Term
| some functions of the respiratory system |
|
Definition
| -Ventilation (breathing)
-Gas exchange
-O2 utilization and CO2 production
[image]
[image] |
|
|
Term
| how the respiratory system functions for ventilation (breathing) |
|
Definition
To move air into and out of respiratory system.
[image] |
|
|
Term
| how the respiratory system functions for gas exchange |
|
Definition
-External respiration
-Internal respiration
-Pressure gradients generate diffusion
[image] |
|
|
Term
| how the respiratory system functions for O2 utilization and CO2 production |
|
Definition
Cellular respiration
[image] |
|
|
Term
|
Definition
gas exchange between air and capillaries in the lungs
[image] |
|
|
Term
|
Definition
gas exchange between systemic capillaries and tissues of the body
[image] |
|
|
Term
| 2 zones in the airway passages |
|
Definition
-Conducting zone
-respiratory zone
[image] |
|
|
Term
|
Definition
-Outside the lungs – nasal passages --> pharynx --> epiglottis --> larynx (glottis)
-Inside the lungs – trachea (1) --> bronchus (2 branches) --> bronchiole --> … --> terminal bronchiole
[image] |
|
|
Term
|
Definition
Respiratory bronchiole --> … --> alveolar sacs
[image] |
|
|
Term
| diameter, length, number, and area of different parts of the airway |
|
Definition
|
|
Term
| how collapsing of the trachea and the rest of the conducting zone is prevented |
|
Definition
| rings of cartilage around the trachea and bronchi |
|
|
Term
| Functions of the Conducting Zone of the airways |
|
Definition
-Passage of air
-Warming
-Humidification
-Filtration
-Immune surveillance
[image] |
|
|
Term
| where does the water for humidification in the airway come from? |
|
Definition
|
|
Term
| the role of the mucociliary apparatus |
|
Definition
removing particulates in the conducting zone
-you wind up either swallowing it or coughing it out
[image] |
|
|
Term
| Functions of the Respiratory Zone |
|
Definition
-Passage of air
-Gas exchange
-Immune surveillance
[image] |
|
|
Term
| number, size, and shape of alveoli |
|
Definition
| -Total # = ~300 x 106
-0.25 - 0.5 mm in diameter
-Total area = 60 - 80 m2
[image] |
|
|
Term
| the 2 types of cells in the alveolar wall |
|
Definition
-Type I alveolar cells
-Type II alveolar cells
[image] |
|
|
Term
| function of Type I alveolar cells |
|
Definition
the major lining cells, accounts for 95-97% of total surface area
[image] |
|
|
Term
| function of Type II alveolar cells |
|
Definition
production of surfactants
[image] |
|
|
Term
|
Definition
-~0.3 μm
-barrier between blood and air that allows gas exchange to occur
[image] |
|
|
Term
| depiction of the net capillaries form over the alveoli |
|
Definition
|
|
Term
| depiction of the air-blood barrier |
|
Definition
|
|
Term
| the Layers of the respiratory membrane: |
|
Definition
1. Fluid layer with surfactant. (Surfactant coats the inside of the alveolus).
2. Type I alveolar cell membranes.
(3. Narrow interstitial space, if any.)
4. Capillary endothelial cell membranes.
[image] |
|
|
Term
| depiction of the thoracic cavity in its context |
|
Definition
|
|
Term
| Thoracic cavity surrounded by... |
|
Definition
rib cage (chest wall) and the respiratory muscles.
[image] |
|
|
Term
| Pleural (intra-pleural) space |
|
Definition
-Thin fluid layer between visceral pleura covering lungs (visceral) and parietal pleura lining thoracic cavity walls.
-*Air-free, potential space --> lungs cling to inside of thorax.
-basically makes the lungs adhere to the thoracic cavity
[image][image] |
|
|
Term
|
Definition
muscle between thoracic & abdominal cavities
[image] |
|
|
Term
|
Definition
-active process:
1. Contraction of diaphragm --> ↑ thoracic vol vertically
2. Parasternal and external intercostals contract --> raising the ribs --> ↑ thoracic vol laterally (horizontally); makes the rib cage bigger
[image] |
|
|
Term
|
Definition
muscles between the ribs that cause the thoracic cavity to expand horizontally (laterally)
[image] |
|
|
Term
| the 2 types of expiration in breathing |
|
Definition
-quiet expiration
-forced expiration
[image] |
|
|
Term
|
Definition
| passive process, relaxation of inspiratory muscles.
[image] |
|
|
Term
|
Definition
| active process assisted by the abdominal muscles.
[image] |
|
|
Term
| some functions of the respiratory system |
|
Definition
| -Ventilation (breathing)
-Gas exchange
-O2 utilization and CO2 production
[image]
[image] |
|
|
Term
| how the respiratory system functions for ventilation (breathing) |
|
Definition
To move air into and out of respiratory system.
[image] |
|
|
Term
| how the respiratory system functions for gas exchange |
|
Definition
-External respiration
-Internal respiration
-Pressure gradients generate diffusion
[image] |
|
|
Term
| how the respiratory system functions for O2 utilization and CO2 production |
|
Definition
Cellular respiration
[image] |
|
|
Term
|
Definition
gas exchange between air and capillaries in the lungs
[image] |
|
|
Term
|
Definition
gas exchange between systemic capillaries and tissues of the body
[image] |
|
|
Term
| 2 zones in the airway passages |
|
Definition
-Conducting zone
-respiratory zone
[image] |
|
|
Term
|
Definition
-Outside the lungs – nasal passages --> pharynx --> epiglottis --> larynx (glottis)
-Inside the lungs – trachea (1) --> bronchus (2 branches) --> bronchiole --> … --> terminal bronchiole
[image] |
|
|
Term
|
Definition
Respiratory bronchiole --> … --> alveolar sacs
[image] |
|
|
Term
| diameter, length, number, and area of different parts of the airway |
|
Definition
|
|
Term
| how collapsing of the trachea and the rest of the conducting zone is prevented |
|
Definition
| rings of cartilage around the trachea and bronchi |
|
|
Term
| Functions of the Conducting Zone of the airways |
|
Definition
-Passage of air
-Warming
-Humidification
-Filtration
-Immune surveillance
[image] |
|
|
Term
| where does the water for humidification in the airway come from? |
|
Definition
|
|
Term
| the role of the mucociliary apparatus |
|
Definition
removing particulates in the conducting zone
-you wind up either swallowing it or coughing it out
[image] |
|
|
Term
| Functions of the Respiratory Zone |
|
Definition
-Passage of air
-Gas exchange
-Immune surveillance
[image] |
|
|
Term
| number, size, and shape of alveoli |
|
Definition
| -Total # = ~300 x 106
-0.25 - 0.5 mm in diameter
-Total area = 60 - 80 m2
[image] |
|
|
Term
| the 2 types of cells in the alveolar wall |
|
Definition
-Type I alveolar cells
-Type II alveolar cells
[image] |
|
|
Term
| function of Type I alveolar cells |
|
Definition
the major lining cells, accounts for 95-97% of total surface area
[image] |
|
|
Term
| function of Type II alveolar cells |
|
Definition
production of surfactants
[image] |
|
|
Term
|
Definition
-~0.3 μm
-barrier between blood and air that allows gas exchange to occur
[image] |
|
|
Term
| depiction of the net capillaries form over the alveoli |
|
Definition
|
|
Term
| depiction of the air-blood barrier |
|
Definition
|
|
Term
| the Layers of the respiratory membrane: |
|
Definition
1. Fluid layer with surfactant. (Surfactant coats the inside of the alveolus).
2. Type I alveolar cell membranes.
(3. Narrow interstitial space, if any.)
4. Capillary endothelial cell membranes.
[image] |
|
|
Term
| depiction of the thoracic cavity in its context |
|
Definition
|
|
Term
| Thoracic cavity surrounded by... |
|
Definition
rib cage (chest wall) and the respiratory muscles.
[image] |
|
|
Term
| Pleural (intra-pleural) space |
|
Definition
-Thin fluid layer between visceral pleura covering lungs (visceral) and parietal pleura lining thoracic cavity walls.
-*Air-free, potential space --> lungs cling to inside of thorax.
-basically makes the lungs adhere to the thoracic cavity
[image][image] |
|
|
Term
|
Definition
muscle between thoracic & abdominal cavities
[image] |
|
|
Term
|
Definition
-active process:
1. Contraction of diaphragm --> ↑ thoracic vol vertically
2. Parasternal and external intercostals contract --> raising the ribs --> ↑ thoracic vol laterally (horizontally); makes the rib cage bigger
[image] |
|
|
Term
|
Definition
muscles between the ribs that cause the thoracic cavity to expand horizontally (laterally)
[image] |
|
|
Term
| the 2 types of expiration in breathing |
|
Definition
-quiet expiration
-forced expiration
[image] |
|
|
Term
|
Definition
| passive process, relaxation of inspiratory muscles.
[image] |
|
|
Term
|
Definition
| active process assisted by the abdominal muscles.
[image] |
|
|
Term
|
Definition
-At a constant temperature P1V1 = P2V2
-Thoracic expansion and contraction -> air movement
-pressure and volume have an inverse relationship in the lungs
[image] |
|
|
Term
| How do we get O2 into the body and CO2 out of the body? |
|
Definition
-Ventilation = air in and out of lungs
-Results from pressure differences (gradient) induced by changes in lung volumes
-Pressure (P) gradient – results in net gas flow & diffusion from high P to low P
[image] |
|
|
Term
| flow of O2 and CO2 in respiration |
|
Definition
| -For PO2 – alveolar space > blood plasma > interstitial fluid > cytosol > mitochondria
-For PCO2 – mitochondria > cytosol > interstitial fluid > blood plasma > alveoli
-this flow is caused by partial pressures
[image] |
|
|
Term
| the 3 pressures to follow in respiration |
|
Definition
-Atmospheric
-Alveolar (Intrapulmonary)
-Pleural (Intrapleural)
[image] |
|
|
Term
|
Definition
|
|
Term
| Alveolar (Intrapulmonary) pressure |
|
Definition
at rest, during inspiration, during expiration
[image] |
|
|
Term
| Pleural (Intrapleural) pressure |
|
Definition
at rest, during inspiration, during expiration
[image] |
|
|
Term
| the 3 phases of breathing |
|
Definition
-at rest
-inspiration
-expiration
[image] |
|
|
Term
| the interplay between the recoil of the lungs and the chest wall |
|
Definition
| -The lung tends to recoil inward and the chest wall outward
-*These recoil forces in opposite directions create a negative (sub-atmospheric) pleural pressure: -3 to -4 mm Hg relative to atmospheric and alveolar pressures.
+-> Lungs expand and contract along with the thoracic cavity.
[image] |
|
|
Term
| What happens if the pleural space is disrupted by air or fluid? |
|
Definition
lungs basically collapse due to the greater pleural space
-Air (pneumothorax) or fluid (hydrothorax, generically) -> relative negative pressure lost -> lung lobes collapse.
-New pressure gradient -> pneumothorax.
[image] |
|
|
Term
|
Definition
separates each side of thorax; this is why only one lung is affected by the disruption of the pleural space
[image] |
|
|
Term
| Mechanics of Breathing (Ventilation) during inspiration |
|
Definition
-Contraction of inspiratory muscles --> ↑ chest vol --> ↑ pleural vol --> ↓ pleural P --> ↑ lung vol --> ↓ alveolar P
---> atmospheric P > alveolar P --> generation of pressure gradient --> air to flows into the lung
-Energy -> muscular contraction -> works against the elastic recoil forces of the lung. |
|
|
Term
| Mechanics of Breathing (Ventilation) during expiration |
|
Definition
-↓ lung vol --> ↑ alveolar pressure above atmosphere (alveolar P > atmospheric P) --> air goes out
-Elastic recoil forces of the lung contribute to change in pressure gradient. |
|
|
Term
| how alveolar and pleural pressure change during inspiration and expiration |
|
Definition
|
|
Term
|
Definition
ALWAYS lower than alveolar P & atmospheric P
-ALWAYS negative (sub-atmospheric) |
|
|
Term
|
Definition
| may be “-” (inspiration) or “+” (expiration) |
|
|
Term
|
Definition
Trans-pulmonary P = Δ P across the wall of the lung
Δ P across the wall of the lung = Alveolar P – Pleural P
-Always positive
-Increasing difference vs. decreasing difference. |
|
|
Term
|
Definition
-tidal vol (TV)
-inspiratory reserve vol (IRV)
-expiratory reserve vol (ERV)
-residual vol (RV)
[image] |
|
|
Term
|
Definition
-inspiratory capacity (IC)
-functional residual capacity (FRC)
-vital capacity (VC)
-total lung capacity (TLC)
[image] |
|
|
Term
| Timed vital capacity (or forced expiration volume for the 1st second, FEV1) |
|
Definition
normal is > 80%
-this is the amount of air you can force out of your lungs within the first second of a forceful breath out
-can be used to assess lung function
[image] |
|
|
Term
|
Definition
the volume of gas inspired or expired in an unforced respiratory cycle at rest
[image] |
|
|
Term
|
Definition
the volume of gas remaining in the lungs after a maximum expiration
[image] |
|
|
Term
|
Definition
the total amount of gas in the lungs after a maximum inspiration
[image] |
|
|
Term
|
Definition
the maximum amount of gas that can be expired after a maximum inspiration
[image] |
|
|
Term
|
Definition
regions of the airways that are ventilated but no gas exchange occurs
[image] |
|
|
Term
|
Definition
anatomic dead space + alveolar dead space
[image] |
|
|
Term
|
Definition
| -*Air in the conducting airways of respiratory system that does NOT participate in the gas exchange.
-Not all of the inspired air reaches the alveoli.
-Inhaled fresh air mixed with expired air in anatomical dead space.
[image] |
|
|
Term
| Alveolar or functional dead space |
|
Definition
-*Air in the respiratory zone that is ventilated but does NOT participate in gas exchange.
-Due to lack of blood flow to those alveoli.
[image] |
|
|
Term
| Ventilation-Perfusion Ratio (V/Q) |
|
Definition
| -VA = alveolar ventilation
-Q = blood flow
-For efficient gas exchange (O2 in, CO2 out), want level of ventilation to match blood flow in alveoli. V/Q ≈ 0.8
-VA is greater in the apices of the lungs -> high V/Q – overventilated and underperfused
-Q is greater in the basal lung lobes -> low V/Q – underventilated and overperfused
[image] |
|
|
Term
| the part of the lungs that is overventilated and underperfused and why that is |
|
Definition
| VA is greater in the apices of the lungs -> high V/Q – overventilated and underperfused
[image] |
|
|
Term
| the part of the lungs that is underventilated and overperfused and why that is |
|
Definition
Q is greater in the basal lung lobes -> low V/Q – underventilated and overperfused
[image] |
|
|
Term
| ideal Ventilation-Perfusion Ratio (V/Q) |
|
Definition
| 0.8
-For efficient gas exchange (O2 in, CO2 out), want level of ventilation to match blood flow in alveoli. |
|
|
Term
| why putting COVID-19 patients on their sternum helps them breathe |
|
Definition
| because it helps open up some lung space on the dorsal side |
|
|
Term
| what Systemic arterioles (e.g., muscle beds) do in response to low arterial O2 levels (PaO2) |
|
Definition
| they dilate if arterial O2 levels (PaO2) are low -> more blood with O2 delivered. |
|
|
Term
| what Pulmonary arterioles do in response to alveolar O2 (PAO2) levels |
|
Definition
| they constrict if alveolar O2 levels (PAO2) are low. Dilate if PAO2 high.
[image] |
|
|
Term
| the factors affecting ventilation |
|
Definition
-compliance
-elastance (elasticity)
-surface tension |
|
|
Term
|
Definition
distensibility (stretchability)
-Change in lung vol per change in transpulmonary P
+Compliance = ΔV/ΔP
-100 x more distensible than a balloon
-Compliance is affected by elastance (2) ; and surface tension (3) |
|
|
Term
|
Definition
recoil ability, resistance to distension
-Elasticity = 1/compliance
-Tendency to return to initial size after distension.
-High content of elastin proteins
-Elastic tension ↑ during inspiration and ↓ during expiration |
|
|
Term
| Compliance is affected by... |
|
Definition
-elastance
-surface tension |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
Reflects the work needed to ↑ surface area of a liquid at an interface.
[image] |
|
|
Term
|
Definition
P in alveoli is directly proportional to surface tension; and inversely proportional to radius of alveoli.
-T is the same for same interface.
-For the same T, smaller alveoli have higher P to collapse than larger alveoli.
-r=2 (P=T) vs. r=1 (P=2T) --> collapse of smaller alveoli
-↑ P --> ↓ compliance --> takes more energy to expand.
[image] |
|
|
Term
| equation for the Law of Laplace |
|
Definition
P = (2 x T) / r
where P = pressure, T = surface tension, and r = radius
[image] |
|
|
Term
|
Definition
-Produced by type II alveolar cells (pneumocytes).
1. Phospholipids – amphipathic; act as surfactant
2. Surfactant proteins – help distribute phospholipids.
[image] |
|
|
Term
| functions of surfactants in the lungs |
|
Definition
-Lower surface tension --> ↑ compliance.
-Prevent collapse of smaller alveoli.
+As alveoli radius decreases, surfactant’s ability to lower surface tension increases. |
|
|
Term
| Newborn respiratory distress syndrome |
|
Definition
-Occurs in ~10% of premature neonates.
-Underdeveloped anatomy.
-Surfactant insufficiency; not enough surfactant and thus less compliance, making it harder to breathe.
-Every breath is like the first breath.
[image][image] |
|
|
Term
| how the alveoli in Newborn respiratory distress syndrome differ from those in healthy newborns |
|
Definition
|
|
Term
| some ways Newborn respiratory distress syndrome can be treated |
|
Definition
-administering surfactants endotrachially
-corticosteroids; stimulate development of type I and type II pneumocytes |
|
|
Term
| Restrictive Disorders (breathing) |
|
Definition
| -Ex., pulmonary fibrosis
-Accumulation of fibrous connective tissue in alveolar wall.
-↓ vital capacity; normal FEV1; ↓ compliance
-*Reduced lung volume
[image] |
|
|
Term
| examples of restrictive pulmonary disorders |
|
Definition
|
|
Term
| the phase of breathing affected by restrictive disorders |
|
Definition
|
|
Term
| Obstructive Disorders (breathing) |
|
Definition
| -Ex., asthma, cystic fibrosis
-Vital capacity may be normal; FEV1 is < 80%
-*Reduced airflow
[image][image] |
|
|
Term
| examples of pulmonary Obstructive Disorders |
|
Definition
|
|
Term
| the phase of breathing affected by obstructive disorders |
|
Definition
|
|
Term
|
Definition
-alveolar tissue is destroyed, compliance
-Chronic progressive; reduces surface area for gas exchange
-Cigarette smoking --> ↑ WBC proteinases secretion --> ↑ destruction tissue proteins ↑ collapse of alveolar sacs
[image] |
|
|
Term
|
Definition
chronic obstructive pulmonary disease
-Asthma & emphysema |
|
|
Term
|
Definition
| the law of partial pressures
-The pressure exerted by each component in a gaseous mixture is independent of other gases in the mixture, and the total pressure of the mixture of gases is equal to the sum of the separate pressures.
-PB = PCO2 + PO2 + PN2 + PH2O = 760 mm Hg atmospheric pressure (PB = barometric pressure
-Movement of individual gases |
|
|
Term
|
Definition
C = kP
-Concentration of gas in liquid = solubility x partial pressure in liquid.
-At equilibrium, partial pressure is equal on both gas and liquid sides, but # of molecules varies depending on solubility of the gas.
[image] |
|
|
Term
|
Definition
C = kP
Concentration of gas in liquid (C) = solubility (k) x partial pressure in liquid (P) |
|
|
Term
|
Definition
| dissolved in blood plasma |
|
|
Term
| depiction of how partial pressures dictate the movement of O2 and CO2 |
|
Definition
| [image]
PA = partial pressure alveolar
Pa = partial pressure arterial
Pv = partial pressure venous |
|
|
Term
| blood flow rate in pulmonary vs. systemic circulation |
|
Definition
Rate of blood flow through the pulmonary circulation = flow rate through the systemic circulation
that is, the amount of blood entering the pulmonary circulation is equal to the amount of blood entering the systemic circulation |
|
|
Term
| depiction of the path blood takes from the tissues --> right heart --> lungs --> left heart --> tissues |
|
Definition
[image]
Please know the path of blood through the heart, lungs, and systemic circulation. |
|
|
Term
| why Pulmonary vascular resistance is lower than systemic vascular resistance |
|
Definition
because of less smooth muscle in the pulmonary vessels
this may be to prevent rupture of vessels in the lungs |
|
|
Term
| the pressure gradient for O2 is 64, but the one for CO2 is only 5, so why does it work? |
|
Definition
| because CO2 has a much higher diffusion rate in fluid/tissue phase vs. O2
Solubility coefficient CO2/solubility coefficient O2 = 0.57/0.024 = 23.75/1
-Need a much higher diffusion gradient for O2 to supply enough molecules to tissues to produce ATP.
-Much lower diffusion gradient for CO2 needed to bring enough molecules to lung for exhalation. |
|
|
Term
| where the O2 is in the blood |
|
Definition
| -Dissolved O2 (< 2%)
-Hb-O2 (> 98%) |
|
|
Term
| amount of hemoglobin in red blood cells and how much O2 they carry |
|
Definition
| 280 million Hb/Red Blood Cell
-Each Hb has 4 polypeptide chains (2 alpha, 2 beta) and 4 hemes
-*1 heme binds to 1 O2, thus 1 Hb binds to 4 O2 maximally
[image] |
|
|
Term
|
Definition
| ↓ RBCs -> [Hb] below normal |
|
|
Term
|
Definition
| ↑ RBCs -> [Hb] above normal |
|
|
Term
|
Definition
| controls Hb production
-Production stimulated by PCO2 delivery to kidneys |
|
|
Term
| some types of hemoglobin associated with health problems |
|
Definition
-Methemoglobin
-Carboxyhemoglobin |
|
|
Term
|
Definition
| Fe2+ oxidized -> Fe3+, cannot bind with O2
-Brown blood, brownish-blue mucous membranes
-this can be caused by nitrates and other substances that can oxidize hemoglobin
-can be treated by reducing agents such as methylene blue and ascorbic acid |
|
|
Term
|
Definition
| (CO-Hb) – carbon monoxide.
-The bond with CO is 210x stronger than the bond with O2.
-Transport of O2 to tissues is impaired.
-the CO can't be used for oxidative phosphorylation |
|
|
Term
|
Definition
| [image]
-X-axis denotes PO2 (mm Hg)
-Y-axis denotes O2 saturation rate (%) or O2 content (mL O2 /dL blood)
-The higher the PO2, the higher Hb-O2 saturation |
|
|
Term
| the pathway by which O2 is loaded onto hemoglobin and the saturation it reaches |
|
Definition
| Gas exchange at alveolar space → loading of O2 → oxygenated blood → PO2 = 100 mm Hg → O2-Hb is ~98%
[image] |
|
|
Term
| the pathway by which O2 is unloaded off of hemoglobin and the saturation it reaches |
|
Definition
| At peripheral tissues → unloading of O2 → deoxygenated blood → PO2 = to 40 mm Hg → O2-Hb is ~ 75%
[image] |
|
|
Term
| why muscles use myoglobin |
|
Definition
| to maintain a steady O2 supply |
|
|
Term
| depiction of the cooperative binding of hemoglobin to O2 and how it changes affinity to O2 |
|
Definition
|
|
Term
| the Hb-O2 Curve shifting to the left indicates... |
|
Definition
| increased affinity of Hb for O2
[image] |
|
|
Term
| the Hb-O2 Curve shifting to the right indicates... |
|
Definition
| decreased affinity of Hb for O2
[image] |
|
|
Term
| what increased affinity of hemoglobin to O2 means in the lungs and tissues |
|
Definition
| -for the lungs, it means loading a little more O2 onto the hemoglobin
-for the tissues, it means more O2 remains on the hemoglobin in the tissues
[image] |
|
|
Term
| what decreased affinity of hemoglobin to O2 means in the lungs and tissues |
|
Definition
| -for the lungs, it means a little less O2 being loaded onto the hemoglobin
-for the tissues, it means a lot more O2 unloaded in the tissues
[image] |
|
|
Term
| when the Hb-O2 curve shifts to the right |
|
Definition
| when there's more need for O2 in the tissues
[image] |
|
|
Term
| some factors that cause the Hb-O2 curve to shift to the right |
|
Definition
| -↓ pH (acidosis) → right shift
-↑ PCO2 (suggests hypoxemia) → right shift (Bohr effect)
-↑ temperature → right shift
-↑ [2,3-DPG] in RBC → right shift
[image] |
|
|
Term
| some factors that cause the Hb-O2 curve to shift to the left |
|
Definition
| -↑ pH (alkalosis) → left shift
-↓ PCO2 (suggests hypoxemia) → left shift (Bohr effect)
-↓ temperature → left shift
-↓ [2,3-DPG] in RBC → left shift
[image] |
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Term
| 2,3-diphosphoglycerate or 2,3 bisphosphoglycerate (2,3-BPG) |
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Definition
-Metabolic by-product of glycolysis in RBCs.
-O2 inhibits its production.
-2,3-DPG binds Hb -> decrease in affinity for O2 -> right shift where more O2 is released in tissues.
-2,3-DPG production ↑ with hypoxemic conditions
+Anemia
+High altitudes
+Some forms of chronic lung disease
[image] |
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Term
| how 2,3-DPG causes right shift in the Hb-O2 curve |
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Definition
| 2,3-DPG binds Hb -> decrease in affinity for O2 -> right shift where more O2 is released in tissues
[image] |
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Term
| some hypoxemic conditions that cause ↑ 2,3-DPG production |
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Definition
-Anemia
-High altitudes
-Some forms of chronic lung disease |
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Term
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Definition
| -Red pigment found exclusively in striated muscle (skeletal and cardiac muscle fibers).
-*Has a higher affinity for O2 than Hb.
[image] |
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Term
| what myoglobin does in muscles |
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Definition
| -Ferrying effect – acts as a “go-between” in the transfer of O2 from blood to the mitochondria within muscle cells.
-O2 storage function – in cardiac muscles. |
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Term
|
Definition
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Term
|
Definition
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Term
|
Definition
|
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Term
| 2 major classes of acids in body |
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Definition
-volatile acid
-non-volatile acid |
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Term
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Definition
| can be converted to a gas
-CO2 in bicarbonate buffer system can be breathed out (lungs). |
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Term
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Definition
cannot leave blood
-lactic acid, fatty acids, ketone bodies
-Need to bind to buffer molecules |
|
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Term
| examples of volatile acids in the blood |
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Definition
| CO2 in bicarbonate buffer system can be breathed out (lungs). |
|
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Term
| examples of non-volatile acids in the blood |
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Definition
-lactic acid
-fatty acids
-ketone bodies
-Need to bind to buffer molecules |
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Term
| Buffers in the body for non-volatile acids include... |
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Definition
| -HCO3–
-PO42–
-proteins including Hb |
|
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Term
| how kidneys help regulate blood pH |
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Definition
| -excrete H+ into urine
-reabsorb HCO3- from urine |
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Term
| the formula for the bicarbonate buffer system |
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Definition
| CO2 + H2O ⇌ H2CO3 ⇌ H+ + HCO3-
[image] |
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Term
| the bicarbonate buffer system the blood uses |
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Definition
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Term
| carbonic anhydrase enzyme (CA) |
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Definition
-Catalyzes reaction both directions.
-Higher expression in RBCs, gastric mucosa, pancreatic exocrine cells, renal tubules.
[image] |
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Term
| Henderson-Hasselbalch equation relating to blood |
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Definition
| pH = 6.1 + log ( [HCO3-] / [CO2] ) |
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Term
| [CO2] is adjusted by ______, [HCO3-] by kidneys |
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Definition
|
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Term
| Free H+ in ______ concentrations, free HCO3- in mmol/L concentrations. |
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Definition
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Term
| What effect does adding HCO3- have on plasma [H+]? |
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Definition
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Term
| What does increased [HCO3-] do to pH? |
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Definition
|
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Term
| What does decreased [HCO3-] do to pH? |
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Definition
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Term
| What effect does adding CO2 have on plasma [H+]? |
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Definition
|
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Term
| What does increased [CO2] do to pH? |
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Definition
|
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Term
| What does decreased [CO2] do to pH? |
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Definition
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Term
| what ventilation adjusts itself to and why |
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Definition
| Ventilation usually adjusted to metabolic rate to maintain normal CO2 levels. |
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Term
| So how would the lungs (controlled by the brain) respond to ↑ plasma [CO2], ↑ plasma [H+], and ↓ plasma pH? |
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Definition
| increase breathing rate to release CO2 and bring the pH back into balance
[image] |
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Term
| And how would the lungs (controlled by the brain) respond to ↓ plasma [CO2], ↓ plasma [H+], and ↑ plasma pH? |
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Definition
| decrease breathing rate to retain CO2 and bring the pH back into balance
[image] |
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Term
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Definition
| -Caused by hypoventilation, which can be caused by CNS depression, neuromuscular disorders, chest wall restriction, pulmonary tissue disease, airway obstruction.
-Accumulation of CO2 in the tissues --> ↑ PCO2 in blood --> ↓ pH in blood |
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Term
|
Definition
| -Caused by hyperventilation, which can be caused by CNS disease, acute asthma, hypoxemia.
-Excessive loss of CO2 --> ↓ PCO2 --> ↑ pH in blood |
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Term
| 3 forms of CO2 that are transported in the blood |
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Definition
| -Dissolved CO2 (10%) – accounts for PCO2
-HCO3- (70%)
-Carbaminohemoglobin (20%)
+Unloading of O2 --> Hb-CO2 formed
+CO2 does NOT bind heme in Hb. |
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Term
| does CO2 bind the heme in hemoglobin? |
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Definition
|
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Term
| how Carbaminohemoglobin is formed |
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Definition
| Unloading of O2 --> Hb-CO2 formed
[image] |
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Term
| Carbonic anhydrase is located in... |
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Definition
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Term
| how bicarbonate (HCO3-) gets transported across the plasma membrane of red blood cells |
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Definition
| Antiporter exchanges chloride (Cl-) for bicarbonate (HCO3-).
[image] |
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Term
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Definition
| hemoglobin with CO2 bound to one of the amino acids |
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Term
| how Cl-/HCO3- exchange differs systemic capillaries and pulmonary capillaries |
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Definition
| Cl- goes into the red blood cell in the systemic capillaries and out of the red blood cell in pulmonary capillaries |
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Term
| how regulation of breathing helps maintain homeostasis |
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Definition
| For metabolic homeostasis, the frequency and amplitude of breathing must respond to metabolic changes. |
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Term
| some sensors involved in regulation of breathing |
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Definition
-Chemoreceptors for chemical changes
-mechanoreceptors for mechanical changes
[image] |
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Term
| the integrator involved in regulation of breathing |
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Definition
|
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Term
| the effectors involved in regulation of breathing |
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Definition
respiratory muscles
[image] |
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Term
| the respiratory centers of the brain stem |
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Definition
-Rhythmicity center (medulla)
-Apneustic center (pons)
-Pneumotaxic center (pons)
[image] |
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Term
| how the brain acts as an integrator in regulation of breathing |
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Definition
| -Continuous display of voluntary and involuntary actions.
-Voluntary action is done by cerebrum, hypothalamus, limbic system (anger).
-Involuntary action is done by the brain stem respiratory centers (medulla oblongata and pons).
-Brain stem respiratory centers
+Rhythmicity center (medulla)
+Apneustic center (pons)
+Pneumotaxic center (pons)
[image][image] |
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Term
| the 2 groups of chemoreceptors that help regulate breathing by monitoring changes in blood PCO2, PO2, and pH. |
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Definition
-Central chemoreceptors
-Peripheral chemoreceptors |
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Term
|
Definition
| -Located in medulla, different from the rhythmicity center.
-More sensitive to blood PCO2 than blood pH (due to the blood-brain barrier (BBB)). |
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Term
| Peripheral chemoreceptors |
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Definition
| -Carotid and aortic bodies
-Directly detect changes in PO2
-Indirectly detect changes in PCO2 through pH
+H2O + CO2 <--> H2CO3 <--> H+ + HCO3-
-More sensitive to changes in blood pH than PO2
[image] |
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Term
| the types of peripheral chemoreceptors |
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Definition
-Carotid bodies
-aortic bodies |
|
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Term
| depiction of chemoreceptor cells and baroreceptor cells |
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Definition
[image]
-Baroreceptors: Carotid sinuses and aortic arch
-Chemoreceptors: Carotid bodies and aortic bodies |
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Term
| Pulmonary Mechanoreceptors |
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Definition
| -Detect mechanical changes of breathing (volume and frequency).
-Influence the brain stem respiratory control centers via sensory fibers in vagus nerves.
-Pulmonary stretch receptors (PSR)
+detect volume changes
+present in the smooth muscle of the airways
+slowly adapting
+activated during inspiration to force expiration |
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Term
| Pulmonary stretch receptors (PSR) |
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Definition
the main type of pulmonary mechanoreceptors
-detect volume changes
-present in the smooth muscle of the airways
-slowly adapting
-activated during inspiration to force expiration |
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Term
| Hering-Breuer inflation reflex |
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Definition
Triggered to prevent over-inflation of the lungs
[image] |
|
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Term
| some types of pulmonary mechanoreceptors |
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Definition
-Pulmonary stretch receptors (PSR)
-Pulmonary irritant receptors (PIR)
-Unmyelinated C fibers |
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Term
| Pulmonary irritant receptors (PIR) |
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Definition
-A.k.a. – rapidly adaptive receptors on Aδ fibers
-Detect frequency of breathing
-Respond to smoke, smog, and particulates -> cause coughing
[image] |
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Term
|
Definition
-Sensory neurons located in lungs
-Stimulated by noxious substances such as capsaicin
-Produces initial apnea -> rapid, shallow breathing
[image] |
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Term
|
Definition
| Located in medulla oblongata
-generate automatic basic rhythm of breathing
-Basic rhythm is irregular, erratic, and unstable. It is NOT the normal rhythm
-Consists of interacting neurons that fire either during inspiration (I neurons) or expiration (E neurons)
-Quiet expiration is a passive process that occurs when the I neurons are inhibited
[image] |
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Term
|
Definition
| interacting neurons in the rhythmicity center that fore during inspiration |
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Term
|
Definition
| interacting neurons in the rhythmicity center that fore during expiration |
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Term
| divisions of the rhythmicity center |
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Definition
-dorsal respiratory group (DRG)
-ventral respiratory group (VRG) |
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Term
| Dorsal respiratory group (DRG) |
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Definition
division of the rhythmicity center that triggers inspiration
[image] |
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Term
| Ventral respiratory group (VRG) |
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Definition
division of the rhythmicity center that triggers expiration when a more forceful expiration is needed
[image] |
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Term
| how the pons regulates breathing |
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Definition
| Basic rhythm generated by the medullary rhythmicity center must be adjusted by pons. |
|
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Term
| the pontine centers involved in regulation of breathing |
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Definition
-Apneustic center
-Pneumotaxic center
[image] |
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Term
|
Definition
Promotes long inspiration and sharp expiration (apneustic breathing).
[image] |
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Term
|
Definition
-Needs to work together with apneustic center.
-Antagonizes the apneustic center’s effects.
-Inhibits inspiration, thus the normal rhythm.
[image] |
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Term
| how the Apneustic center, Pneumotaxic center, Dorsal respiratory group (DRG), and Ventral respiratory group (VRG) interact with each other to regulate breathing |
|
Definition
|
|
Term
| general overview of how everything interacts with each other to regulate breathing |
|
Definition
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