Which of the following best describes the combined functional roles of the respiratory system beyond gas exchange?
A. The respiratory system primarily regulates blood pressure and acid-base balance without significant immune or sensory functions. B. The respiratory system not only mediates gas exchange but also conditions and filters inspired air, contributes to vocalization, detects odors, and helps regulate immune responses to inhaled antigens.
C. The respiratory system functions mainly in nutrient absorption and mechanical breakdown of air particles before they reach the lungs.
D. The respiratory system is limited to passive air conduction and has no active role in immune defense or sensory processes.
B. The respiratory system not only mediates gas exchange but also conditions and filters inspired air, contributes to vocalization, detects odors, and helps regulate immune responses to inhaled antigens.
Which of these belong to upper respiratory
A. nasal cavity
B. superior lobe
C. Alveoli
D. Diaphragm
E. Pharynx
A.
E.
Which of these belong to lower respiratory
A. trachea
C. Epiglottis
D. Bronchi
E. Larynx
B.
D.
Are both upper and lower respiratory tract sterile?
No both are not, later days they believed lower to be
Which part facilitate both air conduction and air exchange?
Respiratory bronchioles
Which of the following statements best describes the alveoli and their function within the respiratory system?
A. Alveoli are ciliated airways that warm and filter inhaled air before it reaches the bronchi.
B. Alveoli are terminal respiratory units clustered in alveolar sacs, connected to respiratory bronchioles by alveolar ducts, and serve as the primary site of gas exchange.
C. Alveoli are muscular structures that regulate airflow resistance during exhalation.
D. Alveoli are part of the conducting zone responsible for sound production and immune defense.
A graph shows that the size of deposited particles decreases progressively from the nasal cavity to the alveoli. Which statement best explains this observation?
A. Larger particles are efficiently trapped in the upper airways by mucociliary clearance, while only very small particles can reach the alveoli where air velocity is low.
B. Smaller particles are filtered first in the nasal cavity because they are more easily captured by mucus.
C. The bronchial tree actively expands to trap particles of all sizes equally throughout the airways.
D. Particle size does not influence where particles deposit along the respiratory tract.
A
Because:
The nasal cavity and conducting airways filter large particles (>5 µm) via impaction and mucociliary clearance.
Smaller particles (1–5 µm) settle deeper by sedimentation in bronchioles.
Ultrafine particles (<1 µm) may reach the alveoli, where diffusion dominates due to low airflow velocity. → Thus, particle size decreases with progression down the conduction zones.
Where can you find the highest microbiota density
A. Nasal cavity
B. Nasopharynx
C. Oropharynx
D. Lungs
What 3 physical barriers exit to maintain ariway homeostasis?
mucus
anti microbial peptides
epithelial barrier
Who is producing mucus?
goblet cells & mucus-secreting glands
What are the two main epithelial cells of the respiratory mucosa and what is there function?
Ciliated columnar cells
provide coordinated sweeping motion of the mucus
function as a mucocilary escelator
Airway basal cells
stem cell that differtiate into al epithelial cells type above bronchioles
What are the two secretory epithelial cells of the respiratory mucosa and what is there function?
goblet cells
produce mucins
club cells
producse antimicorbial factors
secretory cells appear in bronchioles & increase in number as goblet cells decrease
What are the 2 nerve associated epithelial cells of repiratory mucosa?
brush cells (tuft cells)
sensory & chemoreceptor cells
promote basal airway reflexes
basal surface from a synapse with an afferent nerve ending
pulmonary endocrine cells
respond to oxygen, stretch and chemical stimuli
What is the function of alveoli and which two celltype exist?
-> terminal air spaces & site of gas exchange between air and blood
type 1 alveolar cells
facilitate gas exchange
no cell division
40% but covr 95 % of aveoli surface
type 2 alveolar cells
60 % onlx 5% surface
secretory cells od srufactants -> resuce surface tension at air and epithelium interface
Where is NALT and where iBALT
NALT -> upper
iBALT -> lower
Which statement best describes the organization and function of secondary lymphoid tissue in the respiratory system?
A. In humans, nasal-associated lymphoid tissue (NALT) forms part of Waldeyer’s ring, including tonsils and adenoids, while in the deeper lungs, inducible bronchus-associated lymphoid tissue (iBALT) forms only after antigenic stimulation.
B. Secondary lymphoid tissue is absent from the upper airways and forms only in adults after repeated infections.
C. NALT and iBALT are both permanently structured lymphoid organs present from birth and independent of antigen exposure.
D. Lung-draining lymph nodes are unimportant for mucosal immunity in the lower respiratory tract because iBALT fully replaces them.
What are the key structural and vascular features of NALT, and how do B and T cells function there?
Location: Upper airways; part of Waldeyer’s ring (tonsils + adenoids).
Structure: Permanent, well-organized secondary lymphoid tissue with distinct B- and T-cell zones.
B cells: Form follicles and germinal centers → differentiate into IgA-producing plasma cells for mucosal defense.
T cells: Mostly CD4⁺ helper cells supporting class switching to IgA and maintaining mucosal memory.
Blood vessels: Rich in high endothelial venules (HEVs) → allow naive lymphocytes from the bloodstream to enter NALT.
Lymphatic drainage: Connects to cervical lymph nodes, enabling immune-cell recirculation.
Function: Constant immune surveillance against inhaled pathogens and antigens.
What are the key features of iBALT, especially regarding B/T cells and its blood/lymph vessel organization?
Location: In the lung parenchyma and around bronchi; forms only after inflammation or infection.
Structure: Inducible and less organized than NALT; develops de novo around small airways.
B cells: Form temporary follicles with germinal centers → produce IgA and IgG locally.
T cells: Include effector and memory subsets (CD4⁺ & CD8⁺) that can be activated locally.
Blood vessels: Develop new vessels resembling HEVs during inflammation → enable lymphocyte recruitment from blood.
Lymphatic vessels: Form alongside to allow antigen and cell drainage to lung-draining lymph nodes.
Function: Provides localized, rapid immune responses in lung tissue after antigen exposure.
Which secondary lymphoid organs ensure that T and B cell memory responses are formed in the airway immune response?
NALT and lung-draining lymph nodes are the main secondary lymphoid sites where T and B cells are activated and differentiate into memory cells after encountering inhaled antigens.
A dendritic cell has taken up an antigen in the nose — which secondary lymphoid organs does it migrate to?Where would it go in the lung?
From the nose: → The dendritic cell migrates to NALT (part of Waldeyer’s ring), where it presents the antigen to naive T and B cellsand initiates adaptive immune responses. → Some antigen-loaded dendritic cells may also traffic to cervical lymph nodes via lymphatic drainage.
From the lung: → The dendritic cell migrates to the regional lung-draining lymph nodes, mainly the hilar and mediastinal lymph nodes. → There, it activates T helper cells, which in turn help B cells undergo class-switching (often to IgA) and memory formation. → If iBALT is present (after infection), dendritic cells can also present antigen locally in the lung tissue.
What are the first line defense cells against airway infection
alveolar macrophages
-> support epitheal inegrity
-> clear senescemt cells and inhaled antigens
What are the second line defense cells against airway infection
Interstital macrophages
-> support stroma and T cells by production of IL-10
->
How do airway macrophages change during inflammation and resolution?
Inflammation: Alveolar macrophages activate and recruit monocytes → become proinflammatory macrophages (release TNF-α, IL-1β, IL-6).
Resolution: Macrophages switch to anti-inflammatory, reparative phenotype → clear apoptotic cells and secrete IL-10, TGF-β, resolvins.
Result: Inflammation ends, tissue heals, homeostasis restored.
What describers what: upper airway homeostasis, lower airway homeostasis, upper airway inflammation, lower airway inflammation
epithelial types: goblet cells …; laminate propria: mucus hypersection, dendritic cells, Macrophage Apoptotic blebbing …
epithelial types: club cells, pulomonary neuroendocrine cells, pulmonary Ionocyrw; laminate propria: dendritic cell, alveolar macrophage, ILC …
epithelial types: dendritic cell, goblet cells..; laminate propria: fibroblast, innate lymphoid cells …
epithelial types: ciliated cell; laminate propria: antigen presenting cells, mast cells..
upper airway inflammation,
lower airway homeostasis
upper airway homeostasis
lower airway inflammation
Which kind of cells does intra-epohtelial t cells mainly express and whcih lampina propria
intra-epohtelia: CD8
lampina propria: CD4
Which immune cells produce IL-10 and TGF beta to maintain immune tolerance in the steady state lung?
macrophages
Treg
How is immune tolerance maintained in the lung?
Through Tregs, anti-inflammatory macrophages, and epithelial-derived signals (IL-10, TGF-β) that limit immune activation against harmless antigens.
What are neuro-immune interactions in the lung?
Neurons and immune cells communicate via neuropeptides and cytokines, coordinating inflammation, mucus secretion, and airway reflexes.
What is the oxygen cascade in health?
The stepwise decrease in O₂ pressure from inhaled air to tissues; ensures oxygen delivery for metabolism and immune function.
How does hypoxia influence adaptive immune responses?
Via HIF-1α, hypoxia promotes proinflammatory Th17 and effector T-cell activity, while reducing Treg function, enhancing inflammation.
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