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Title

Phys Block 3-Resp

Description

Forster material

Total Cards

101

Subject

Other

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Not Applicable

Created

04/01/2008

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Term

Avogadro's hypothesis

Definition

For all gases, equal # molecules with same vol. and @ same Temp. will exert equal gas pressure

(i.e. colligative property, not dpendent on quantum features)

Term

Hypoxia vs. hypoxemia

Definition

Hypoxia = low O2 in air
Hypoxemia = arterial blood

Term

All the -pneas:
Eu-
Hyper-
Hypo-
Dys-
Tachy-
A-

Definition

Eupnea=normal (at rest)
Hyperpnea=increased vol./time
Hypopnea=decreased vol./time
Dyspnea=awareness (pathological)
Tachypnea=increased rate
Apnea=cessation

Term

Hypercapnia

Definition

Increased pCO2 in alveolar space and/or arterial blood

Term

Hyperventilation vs. hypoventilation

Definition

Determine ventilation status based on:
pCO₂

Defined as breathing IN EXCESS OF/DEFICIENT FOR metabolic requirements

Term

Example:

Hyperventilation vs. hyperpnea vs. tachypnea

Definition

Hyperventilation=decreased pCO₂ (not always increased pO₂ due to other factors)
Hyperpnea=increased ventilation/time (not in excess of metabolic needs)

Tachypnea=increased breathing RATE (not necessarily hyperpnea or hyperventilation)

Term

Ideal Gas Law (IGL)

Other laws based on it:
Charle's law
Boyle's law
Avogadro's hypothesis

Definition

PV=nRT
R=gas constant (only constant in eq.)

Charle's: if V=constant, P is proportional to T
Boyle's: as gas is compressed, its vol. increases proportionally (P₁V₁=P₂V₂)
Avogadro's: if n=constant, T=constant and V=constant, than P will be also constant (duh)

Term

1 mole of any gas under ideal gas conditions @ 0 C, 760 mmHg:

1. volume
2. number of molecules

Definition

1. 22.4 L
2. 6 x 10²³ (Avogadro's #)

Term

4 stages of respiration:
which use energy?

Definition

1. Ventilation (air from atm into lungs)
2. Pulm. gas exchange
3. Gas transport
4. Periph. gas exchange

1, 3 use energy (metabolic; circulation, pump mm.)

Term

Major point:

What determines arterial blood gas pressures?

Definition

Respiratory system dynamics, NOT Hb!

Ex: case of anemia (arterial gases at normal levels; see difference only in mixed venous blood)

Term

Lung equilibrium volume
vs.
Pleural cavity equilibrium volume

Definition

0% vs. 60%

Net=functional residual capacity (FRC) ~37%

FRC cannot be measured by spirometry b/c it includes residual volume

Term

Respiratory muscles:

1. inhalation
2. exhalation
3. during exercise or pathology

Definition

1. diaphragm
2. passive (except for laryngeal mm. resisting a bit)
3. Inspiration: SCM, scalenes, external intercostals
Expiration: internal intercostals, abdominals

Term

3 important pressures to know:

Definition

1. P_TP=transpulmonary (only fluctuares a little)
2. P_alv=alveolar (fluctuates btw. + and - 1 mmHg)
3. P_pl=pleural (fluctuates the most, always NEGATIVE; diaphragm)

P_TP=P_alv - P_pl

Term

1. What (pressure) causes ventilation?
2. During breathing, why does P alv change LESS THAN P pl?
3. Situation btw. inspiration and expiration=?
4. What happens when P pl EXCEEDS P TP?

Definition

1. P_alv (- @ inspiration, + @ expiration)
2. Energy dissipated in stretching alveoli (elastic recoil energy that is dissipated in expiration (passive)).
3. P_alv=0, so P_pl=P_TP (P_pl represents lung elastic recoil force-i.e. P_TP-in this case)
4. P_alv must be negative, so inspiration happens.

Term

How to calculate airway resistance

Definition

1. There must be airflow for there to be resistance...

R=P_alv/airflow (P_alv calculated from P_pl and P_TP)

Term

Lung volume vs.

1. P pl
2. P TP

Definition

1. As P_pl decreases (becomes more -), LV increases, and decreases as P_pl increases (becomes less -).
2. As P_TP increases, LV increases, and vice-a-versa.

Term

Possible values for:
P _pl
P_TP

Definition

P_pl is negative under normal conditions, but it can become + under FORCED expiration.

P_TP is ALWAYS + (even under forced exhalation conditions, b/c P_alv becomes + enough to compensate for the + P_pl

Term

Saline-filled lung vs. air-filled

Definition

1. Saline-filled lung will have no surface tension to overcome (air-liquid interface eliminated), so only tissue forces need to be overcome (simple inv. parabolic)

2. Air-filled: surface tension AND tissue forces must be overcome, so the curve represents hysteresis (not simple parabolic, but sigmoidal)

Term

Lung compliance in normal px, emphysema and pulm. fibrosis

Definition

Normal, at 60% VC, 10 cm H₂O (collapsing force)
Emphysema: greater compliance, larger vol.
- lungs filled, but no fresh air ciirculates much

Pulm. fibrosis: lower compliance, smaller vol.
Ex: Farmer's lung, Coal Miner's disease (increased PA O₂, decreased PaO₂ and MV O₂; decreased pCO₂)

Term

Chest wall elastic characteristics:
1. at rest
2. @ 0% VC
3.@ 100% VC
4. at equilibrium with lungs (physiological)

Definition

1. 60% VC, no pressure
2. at 0%, exerts -40 cm H₂O filling pressure
3. at 100%, exerts, +15 cm H₂O recoiling pressure
4. At physiological equilibrium: 40% VC, ~-5 cm H₂O

Term

1. What determines airway resistance?

2. What component of the airway has highest resistance? Why?

3. How does lung elasticity counteract airway resistance?

Definition

1. MAJOR: airway diameter (under physiological control; effected by most pathology)
Minor: airway length, gas density
2. Highest=least cross-sectional area (bronchioles)
3. As alveoli fill, there is a large rediction in surface tension, which acts on surrounding alveoli to expand these (+ feedback loop basically)

Term

Airway cellular characteristics based on generation
0-16
17-23

Definition

0=trachea-->16 (bronchioles) "conducting zone"
Have ciliated columnar epithelium, cartilage, SMCs, and Goblet cells

17-23: "respiratory zone"; respiratory bronchioles, alveoli
Have cuboidal-->squamous epithelium (no cilia)

Term

What is the relationship btw. expiratory flow and lung volume?

Definition

As lung volume decreases, so does expiratory flow rate:

1. lung elastic recoil decreases with decreased volume
2. lung elastic recoil pressure/P_TP decreases during expiration

- Net: exp. airflow is greatest at max. lung volume
- Calculate: airflow=P_TP/R

Term

Note: at 40% VC, how does exp. airflow rate depend on effort?

*Equal pressure point effect

Definition

It does not; effort-independent.

Equal pressure point: where P_A=P_pl (any increase in effort (P_pl) is offset by increased compression of airway, which increases R, so airflow doesn't increase)

Term

Max expiratory flow rates in disease:
Emphysema
Pulmonary fibrosis

Exercise vs. rest

Definition

Both=lower max exp. rate

Emphysema: decreased P_A, increased R_A (F=P/R)
Fibrosis: same, but DECREASED volume (opposite)

Exercise vs. rest:
During exercise, inspiratory reserve is favored (b/c R_A is lower at greater Volume_A)

Term

Calculating elastic work and flow resistive work:
from vol. vs. pressure graph

CC examples of increased R_A
How would V vs. P graph change is upper airways were reduced in diameter 90%?

Definition

Elastic is area above/L of lung compliance line, while flow work is to R/below. If UR airways were decreased in diameter, the inspiratory line below lung compliance line would bow out more (more work).
This is an example of an asthma attack

Other examples of increased R_A: emphysema, bronchitis, sleep apnea

Term

1. What is the alveolar filling "time constant"?

2. Implications in tachypnea

Definition

1. Def=rate of alveolar filling when a pressure change is applied

Uneven filling of alveoli

2. at low freq. of breathing, different time constants (and therefore uneven filling) is of no consequence
but at high freq., pendelluft can occur (gas x-change btw. adjacent alveoli instead of common airway)

Effect: reduced alv-cap gas exchange

Term

Graphic/clinical example:
Ratio of dynamic compliance over static
vs.
respiration freq.
(Normal vs. asthmatic people)
1. How will the ratio change with freq. for each population?

Definition

1. Ratio decreases sharply with increased freq. in asthmatics (100-->20), while remaining stable for normal individuals

see pg. 642 of notes

Term

1. FRC
2. RV
3. TLC

Definitions and values.

Definition

1. Functional residual vol=vol. of lungs after expiration with NO RESP. MUSCLE activity (40% TLC=2400mL)

2. residual volume=maximal expiratory muscle contraction (limited by chest wall elasticity)
20% TLC=1200mL

3. total lung capacity=maximal inspiratory muscle activity (100%=~6 L)

Term

Difference between and how to calculate:
1. Dead space ventilation (V_D)
2. Alveolar ventilation (V_A)
3. Pulmonary (Inspiratory) ventilation (V_I)
4. Expiratory ventilation (V_E)
Note: there should be dots over the Vs in these symbols, indicating 1 minute as time dimension/unit

Definition

1. Volume of airways
=V_T x [PaCO₂ - PeCO₂]/PaCO₂
2. Volume of fresh air reaching lungs
=[V_T - V_D] x resp. rate (breaths/min.)
3. Total vol. of air reaching lungs in 1 min.
=V_T x breaths/min.
4. Total vol. of air exiting lungs in 1 min.
=effectively equal, but actually slightly LESS THAN V_I (b/c of the 10:8 O₂:CO₂ usage/production ratio)

Term

Respiratory Quotient (RQ):

1. What does it approximate?
2. Equation

Definition

1. Approximates the metabolic rate (CO₂ production over O₂ consumption)

2. RQ=V_ECO₂/V_IO₂

Term

Difference btw:
1. Anatomical V_D (Bohr equation)
2. Physiologic V_D

Definition

1. V_D calculated from Bohr Eq. (V_D=V_T x [PaCO₂-PeCO₂]/PaCO₂)-->vol. of conductive resp. structures

2. Physiologic V_D=Anatomical V_D + Alveolar V_D(dead space of underperfused alveoli...a fxnal definition of V_D)
Vol. of conductive + unperfused alveolar resp. structures

Term

Alveolar hyperventilation vs. hypoventilation
(define with examples)

Definition

Hyper: increase in PaCO₂
Ex: decr. breathing w/o decr. in metabolic need

Hypo: decreased PaCO₂
Ex: V_A incr. w/o incr. in metabolic rate

Concept: "ventilation" status depends upon metabolic needs

Term

Calculating alveolar gas concentrations using the respiratory quotient (RQ):

1. PaCO₂=?
2. PaO₂=?
3. How does RQ fit in? What does it mean? How does it vary for different caloric sources (diet)?

Definition

1. =V_CO2/[V_A x (P_Atm-47)]...so basically a ratio of metabolism (V_CO2) to metabolic rate (V_A)

2. "Alveolar gas equation" (Wikipedia):
PaO₂=P_IO₂ - PaCO₂/RQ

RQ used to calc. alv. O₂ pressure (based on metabolic rate).
RQ for fats=0.7-ish (varies)
RQ for CHOs=1.0
RQ for proteins/AAs=varies 0.7-1.0
RQs >1.0 mean energy being stored (ex: hibernating bear) or misused (pathological, etc.)

Term

Difference in pressures due to gravity within the lungs:

1. Implications on filling
2. Where does air tend to go after RV at FRC and above? Why?

3. Summarize concisely these results

Definition

1. Upright ONLY: upper lung expanded (higher compliance), lower lung compressed (by weight of lung)-->upper lungs at higher compliance; fill with more air than lower

2. Will go to lower lung more b/c upper lung is already filled with air (at higher compliance), making lower lung compliance greater at larger lung volumes)

3. @ RV, lung weight compresses lower lung, making upper lung compliance greater (air goes to upper), while above RV (FRC and above), the lower lung get more air b/c it is at higher compliance

Upper lung is filled with air and at low compliance under normal resp. contitions

Term

N₂ measurement experiment:
1. Desribe the 4 phases of N₂ exhalation observed
2. How does this example reveal the difference in lung compliances from top to bottom of lung in normal and maximal expiration respiration?

Definition

Phase I: V_D contains no N₂
Phase II: V_D transitioning toV_A ([N₂] rises quickly)
Phase III: [N₂] stable (rising slightly); emptying normal breathing lung vol.
Phase IV: below FRC (to RV), N₂ is high b/c it is coming from upper lung that only ejects air at maximal expirations, so it would've had more time to increase its [N₂], so we see the sharp rise again)
2. The 100% O₂ went to the lower lung more

Term

Closing Volume (CV) of airways in emphysema:

1. How is it changed from normal?

Definition

In emphysema, the CV occurs at a greater lung volume due to the increased tendency for the airways to collapse in emphysema (reduced elasticity-->increased R_A-->collapse incr.)

Term

Differences btw. pulmonary & systemic vasculature:
1. wall thickness
2. compliance
3. pressure (quantitative examples)
4. blood volume

Definition

Referring to pulmonary vessels:
1. thinner walls==>
2. greater compliance
3. lower pressures
RV=20/0 vs. LV=120/5
Pulmonary aa.=20/5 vs. aorta=120/80

4. 10% of blood volume

Term

Visualize graph (p. 649) of pressures in pulm. aa., pulm. capillaries & LA:
1. What are these pressures? How do they change?

2. Graph of LA pressure vs. Pulm. aa. pressure? How does LA affect pulm. aa.?

Definition

1. Pulm. aa.=25/8 right after RV, then this pulse pressure decreases to a constant ~7 mmHg @ the pulm. capillaries, then decr. to LA=5 mmHg (or incr. to LA=10 mmHg, depending; LA=5-10 mmHg range of normal)

2. As P_LA incr., so does P_{pulm aa.} (exponentially!). W/in normal ranges (5-10) for LA, pulm. aa. pressure remains relatively constant, but at higher pressures, it incr. MORE rapidly (exponential)

Term

Effect of P_alv on blood flow in adjacent pulm. capillaries:

(3 zones)

Definition

Zone 1 (upper)=no flow
Zone 2 (middle)=intermittent (P_sys intermittently exceeds P_alv=flow)
Zone 3 (lower)=continuous

Term

Pulmonary vasculature resistance vs. lung volume:

1. Define: alveolar vessels & extraalveolar vessels
2. How does resistance change in each with lung vol.?

3. Graph: which other graph does this graph resemble?

Definition

Alveolar=pulm. capillaries
Extraalveolar=pulm. arterioles & venules

2. During inspiration (lung expansion):
Alveolar R incr. + extraalveolar R decr.
@ RV, R_alv is low & R_extraalv is high, and the reverse at TLC is true. Equilib. in middle

3. Resembles equilibrium graph of breathing freq. vs. elastic+flow resistive work (p. 640 vs. 650)

Term

Graph of blood flow vs. lung region (p. 651):

1. During exercise, what is flow like?
2. What is the abrupt decrease in flow at the very bottom of the lung attributed to?

3. At rest, what % (approx.) of blood flow goes where within the lung?

Definition

1. During exercise,the whole lung=Zone 3 b/c the pulm. pressure is always higher than P_alv

2. May be due to weight of the lung compressing pulm. vessels there (this could be tested while patient lies down, but apparently it has not been done)

3. At rest, ~80% flow goes to bottom, while only ~20% goes to top

Term

1. Is gravity the sole determinant of regional blood flow in the lungs?

2. What is the effect of alveolar hypoxia on pulm. regional blood flow?

Definition

1. Gravity is only secondary. "sequential branching of pulm. vessels" is one hypothesized primary factor

2. With incr. hypoxia (lower pO₂ in alveoli), pulm. vascular resistance (PVR) actually increases. This is exaggerated by decreased pH...seems like a pretty bad call on biology's part...

Term

1. During incr. pulm. bloof flow, what occurs to maintain a long pulm. transit time (of blood)?

2. What is the major factor determining rate of equilibration of gases btw. alveoli & pulm. capillaries?

Definition

1. Pulm. capillaries expand (incr. total of pulm. vasculature), so blood units stay in lungs for longer

2. Binding to protein in blood:
Gases that are not bound (freely circulate) will reach equilibrium rapidly. Ex: N₂O (anesthetic)

Gases that are bound will take much longer (b/c bound gases do not contribute to blood partial pressure of that gas)
Ex: O₂, CO

Term

1. What is the (quantitative) balance of hydrostatic and osmotic forces that keep the lungs dry?

2. Why does pulm. edema not occur until LA pressure exceeds 25 mmHg?

Definition

1. P_c=+7 (lower than systemic's +17.3)
   π_p=-28 (same as systemic)
   P_if=-8 (less than systemic's -3)
   π_if=-14 (WAY less than systemic's +8!)

Favoring filtration: P_c, P_if, π_if (+7 - (-8 - 14))=29
Favoring retention: π_p=28
Net: +1 mmHg favoring filtration (which is cleaned up by pulm. lymphatics (@-5 mmHg) and a very small amt. evaporates thru alveolar surfaces)

2. Lung vasculature HIGH compliance prevents P_c from becoming too high and favoring filtration enough to cause edema...up to a point, which=25 mmHg

Term

1. Why is it ideal for every alveolar-capilary unit to receive the same amount of V_A and cardiac output (Q_c)?

2. Describe what the V/Q ratio means from 0 to ∞. What will pO₂ and pCO₂ be under these conditions?

3. What is the term for the volume occupied by an alveolus that is not ventilated?

Definition

1. If each unit is not receiving the same relative amt. of V_A and Q, then there exists areas of over and under ventilation & perfusion.
V_A adn Q are matched under ideal conditions.

2. V_A/Q ratio is another measure of metabolism/metabolic rate.

When V=0, V/Q=0 (alveolus=atmospheric air pressures)
PAO₂=PaO₂=40 mmHg, PACO₂=PaCO₂=45 mmHg
When Q=0, V/Q=∞ (alveolus=mixed venous blood pressure)
PAO₂=P_BO₂=150 mmHg, PACO₂=P_BCO₂=0 mmHg

When V/Q=1, perfect match (ideal):
PAO₂=100 (P_BO₂=150, PaO₂=40), PACO₂=40 (PaCO₂=45)

3. Alveolar dead space (adds into physiological V_D)

Term

1. What is the term for venous blood exiting the pulm. capillaries that was not ventilated? (p. 655)

2. How do V_A/Q ratios compare regionally w/in the lung? (p. 655)

Definition

1. Venous admixture (gas pressures=mixed venous)

2. See graph p. 655:
Bottom: Q > V_A =0.7 (minimum)
Middle: Q & V lines intersect=1.0 (ideal) at about the level of rib #3
Top: Q < V_A = greater than 1.0 (up to ~4.0)

Note: over a large portion of the lung, there exists a good V_A/Q necessary for gas exchange!

Term

1. How does emphysema affect V_A/Q?

2. What factors contribute to NORMAL and abnormal physiological shunting of blood (avoiding ventilation) (4)?

Definition

1. There is non-uniform time constants distributed unevenly throughout the lung-->uneven ventilation = variable ratio

2. 1. Thebesian circulation (to L ventricle-->coronary sinus-->RA)
    2. Bronchial circ. (emties into pulm. veins) "venous admixture"
    3. Atelectatic/collapsed alveoli (alveolar dead space)
    4. Congenital defects (causing L-R mixing)=abnormal

Term

1. Equation: calculate vol. of a cardiac shunt (away from pulm./ventilation) (Q_shunt & Q_Total)

2. Why is it that once the cardiac shunt reaches ~50% CO (to lungs portion), increasing resp./PAO₂ has little if any effect on PaO₂? (p. 657)

Definition

1.Q_shunt=[O₂]_{end pulm.cap} - [O₂]_arterial
Q_Total=[O₂]_{end pulm.cap} - [O₂]_venous

2. When breathing 100% O₂, every 1% of shunt=20 mmHg decr. PAO₂-->PaO₂. Why? Math unsure...

Term

1. What determines gas diffusion btw. two compartments? Depends on phase?

2. Calculate partial pressures of gases in a mixture. What are %s of N₂, O₂, CO₂ and H₂ in air?

3. Calculate concentrations of gases dissolved in a liquid.
(All p. 658)

Definition

1. Pressure gradient (magnitude of difference in gas pressure) determines diffusion rate

2. Partial pressure=P_B x % comp.
N₂=0.8 O₂=0.21 CO₂=0.003 (0.3%)    (H₂<0.5%)

3. Henry's Law: (Gas pressure @ 760 mmHg; sea level is std.; ex: for O₂=150 mmHg)
   Conc.=Gas pressure x Solubility coefficient (mmHg^-1 =units)
   Solubility coeff. for N₂=.012, O₂=.003, CO₂=.072
CO₂ is 6x more soluble than N₂ and 24x more soluble than O₂.

Term

Name the 2 processes determining lung diffusion rate.

Definition

"Diffusion capacity of lung"=DL
1. Diffusion of gas:
D=ΔP A S/d √MW
ΔP=pressure gradient
A=surface area
S=solubility
d=diffusion distance (thru various tissue layers)
MW=molec.weight (CO₂=44, O₂=32)
2. V_max for Hb binding to O₂ (sigmoidal, cooperative, 4/molecule)

Term

1. How is diffusion capacity determined in the lab?

2. How does diffusion limit O₂ vs. CO₂ in the pulm. capillaries? (p. 661)

Definition

1. Diffusion (D)=V_A/[P_A-P_caps]
(D=total gas x-change/mean capillary gradient)

Note: difficult to measure P_caps for O₂, CO₂, but can approx. for CO b/c Hb reacts with it so readily that it basically =0, so D_CO=V_CO/P_{A, CO})

2. O₂ equilibriates faster, but is MORE affected by a reduction in the rate of diffusion w/in the lung.

CO₂ equilibriates slower (due to complex chemical rxns involving it in the blood), but is LESS affected by diffusion rate limitations.

Term

How do the following affect lung diffusion capacity?

1. Hypoxia
2. Exercise
3. Emphysema
4. Fibrosis
5. High-altitude RESIDENCE

Definition

THINK: D=ΔP A S/d √MW

1. Hypoxia: D=decr. b/c ΔP decr.
2. Exercise: D=incr. b/c A incr. (pulm. cap. dilation)
3. Emphysema: D=decr. b/c A decr. (alveolar coalesce)
4. Fibrosis: D=decr. b/c d=decr. (alveolar membranes thickened by inflammation)

Term

1. Calculate amt. of dissolved (free) and bound O₂ in the blood. What is the total (in mL/dL)?

- Amount of Hb in blood (g/dL)
- Arterial vs. mixed venous P_O2 normal values and % Hb saturation values.
- What does P₅₀ signify?

2. Calculate total O₂ content of blood (CaO₂).

3. What is the difference btw. gas partial pressure & gas content/conc. (in blood)?

Definition

Dissolved O₂=PaO₂ x S   (S=0.003 for O₂ in blood @ 37 C, 760 mmHg)
Bound O₂=[Hb]_blood x 1.34 x
- [Hb]_blood=15 g/dL
- NORMAL: PaO₂= 98 (98), P_mvO₂=40 (75) mmHg (% Hb sat.; SaO₂)
P₅₀ = PaO₂ at which 50% Hb is saturated (or 50% total O₂ binding spots are sat.)

2. Bound O₂=15 x 1.34 x 0.98=19.7 mL/dL
   Dissolved O₂=
   CaO₂=bound + dissolved=20 mL/dL
3. P_p reflects the E_kinetic of dissolved gas (free) in blood, while CaO₂ is total amt. of gas in blood (mL).
So arterial pO₂ means that O₂ at a conc. of 20 mL/dL will exert a pressure of ~98 mmHg on the arterial walls if Hb releases all its O₂ into blood (free).

Term

1. Stuff that affects Hb affinity for O₂:
- Shift direction

2. How is P₅₀ correlated with Hb affinity for O₂?

Definition

1.
Shift curve R=unload O₂ (lower affinity, P₅₀ incr.)
CO₂, H⁺(lower pH <7.35), raised temp., 2,3-DPG
Shift curve L=retain O₂ (higher affinity, P₅₀ decr.)
pH high (>7.45), low CO₂, low 2,3-DPG, low temp.

2. P₅₀ (PaO₂ @ which Hb sat.=50%) is inversely correlated with Hb affinity for O₂.
Example: @ a higher P₅₀, MORE O₂ is req. to saturate Hb to 50%

Term

1. What efect do CO poisoning and anemia have on PaO₂ and CaO₂?
*effective Hb binding curve shifts*

2. Is Hb affinity for O₂ affected in either situation?

Definition

1. Both conditions decrease O₂ content of blood.
SHIFT=R (p. 666)

2. When CO binds Hb, it actually increases Hb affinity for O₂, resulting in even lower tissue pO₂ req. for diffusion of O₂ blood-->tissue.
PaO₂ must decr. to lower values in order to release the same (required=5 mL/dL) amt. of O₂ to the tissue.

Term

1. What factors affect pO₂ in systemic capillaries? How do these factors change during EXERCISE?

2. How is CO₂ transported in the blood (%s)?

Definition

1.)
   1. Metabolic rate   (+ during exercise)
   2. Hb affinity for O₂   (- during exercise)
   3. Blood flow   (+ during exercise)
   4. PaO₂   (NO CHANGE during exercise)
Net: end capillary pO₂ is decreased.

2. 70% HCO₃
    25% bound to Hb
    5% free

Term

1. What is the Haldane effect?

2. What is the chloride shift (in the blood)?

3. What is the importance of carbonic anhydrase in RBCs? What are the effects if this dysfxns?

Definition

1. As Hb becomes more bound to O₂ (incr. PaO₂), Hb binding to CO₂ and H⁺ is decreased.

2. The exchange of Cl^- in plasma, for HCO₃^- in RBCs (purpose: drives CO₂ + H₂O rxn by carbonic anhydrase w/in RBCs)

3. CA converts CO₂ into H₂CO₃ and then HCO₃. If this does not happen, PvCO₂ and free CO₂ in blood INCREASE.

Term

Blood gas values to know:
1. for O₂:
PaO₂, PvO₂, SaO₂, SvO₂, [Hb], dissolved, bound and total/content [O₂]_a and [O₂]_v
2. for CO₂:
PaCO₂, PvCO₂, dissolved and total/content [CO₂]_{a & v}

Definition

PaO₂=95, PvO₂=40
SaO₂=98, SvO₂=75
dissolved [O₂]_a=0.3, dissolved [O₂]_v=0.1
bound [O₂]_a=19.7, bound [O₂]_v=15.1
Total content: CaO₂=20.0, CvO₂=15.2

PaCO₂=40, PvCO₂=45
dissolved [CO₂]_a=2.52, dissolved [CO₂]_v=2.84
Total content: CaCO₂=48, CvCO₂=52

Term

1. Why doesn't the difference CaO₂-CvO₂ = CvCO₂-CaCO₂ (difference in gas contents)

-Respiratory quotient
-Metabolism vs. metabolic rate (difference btw. them)

2. What accounts for the difference btw. pO₂ and pCO₂ btw. arterial and venous systems (difference btw. gas pressures)?

Definition

1. This difference reflects the respiratory quotient (R) (CO₂produced/O₂ utilized).
When R=1.0, only CHOs are being metabolized.
When R=0.7, only fats are being metabolized
(metabolism > metabolic rate; ex: )
When 0.7<R<1.0, protein, fat & CHOs metabolized.

Summary: diff. in CONTENT=diff. in metabolic utilization ratio

2. Difference has to do with the different affinities Hb has for O₂ (preferred substrate) vs. CO₂.
A gas no longer exerts pressure when it is bound to Hb.

Term

1. What are effective ways to increase O₂ delivered to cells (in normal individual)?

2. Explain observed differences in PaO₂, SaO₂ and CaO₂ btw. COPD, anemia and CO poisoning clinical examples.

Definition

1. Increase either [Hb] or blood flow.

2. COPD: decr. CaO₂ (only slight w/in Hb sat. curve that has a small slope (60-100 mmHg), decr. PaO₂, decr. SaO₂.
Anemia: [Hb] decr.-->CaO₂ decr. A LOT, but SaO₂ and PaO₂ REMAIN ~CONSTANT b/c O₂ is getting in and binding normally, but there is less Hb to carry it around in the blood/unit vol.
CO poisoning: everything normal ([Hb], PaO₂, SaO₂) except CaO₂ (b/c CO is taking up spots on all Hb, creating a "virtual anemia" effect, just with normal [Hb]_blood).

Term

1. What are the most common Sx of COPD, CO poisoning and anemia mentioned in lecture?

2. How would administration of 100% O₂ affect the COPD, CO and anemia patients?

Definition

1. COPD=exertional dyspnea (CaO₂ not decr. that much b/c
CO poisoning=headaches, confusion (low CaO₂ only abnormal blood gas property)
Anemia=fatigue, low work tolerance (more severe than in COPD, depending on [Hb], extent of obstr.)

2. This treatment would help most in the CO poisoning case (incr. [O₂] would aid in comp. inhibition @ Hb by CO)...it would help the LEAST for the anemic patient b/c the problem is not with O₂, but with having enough Hb to carry it.

Term

1. What CNS structure(s) exert(s) control over the respiratory muscles?

2. What are the branstem nuclei that control respiration? Where are they located relative to other structures?

3. What are the targets of each of these nuclei?

Definition

1. The cerebrum controls the resp. muscles (thru brainstem intermediate)

2. (1) NPBL (Nuc. parabrachialis)/pneumotaxic ctr.
Located dorsal BS, inf/medial to Inf. Colliculi
   (2) DRG (dorsal resp. group)
          Dorsal, in rostral medulla (level of CN XII)

   (3) VRG (ventral resp. group)
          Ventral, in rostral medulla (level of CN XII)
Note: all resp. nuclei are paired structures.

3. DRG-->Intercostals & DIAPHRAGM (+)
    VRG-->Intercostals (+)
    NPBL-->DRG (-)

Term

1. Resp. control nuclei lesions & brainstem transsections: what the spirometer graph looks like.

Definition

Vagus sets rhythm, cerebrum (-) regulates (slows rate and deepens by resp. mm. ctrl.)

1. Lesions:
NPBL-->loss of resp. mm. inhibition=one big breath
VRG and/or DRG-->no resp. b/c all resp. muscle ctrl. is removed
Vagus N.-->resp. rate SLOWS down & deepens

Transsections:
1. midbrain (elim. cerebral ctrl.)=
2. ponto-medullary jxn (elim. cerebrum & pons)=no regular rhythm anymore
3. caudal medulla (cerebrum + whole BS elim.)=no resp. AT ALL

Term

1. Def: respiratory neuron

2. Use the 2 categorization criteria to classify all respiratory neurons into __ groups.

Definition

1. Any neuron that is active during any phase of the respiratory cycle.

2. 3 categories based on phase timing:
(1) inspiration
(2) late inspiration
(3) expiration
2 more categories based on firing pattern:
(4) incremental (increasing)
(5) decremental (decreasing)
Total classification combos=6 (2 x 3)

Term

1. Difference btw. resp. RHYTHM generator and resp. PATTERN generator(s)? What is the current hypothesis about what these structures are?

2. Where does the "respiratory rhythmogenesis" originate from?

Definition

1. Rhythm generator(s) (RRGs)="trigger" pattern generators
Pattern generator(s) (RPGs)=provide proper sequential activation of resp. pump & LMNs

Rhythm generators=
1. preBotzinger Complex (rostral tip of VRG)
2. another more rostral structure
**These reciprocally coupled and activate the RPG centers together**

Term

1. Where/how are breathing and other behaviors coordinated?

2. What is the difference btw. the 2 competing theories of the model of respiratory rhythmogenesis?

Definition

1. First, a "trigger" (RRG) activates a master pattern generator that provides the proper sequence of activations to achieve the required behavior (ex: sneezing, yawning, vomiting, coughing)

2. (1) Pacemaker: spont. depolarizing neurons reside w/in the pre-Botzinger Complex

(2) Network: through reciprocal inhibition w/in a network of resp. neurons in the CNS

Term

1. Components of the carotid body (4).

2. Innervation of the carotid body (2).

3. Defs: chemoreceptor, respiratory chemoreceptor

Definition

1. chemoreceptor cells (w/ synaptic vescicles in cytoplasm), sustentacular cells (support), capillaries, and sensory neuron dendrites/nerve endings

2. (1) sensory neurons in petrosal ganglion (CN IX) sending fibers via the carotid sinus n.
(2) Sup. cervical ganglion via ganglioglomerular nn. (p. 679)

Term

1. Which "chemicals" does the carotid body respond to?

2. Effect of surgical removal of carotid body.

3. Roles of carotid body in resp. regulation/ctrl (5).

Definition

1. Responds to hypoxia (stronger) and hypercapnia (weaker response).

2. (1) transient hypoventilation, then (2) attenuated sensitivity to CO₂.

3. (1) O₂ chemoreceptors, (2) CO₂ chemoreceptors
   (3) stabilize/regularize resp. (to elim. variations in pO₂ and pCO₂ breath-to-breath)
   (4) tonic excitatory input to medullary neurons
   (5) high-alt. acclimatization

Term

1. Medullary neurons' chemoreceptors: sensitive to what "chemicals", relative sensitivity?

Which causes the greater (+) ventilatory response: resp. acidosis/hypercapnia or metabolic acidosis? Why?

Definition

1. Have BOTH CO₂-H⁺ and O₂ chemoreceptors. Respond stronger to resp. acidosis and hypercapnia than to metabolic acidosis

So...theory is that medullary neurons' chemoreceptors must be responding to intracellular rise in CO₂/H⁺ (b/c metabolic is just H⁺ in intercellular spaces, while resp. acidosis "carries H⁺ into cells" via CO₂ diffusion...same for hypercapnia).

Term

1. Experiment: cooling (temp.) medullary neurons in anesthetized and awake goats:

2. Experiment: cooling VRG neurons in goats with intact or removed carotid bodies.

What are the results and implications of these experiments?

Definition

1. After cooling, anesthetized goats exhibited sustained apnea (awake recovered firing after decrease in freq.)

2. Cooling in both cases caused a reduction in freq. of firing from VRG (reflecting decreased resp.). This decr. was accentuated in carotid body-lacking goats.

Meaning: (1) VRG neurons--> (+) respiration
(2) Not only CO₂-H⁺ chemoRs, but ALSO carotid body chemoreceptors influence VRG neurons (+)
(3) VRG lies w/in the rostral medulla-->rostral spinal cord (caudal terminal)

Term

1. There are at least 3 (+)/excitatory inputs into the respiratory control center: name them.

Importance?

2. Clinical conditions that are relevant to this concept.

Definition

1. Carotid chemoreceptors
2. Ventrolateral medullary neurons (likely part of the RTN; retrotrapezoidal nuc.)
3. Wakefulness centers (?)

Importance: when all 3 inputs (-), the RG-RG system is non-functional.

CC: relevance to conditions like sleep apnea, Sudden Infant Death Syndrome & Cong. Central Alveolar Hypoventilation.

Term

1. Relative to norma, how do P_CO2 and P_O2 change in (1) hypercapnia (inspiring CO₂-rich air) and (2) hypoxia (inspiring O₂-poor air)? Why?

2. What undelies the observed incr. in ventilation (both situations)?

Definition

1. Breathing CO₂: incr. P_CO2 (due to air), incr. P_O2 (due to hyperventilation)

Breathing O₂-poor air: P_O2 decr. (due to air), P_CO2 decr. (due to hyperventilation reducing relative proportion of CO₂ to all gases in alveoli)

2. carotid chemoRs (quick rxn), intracranial chemoRs (have a more latent rxn/effect on V_E (p. 686)
Major point: both hypoxia & hypercapnia incr. ventilation/min. This hyperventilation (resp. in excess of metabolic need) causes an incr. in P_O2 and a decr. in P_CO2 (effect of taking in more air).

Term

1. What are some similarities btw. hypercapnia and COPD?

2. How would you characterize [H⁺] status in the case of hypercapnia or hypoxia (quantitative measure)?

Definition

1. Really, only the hypercapnia (incr. P_ACO₂).

2. In resp. acidosis, every +1 mmHg of CO₂ translates roughly into a decrease in pH of ~0.01.
hypercapnia=resp. acidosis
hypoxia=resp. alkalosis (acute) (b/c P_CO2 decr.)

Term

1. Why is V_E incr. MORE in hypercapnia than hypoxia?

2. What happens in CHRONIC alveolar hypoventilation?

Definition

1. CO₂ is more important of a controller of resp. in eupneic breathing than O₂ (diff. in sensitivities of the 2 sets of chemoRs).

2. Kidneys make more HCO₃^- (to compensate for incr. H⁺), CO₂-H⁺ chemoRs become desensitized, pH is almost returned to normal (by kidney comp.).

Term

1. Phases of resp. adaptation in chronic hypoxia.

2. From these phases, what is the major coping mechanism for prolonged hypoxia?

3. What is the major mechanism for altitude acclimatization in humans (which phase represents)?

4. What phase represents those living at high altitude?

Definition

1. I: initial hyperpnea (carotid O₂ chemoR activation)
II: return to normal (CO₂-H⁺ chemoR attenuation + hypoxic brain depression)
III: second period of hyperpnea (incr. carotid chemoRs)
IV: return to normal (carotid chemoR attenuation)

2. chemoR desensitization/attenuation (CO₂-H 1st)
3. Phase 3: carotid chemoRs incr. sensitivity
4. Phase 4: attenuated carotid chemoRs (this only occurs in high alt. residents)

Term

1. Def: hypoxic brain depression

2. How are SIDS and hypoxic brain depression possibly related?

Definition

1. the direct depressant effect of low [O₂] on neuron excitability (lowered).

2. Decr. excitability of resp. neurons is one of the postulated causes of Sudden Infant Death Syndrome (SIDS); esp. RRG neurons.

Term

1. Name the hypothesized causes of SIDS (7).

2. Name the symptoms of CCAH (3) and treatment (also, 3 physiologically normal processes).

Definition

1. (1) low CO₂-H⁺, (2) carotid hypoxic chemoR sensitivity, (3) hypoxic brain depression (esp. resp. ctrs.), (4) failure of sleep arousal mechanisms, (5) airway obstruction, (6) airwayR inhibition of resp.

2. Congenital Central Alveolar Hypoventilation (CCAH):
(1) absent CO₂-H & (2) carotid hypoxic chemoRs, (3) central sleep apnea
Normal: exercise hyperpnea, airway reflexes & resp. mechanics

Tx=diahragm pacing, mechanical vent. during sleep (these px have constant dyspnea, i.e. they need to consciously think about resp. or they will not do it)

Term

1. Name the stages of sleep (5). Include SWS, periodic breathing and regular breathing in descrip.

2. What is RIP? How does it work?

Definition

1. Non-REM: 4 stages
1-2=periodic breathing (fluctuates regularly)
3-4=slow wave sleep (SWS); regular breathing
REM=5th stage
...then arousal.

2. Resp. Inductance Plethysmography (RIP): non-invasive way to measure resp. (elastic band inductance measured-->stretch changes inductance in band around abdomen/chest)

Term

1. How does breathing change during REM?

2. How does overall ventilation compare btw. the different stages of sleep?

3. What is paradoxical thoracoabdominal movement?

Definition

1. Breathing is irregular in timing and amplitude during REM.

2. V_E is highest during wakefullnes, lowest during NREM (SWS esp.), and intermediate during REM.

3. When abdominal and thoracic movements are opposite (abd. incr. in diameter, while chest decreases, for example)

Term

1. What is central apnea? How is it defined?

2. What is obstructive sleep apnea? What differentiates this from central sleep apnea syndrome (CSAS)?

Definition

1. Failure of RRG mechanisms manifested in a lack of thoracic & abdominal motion/resp. mm. inactivity.
"Central Sleep Apnea Syndrome"

2. Cessation of airflow despite continued resp. pump muscle activity. Paradoxical thoracoabdominal wall movements noted as well (p. 693).

Notes: SaO₂ decreases in apnea

Term

1. 2 primary locations of obstruction in sleep apnea.

2. What causes these obstructions?

3. Statistics of OSA in the U.S.

4. Symptoms of OSA (6) and treatments.

Definition

1. retropalatal=soft palate
retroglossal=back of tongue

2. Loss of rhythmic & tonic genioglossal m. activity, or anatomical abnormalities, loss of protective resp. reflexes

3. 15% of adults in the USA!

4. Sx: hypoxemia, psychiatric disorders, hypertension, daytime somnolence, incr. symp. nerve activity

Tx: surgery, tracheotomy, + pressure breathing, oral mechanical devices

Term

1. What is Cheyne-Stokes respiration?

2. What might cause it? Under what conditions does this type of resp. occur in normal and diseased px?

Definition

1. Periodic breathing: (longer) phases of hyperpnea and apnea.

2. Might be caused by increased gain of carotid chemoRs resulting in PaO₂ "over corrections"
When: high alt. (first few days), CHF, unstable sleep states

Term

1. Lung defense mechanisms: (1) in conductive resp. system, (2) in respiratory system (x-change area).

2. What is the primary surface tension-reducing component of surfactant?

3. Of the protein component of surfactant, which have immune fxn and which have surface tension-reducing fxns?

Definition

In conductive: ciliated eipthelium (mucociliary clearance), coughing, sneezing, etc.

In resp. part: Type II alveolar cells (secrete surfactant; 90 lipids/10 protein). Type I cells form structure of alveoli. Neutrophils and alveolar macrophages (dust cells) also protect. Opsonins (immunoglobulins).

2. Dipalmitoylphosphatidylcholine (DPPG) (50% of 90% lipids=45% surfactant)

3. Surfactant proteins (SPs):
SP-A, SP-D=collectin family of immune proteins that have CHO recognition sites-->promote phago by coating viruses & bacteria
SP-B, SP-C=essential to fxn of surfactant (incr. rate of spreading over alveolar surface)

Term

Airway reflexes: which ones cause which responses:
1. epipharyngeal
2. laryngeal
3. pharyngeal
4. nasal

Which reflexes utilize (1) slowly adapting, (2) rapidly adapting and/or (3) c-fiber neurons?

Definition

1. Epipharyngeal=aspiration reflex (indicated by brief incr. in phrenic n. activity)
2. Laryngeal=apnea reflex (water injected into larynx=no phrenic n. activity (apnea/prolonged expiration; "clearing airway")
3. swallowing
4. sneezing, "diving reflex"

Slow: bronchodilation, tachycardia

Rapid + C-fiber: bronchoconstriction, mucus secretion, pulm. chemoreflex, bradycardia

Term

1. Are the "lung irritant receptors" slowly or rapidly adapting receptors?

2. Compare: Hering-Breuer deflation vs. inflation reflexes
(1) types of fibers carrying signals
(2) function

Definition

1. rapidly adapting

2. H-B reflexes use stretch receptors in lung smooth muscle to prevent overinflation and over-deflation of the lungs.
Deflation reflex:
(1) BOTH slow & rapidly adapting receptors (stretch and other proprioceptor receptors in lungs)
(2) prevents over-deflation

Inflation reflex:
(1) slowly adapting receptors (stretch)
(2) prevents over-inflation

Term

CNS pathway for resp. reflexes/neural control of respiration/lung volumes:

1. nerve carrying signals
2. CNS target(s)
3. descending controller(s)

Definition

1. Stretch receptor afferents in vagus n.
2. Vagus n. afferents (incr.)-->excites pontine apneustic resp. ctrl. center (in NTS).

3. NTS (once excited) inhibits Nuc. ambiguus
4. Nuc. ambiguus is responsible for tonic inhibition of heart rate (its efferents also carried by vagus n.)

Net result: increased pulm. stretch-->incr. HR
(Deflation reflex is just decr. vagal n. afferents from lungs)

Term

Mechanism whereby ventilation increases during work is still unknown.

5 observations regarding work-induced hyperpnea:
1. temporal pattern of V_A
2. blood gases
3. temporal pattern of Resp. Quotient (R)
4. electrically-induced exercise
5. paraplegic subject + electrically-induced exercise

Definition

1. V_A exhibits (1) sharp initial increase, (2) slower increase to strady state by ~90 sec
2. blood gas homeostasis until about 60% maximal exertion
3. R constant until ~60% maximal exertion (then increases due to hyperventilation; mechanism unknown)
4. ventilatory response does not differ btw. voluntaryelectrically-induced exercise (not central ctrl.-dependent) and
5. paraplegics exhibit same ventilatory response as patients in #4

Implications:
1. fast & slow components
2. hyperpnea not a result of incr. chemoR activation
3. hyperventilation above 60% max exertion
4. ventilation not dependent on central ctrl.
5. ventilation not dependent on spinal afferents

Term

1. Whatvalue determines if V_A has been changed?

2. In a patient with low Pa_CO2 and high Pa_O2 (hyperoxia), what is then driving respiration if not chemoRs?

Definition

1. PaCO₂ (Normal a=40, mv=45)

2. This would describe a case of hyperventilation (V_A/V_CO2 elevated relative to normal). Stress or a brainstem lesion (BSL) could be driving resp.

Term

1. Importance of maintaining a relatively constant [H⁺]

2. What is "physical-chemical H⁺ buffering"?

3. What are the primary buffering systems in the ECF vs. the ICF?

Definition

1. optimal enzyme fxn/protein stability
CC: high [H⁺]=decr. neuron excitability (membrane channels)=coma (vs. low [H⁺]=seizures)

2. Fancy term for buffering

3. ECF=HCO₃^-, H₂PO₄, proteins⁽⁺⁾
ICF=proteins, H₂PO₄

Term

1. How to distinguish btw. resp. and metabolic acidosis

2. What is the "isohydric principle"?

3.

Definition

1. Given low pH (acidosis), if CO₂ is also elevated, then it is most likely respiratory.

2. Concept that all buffer pairs existing within body fluid compartments are in equilibrium with the same pH (same compartment) and bind H⁺ according to their pK_a. When [H⁺] is altered, so to will be all the buffer pairs in sol'n.

Term

1. What determines buffering capacity for a given buffer pair?

2. When is a buffer at optimal buffering capacity (relative to pH of sol'n)?

3. What is "physiological buffering"?

Definition

1. (1) buffer concentration, (2) difference btw. pH of sol'n and pKa of buffer

2. When sol'n pH=pKa of buffer (equal amt. of A/B in solution)

3. Physiological buffering is the body's ability to generate buffer pairs from existing chemicals within the body fluids.

Term

1. Plasma [H⁺] regulation mechanisms:
(1) transmembrane: ECF-ICF
(2) pulm. ventilation
(3) physiological buffering

Definition

1. (1) ICF has lost of buffers, ECF has less, so H⁺ is exchanged for either Na⁺ or K⁺ from inside cell.
(2) Excess acid (H⁺) can be eliminated via conversion to H₂CO₃-->H₂O + CO₂.
(3) Generation of HCO₃ from Gln in the kidney and excretion of acid using NH₃ as a buffer (ammonia excretion)

Term

1. The body makes strong organic acids daily. What limits the body's ability to buffer these acids?

2. During acidosis, what role does the BBB play in regulating CSF pH? How effective?

Definition

1. The amt. of HCO₃ available to buffer the H⁺ made by the body...hence, the kidney's ability to make HCO₃ from Gln (primarily; brain also can do this) and then excrete the by-product ammonia.

2. The BBB limits passage of medium-sized uncharged and all charged particles (like H⁺), so the change in pH in the CSF is only 10% of the change in pH seen systemically.

Term

1. The BBB is an ineffective barrier against resp. acidosis & alkalosis (gases are membrane-permeable). What does the brain do to regulate its pH in these situations?

2. Given a strong acid IV injection, what buffer systems will handle this (temporal sequence)?

Definition

1. During resp. acidosis: glial cells make NH₃
During alkalosis: they make lactic acid

2. First 30 min.=HCO₃ in plasma (depleted)
After couple hours=H⁺/Na, K ECF-ICF exchange (transmembrane exchange now compromised)
Days=kidneys will make more HCO₃ to restore equilibrium, transmembrane gradients, and buffering capacity of blood to normal.
kidney=ultimate corrector of A/B disturbances

Term

1. What is normal [HCO₃^-] in mM/L? How would a decreased [HCO₃] affect pH?

2. An elevated or lowered pH would cause mental confusion/lethargy?

3. What is the cause of posthypercapnic alkalosis?

Definition

1. Normal=20-24 mM/L. Decreased [HCO₃] would result in decreased pH (b/c it is buffering H⁺).

2. Lowered CSF pH=mental lethargy (decr. neuron excitability).

3. Renal compensation for resp. acidosis by increasing [HCO₃].

Term

1. What is cor pulminale? What can it be a complication of (a resp. disease)? What are other common comorbidities of this disease?

2. What are the symptoms of acute vs. chronic bronchitis?

3.

Definition

1. Cor pulmonale=R-sided heart failure (common w/ COPD). Also: URTI/URIs (upper resp. tract infections) and bronchitis.

2. acute=days-wks., chronic=persistent, productive sputum for at least 3 mo. or a 2 yr. period

Term

CC: COPD patient

1. Why elevated HCO₃?
2. Why hypercapnia after admin. O₂ supplement air?
3. Why the transient decrease in blood pH?
4. What is the alveolar-arterial oxygen gradient, and what does it indicate?

Definition

1. Renal compensation for chronic resp. acidosis.
2. Unknown: possible mechanisms include incr. Hb O₂ sat. shifting CO2 from Hb to dissolved in blood (decr. pH; Haldane effect), suppressed hypoxic ventilatory reflex/reduced tidal vol./incr. dead space vol. (shallower breathing), etc.
3. due to the hypercapnia
4. Indicates how effectively O₂ is diffusing from air into blood (indicates diffusion capability of lungs).

Term

1. What is status asthmaticus? What is typical presentation and treatment?

2. Lung fxn tests: COPD vs. restrictive lung disease

Definition

1. Asthma attack that has failed to respond to bronchodilator admin. in outpatient setting (puff-puff no work). low pH, A-a mismatch (alv-arterial gradient) due to bronchoconstriction, hyperventilation and hypocapnia. Tx: corticosteriods, O₂ supplemented air, intubation an option.

2. COPD=elevated TLC, RV, FRC
RLD=reduced TLC, FRC, RV

Term

1. OSA and Pickwickian syndrome (Sx, etc).

Definition

1. OSA can cause hypertension, hypersomnolence (daytime), and stress-related comorbidities (incr. weight, asthma, etc.)

Pickwickian syndrome=OSA + alveolar hypoventilation

Pulm. hypertension-->RV hypertrophy, sleep-disordered breathing, nocturnal Hb O₂ desat...

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