Anatomy of Respiratory System for Lecture 01
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BUC University
Dr. Mina Atef
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Summary
This presentation provides an overview of the anatomy and physiology of the pulmonary system and thoracic cage. It covers various parts like the nose, mouth, and lungs. The presentation also includes information on the different zones of the respiratory system and how they function.
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Dr. Mina Atef Anatomy of Respiratory System The respiratory system consists of organs: Nose Mouth (oral cavity) Pharynx (throat) Larynx (voice box) Trachea (windpipe) Bronchi Lungs Organs of the Respiratory System Divided into Conducting zone Respiratory zone ...
Dr. Mina Atef Anatomy of Respiratory System The respiratory system consists of organs: Nose Mouth (oral cavity) Pharynx (throat) Larynx (voice box) Trachea (windpipe) Bronchi Lungs Organs of the Respiratory System Divided into Conducting zone Respiratory zone Nose Provides an airway for respiration Moistens and warms air Filters inhaled air Resonating chamber for speech The Trachea Descends into the mediastinum C-shaped cartilage rings keep airway open Carina Marks where trachea divides into two primary bronchi Bronchi Bronchial tree: Primary bronchi (main bronchi) Secondary (lobar) bronchi Three on the right Two on the left Tertiary (segmental) bronchi Branch into each lung segment Bronchioles Little bronchi, less than 1 mm in diameter Terminal bronchioles Less than 0.5 mm in diameter Structures of the Respiratory Zone Consists of air-exchanging structures Respiratory bronchioles – branch from terminal bronchioles Lead to alveolar ducts Lead to alveolar sacs Gross Anatomy of the Lungs Major landmarks of the lungs Apex, base, hilum, and root Left lung Superior and inferior lobes Fissure – oblique Right lung Superior, middle, and inferior lobes Fissures – oblique and horizontal Anterior View of Thoracic Structures The Pleurae A double-layered sac surrounding each lung Parietal pleura Visceral pleura Pleural cavity Potential space between the visceral and parietal pleurae The Mechanisms of Ventilation Two phases of pulmonary ventilation Inspiration – inhalation Expiration – exhalation Inspiration -The principal muscles are: 1. The diaphragm 2. Intercoastal muscles - Volume of thoracic cavity increases - Decreases internal gas pressure -Action of the diaphragm Diaphragm flattens -Action of intercoastal muscles Contraction raises the ribs Inspiration Accessory muscles are typically only used when the body needs to process energy quickly (e.g. during strenuous exercise, during the stress response, or during an asthma attack): Scalenes Sternocleidomastoid Pectoralis major Pectoralis minor Erector spinae – extends the back Expiration Quiet expiration – chiefly a passive process Inspiratory muscles relax Diaphragm moves superiorly Volume of thoracic cavity decreases Forced expiration – an active process Produced by contraction of Internal and external oblique muscles Transverse abdominal muscles Neural Control of Ventilation Most important respiratory center Ventral respiratory group Located in reticular formation in the medulla oblongata Neurons generate respiratory rhythm Lung Volumes and Capacities 6000 IRV IC Volume (ml) VC VT TLC ERV FRC RV 0 Primary Lung Lung Capacities Volumes Basic Lung Volumes There are 4 volume subdivisions: 1. Tidal Volume: TV 2. Inspiratory Reserve Volume: IRV 3. Expiratory Reserve Volume: ERV 4. Residual Volume: RV Basic Lung Volumes There are 4 volume subdivisions: They do not overlap They can not be further divided When added together equal total lung capacity Basic Lung Volumes There are 4 volume subdivisions: Tidal Volume: TV The amount of gas inspired or expired with each normal breath. About 500 ml Basic Lung Volumes Inspiratory Reserve Volume: IRV Maximum amount of additional air that can be inspired from the end of a normal inspiration. Basic Lung Volumes Expiratory Reserve Volume: ERV The maximum volume of additional air that can be expired from the end of a normal expiration. Basic Lung Volumes Residual Volume: RV The volume of air remaining in the lung after a maximal expiration. This is the only lung volume which cannot be measured with a spirometer. Lung Capacities Are subdivisions of the total volume that include two or more of the 4 basic lung volumes Lung Capacities Total Lung Capacity: TLC Vital Capacity: VC Functional Residual Capacity: FRC Inspiratory Capacity: IC Lung Capacities Total Lung Capacity: TLC The volume of air contained in the lungs at the end of a maximal inspiration. Called a capacity because it is the sum of the 4 basic lung volumes TLC= RV+IRV+TV+ERV Lung Capacities Vital Capacity: VC The maximum volume of air that can be forcefully expelled from the lungs following a maximal inspiration. Called a capacity because it is the sum of inspiratory reserve volume, tidal volume and expiratory reserve volume. VC= IRV+TV+ERV = TLC - RV Lung Capacities Functional Residual Capacity: FRC The volume of air remaining in the lung at the end of a normal expiration. Called a capacity because it equal residual volume plus expiratory reserve volume. FRC= RV+ERV Lung Capacities Inspiratory Capacity: IC Maximum volume of air that can be inspired from end expiratory position. Called a capacity because it is the sum of tidal volume and inspiratory reserve volume. This capacity is of less clinical significance than the other three. IC= TV+IRV Respiratory Diseases Restrictive Disease: Makes it more difficult to get air in to the lungs. They “restrict” inspiration. Decreased VC; Decreased TLC, RV, FRC Includes: Fibrosis Sarcoidosis Muscular diseases Chest wall deformities Tumors Pleural Effusion, Pneumothorax Respiratory Diseases Obstructive Disease Make it more difficult to get air out of the lungs. Decrease VC; Increased TLC, RV, and FRC Includes: Emphysema Chronic bronchitis Asthma