegewald1, Robert L Jensen, John G Teeter

  • 1Division of Pulmonary and Critical Care Medicine, University of Utah School of Medicine and Intermountain Medical Center, Salt Lake City/Murray, Utah, USA.

Respiration; International Review of Thoracic Diseases
|January 4, 2012
PubMed
Summary
This summary is machine-generated.

Long-term diffusing capacity (DL(CO)) variability in biocontrols was characterized. Deviations greater than 12% or 3.0 units from the average of the first six tests suggest equipment quality control issues.

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Quantitative Measure of Lung Structure and Function Obtained from Hyperpolarized Xenon Spectroscopy
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Quantitative Measure of Lung Structure and Function Obtained from Hyperpolarized Xenon Spectroscopy
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Quantitative Measure of Lung Structure and Function Obtained from Hyperpolarized Xenon Spectroscopy

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Area of Science:

  • Pulmonary Function Testing
  • Biomedical Engineering
  • Quality Control in Healthcare

Background:

  • Assessing long-term diffusing capacity (DL(CO)) variability is crucial for equipment quality control and patient management.
  • Previous research has not reported on long-term DL(CO) variability.

Purpose of the Study:

  • To characterize the long-term variability of DL(CO) in a biocontrol cohort.
  • To compare different methods for selecting a target DL(CO) value for variability assessment.

Main Methods:

  • Longitudinal DL(CO) monitoring of 288 biocontrols over up to 5 years, with twice-monthly testing.
  • Standardized DL(CO) measurement technique used throughout the study.
  • Variability analysis using three distinct target value selection methods.

Main Results:

  • The 90th percentile for mean intersession DL(CO) change ranged from 10.9% to 15.8% (2.6-4.1 units).
  • Lowest variability was observed when using the mean of all tests as the target; highest variability occurred when using the baseline DL(CO).
  • The average of the first six DL(CO) tests accurately estimated the mean DL(CO) value, yielding a 90th percentile change of 12.3% (3.0 units).

Conclusions:

  • DL(CO) deviations exceeding 12% or 3.0 units from the average of the first six tests indicate potential instrument quality control issues.
  • Instruments showing such deviations require careful evaluation before further patient testing.
  • Variability remained stable over time and was not significantly associated with demographic factors.