NVCC Bio 212

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NVCC Bio 212

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Title: NVCC Bio 212 Subject: Respiratory system Author: Greg Erianne Last modified by: Greg Created Date: 1/14/2003 11:26:13 PM Document presentation format – PowerPoint PPT presentation

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Title: NVCC Bio 212

1
Martinis Visual Anatomy and Physiology First
Edition Martini w Ober
Chapter 20 - Respiratory System Lectures 12 13
2
Midterm Grades
Your midterm grades (due March 28) will be
calculated as follows Lec 1 Exam 100
pointsLec 2 Exam 100 pointsLab 1 Exam
100 pointsLaboratory Grade 25-35 points
(5-7 labs so far)Extra Credit 4 points Total
points possible so far...329-339 points Your
grade (Ex., Total points you have / 330)
100 Note No grades will be dropped for
calculation of midterm grade.
3
Mid-term Checkup
Based on the three (3) grades you have received
so far, you should do a mid-term checkup. To find
your average so far total the following points
Lec Exam 1 Lec Exam 2 Lab Exam 1 Lab points
(6 labs) Example (83 67 90 26) ? 330
0.80 (80) Dropping the low grade (83 90 26)
? 230 0.86 (86) To figure out what you need
to AVERAGE for the next lecture and/or lab exam
and the final COMBINED to get a particular grade
Points desired (see syllabus) Total points so
far
Average grade needed on remaining exams

350 (if no grade dropped) or 450 (if low grade
dropped)
This formula assumes you will have 50 pts for
lab and 6 XC pts at the end of the course
4
Points and Grades (from Syllabus) - Revised
Grade for Course Grade as Points (of a possible 700) Quality Points
A 92-100 644-700 4.0
A- 90-91 630-643 3.7
B 88-89 616-629 3.3
B 82-87 574-615 3.0
B- 80-81 560-573 2.7
C 78-79 546-559 2.3
C 70-77 490-545 2.0
D 68-69 476-489 1.0
D 60-67 420-475 0.7
F less than 60 less than 420 0.0
Example 1 To get a grade of B for the course,
using the example grades on previous slide, and
not dropping lowest grade (50), and assuming 50
pts for lab and 6 XC points
574 (83 67 90 50 6) x
x 0.79 (79) Average on upcoming exams
350
Example 2 To get a grade of B for the course,
using the example grades on previous slide, and
dropping lowest grade (67), and assuming 50 pts
for lab and 4 XC points
574 (83 90 50 6) x
x 0.76 (76) Average on upcoming exams
450
5
Lecture Overview

Lectures 12 13
The breathing mechanism (ventilation)
Respiratory volumes and capacities
Nonrespiratory air movements
Alveolar gas exchange
Transport of O2 and CO2 in the blood
Control of breathing
Factors affecting breathing

6
Gases and Pressure

Our atmosphere is composed of several gases and
exerts pressure
78 N2, 21 O2, 0.4 H2O, 0.04 CO2
760 mm Hg, 1 ATM, 29.92 Hg, 15 lbs/in2,1034 cm
H2O
Each gas within the atmosphere exerts a pressure
of its own (partial) pressure, according to its
concentration in the mixture (Daltons Law)
Example Atmosphere is 21 O2, so O2 exerts a
partial pressure of 760 mm Hg. x .21 160 mm
Hg.
Partial pressure of O2 is designated as PO2

7
Air Movements
If Volume increases, pressure decreases and vice
versa Stated mathematically P ? 1/V (Boyles Law)

Moving the plunger of a syringe causes air to
move in or out
Air movements in and out of the lungs occur in
much the same way

Figure from Saladin, Anatomy Physiology,
McGraw Hill, 2007
8
Lungs at Rest
When lungs are at rest, the pressure on the
inside of the lungs is equal to the pressure on
the outside of the thorax
Figure from Holes Human AP, 12th edition, 2010
Think of pressure differences as difference in
the concentration of gas molecules and use the
rules of diffusion. Higher pressure means higher
concentration (ignoring temperature difference)
9
Normal Inspiration

Intra-alveolar (intrapulmonary) pressure
decreases to about 758 mm Hg as the thoracic
cavity enlarges
Atmospheric pressure (now higher than that in
lungs) forces air into the airways
Compliance ease with which lungs can expand

An active process
Figure from Holes Human AP, 12th edition, 2010
Phrenic nerves of the cervical plexus stimulate
diphragm to contract and move downward and
external (inspiratory) intercostal muscles
contract, expanding the thoracic cavity and
reducing intrapulmonary pressure. Attachment of
parietal pleura to thoracic wall pulls visceral
pleura, and lungs follow.
10
Maximal (Forced) Inspiration
Thorax during normal inspiration

Thorax during maximal inspiration
aided by contraction of sternocleidomastoid and
pectoralis minor muscles

Compliance decreases as lung volume
increases Costal (shallow) breathing vs.
diaphragmatic (deep) breathing
Figure from Holes Human AP, 12th edition, 2010
11
Normal Expiration

due to elastic recoil of the lung tissues and
abdominal organs
a PASSIVE process (no muscle contractions
involved)

Normal expiration is caused by - elastic recoil
of the lungs (elastic rebound) and abdominal
organs - surface tension between walls of
alveoli (what keeps them from collapsing
completely?)
Figure from Holes Human AP, 12th edition, 2010
12
Maximal (Forced) Expiration
Figure from Holes Human AP, 12th edition, 2010

contraction of abdominal wall muscles
contraction of posterior (expiratory) internal
intercostal muscles
An active, NOT passive, process

13
Terms Describing Respiratory Rate

Eupnea quiet (resting) breathing
Apnea suspension of breathing
Hyperpnea forced/deep breathing
Dyspnea difficult/labored breathing
Tachypnea rapid breathing
Bradypnea slow breathing

Know these
14
Nonrespiratory Air Movements

coughing sends blast of air through glottis
and clears upper respiratory tract
sneezing forcefully expels air through the
nose and mouth
laughing deep breath released in a series of
short convulsive expirations
crying physiologically same as laughing
hiccupping spasmodic contraction of diaphragm
against closed glottis
yawning deep inspiration through open mouth
valsalva maneuver expiration against a closed
glottis

15
Alveoli and Respiratory Membrane

consists of the walls of the alveolus and the
capillary, and the basement membrane between
them

Figure from Holes Human AP, 12th edition, 2010
Mechanisms that prevent alveoli from filling with
fluid
1) cells of alveolar wall are tightly joined
together 2) the relatively high osmotic pressure
of the interstitial fluid draws water out of
them 3) there is low pressure in the pulmonary
circuit
Surfactant resists the tendency of alveoli to
collapse on themselves.
16
Just a Quick Review!

Atmosphere is composed of several gases, each
exerting its own partial pressure, PO2
P ? 1/V (Boyles Law)
Inspiration
Normal
Forced or maximal
Expiration
Normal
Forced or maximal
The respiratory membrane for gas exchange

17
Blood Flow Through Alveoli
Mechanisms that prevent alveoli from filling with
fluid

cells of alveolar wall are tightly joined
together
the relatively high osmotic pressure of the
interstitial fluid draws water out of them
there is low pressure in the pulmonary circuit

Low pressure circuit
Figure from Holes Human AP, 12th edition, 2010
18
Diffusion Across Respiratory Membrane
Figure from Holes Human AP, 12th edition, 2010
19
Diffusion Through Respiratory Membrane
The driving for the exchange of gases between
alveolar air and capillary blood is the
difference in partial pressure between the gases.
Figure from Holes Human AP, 12th edition, 2010
At a given temperature, the amount of a
particular gas in solution is directly
proportional to its partial pressure outside the
solution (Henrys Law)
20
Efficiency of Respiratory Membrane Diffusion

Diffusion of gases across the RM of the lung is
efficient due to
Large partial pressure differences
Small distances
Lipid solubility of gases
Large total surface area
Blood flow and air flow are coordinated

21
Composition of Inspired and Alveolar Air
From Saladin, Anatomy Physiology, McGraw Hill,
2007
22
Factors Affecting O2 and CO2 Transport

O2 and CO2 have limited solubility in plasma
This problem is solved by RBCs
Bind O2 to hemoglobin
Use CO2 to make soluble compounds
Reactions in RBCs are
Temporary
Completely reversible

23
Oxygen Transport

Most oxygen binds to hemoglobin to form
oxyhemoglobin (HbO2)
Oxyhemoglobin releases oxygen in the regions of
body cells
Much oxygen is still bound to hemoglobin in the
venous blood

Figure from Holes Human AP, 12th edition, 2010
Tissues
Lungs
But what special properties of the Hb molecule
allow it to reversibly bind O2?
24
Review of Hemoglobins Structure
Figure From Martini, Anatomy Physiology,
Prentice Hall, 2001
25
The O2-Hb Dissociation Curve
Recall that Hb can bind up to 4 molecules of O2
100 saturation At 75 saturation, Hb binds 3
molecules of O2 on average Sigmoidal (S) shape of
curve indicates that the binding of one O2 makes
it easier to bind the next O2
Figure from Holes Human AP, 12th edition, 2010
This curve tells us what the percent saturation
of Hb will be at various partial pressures of O2
26
Oxygen Release

Amount of oxygen released from oxyhemoglobin
increases as
partial pressure of carbon dioxide increases
the blood pH decreases and H increases (Bohr
Effect shown below)
blood temperature increases (not shown)
concentration of 2,3 bisphosphoglycerate (BPG)
increases (not shown)

Figure from Holes Human AP, 12th edition, 2010
27
Carbon Dioxide Transport in Tissues

dissolved in plasma (7)
combined with hemoglobin as carbaminohemoglobin(1
5-25)
in the form of bicarbonate ions (68-78)

CO2 H2O ? H2CO3 H2CO3 ? H HCO3-
Figure from Holes Human AP, 12th edition, 2010
CO2 exchange in TISSUES
28
Chloride Shift

bicarbonate ions diffuse out RBCs
chloride ions from plasma diffuse into RBCs
electrical balance is maintained

Figure from Holes Human AP, 12th edition, 2010
29
Carbon Dioxide Transport in Lungs
Figure from Holes Human AP, 12th edition, 2010
CO2 exchange in LUNGS
30
Control of Respiration

Homeostatic mechanisms intervene so that cellular
gas exchange needs are met
Control occurs at two levels
Local regulation
Lung perfusion (blood flow 5.5 L/min)
Alveolar ventilation (4.2 L/min)
Ventilation/perfusion coupling (matching)
Respiratory center of the brain

31
Local Control of Respiration

Local Control regulates
Efficiency of O2 pickup in the lungs
Lung perfusion (blood flow)
Alveolar capillaries constrict when local PO2 is
low
Tends to shunt blood to lobules with high PO2
Alveolar ventilation (air flow)
High PCO2 (hypercapnia) causes bronchodilation
Low PCO2 (hypocapnia) causes bronchoconstriction
Directs airflow to lobules with higher PCO2
Rate of O2 delivery in each tissue
Changes in partial pressures
Local vasodilation in peripheral tissues

32
Factors Affecting Resistance to Airflow

Diameter of bronchioles
Bronchodilation (epinephrine, sympathetic
stimulation)
Bronchoconstriction (parasympathetic stimulation,
histamine, cold air, chemical irritants)
Pulmonary compliance
Surface tension of alveoli and distal bronchioles.

33
Neural Control of Respiration
Figure from Holes Human AP, 12th edition, 2010
Neural control of respiration has an autonomic as
well as a voluntary component
34
Respiratory Center Autonomic Control
Figure from Holes Human AP, 12th edition, 2010
-
2 sec / 3 sec
-

Apneustic area
Respiratory centers can be facilitated (caffeine,
amphetamines) or depressed (opioids, barbiturates)
35
Factors Affecting Breathing
Central chemoreceptors Respond to PCO2 and pH of
the CSF Effect is actually due to H as
follows CO2 H2O ? H2CO3 H2CO3 ? H HCO3-
Bicarbonate
Carbonic acid
Figure from Martini, Anatomy Physiology,
Prentice Hall, 2001
36
Factors Affecting Breathing
Both central and peripheral chemoreceptors are
subject to adaptation
Decreased blood PO2 or pH (or increased CO2)
stimulates peripheral chemoreceptors in the
carotid and aortic bodies Stimulation leads to
anincrease in the rate and depth of
respiration
Figure from Holes Human AP, 12th edition, 2010
CO2 is the most powerful respiratory stimulant
37
Factors Affecting Breathing

motor impulses travel from the respiratory
center to the diaphragm and external intercostal
muscles
contraction of these muscles causes lungs to
expand
expansion stimulates stretch receptors in the
lungs
inhibitory impulses from receptors to
respiratory center prevent overinflation of lungs
(Hering-Breuer reflex)

Figure from Holes Human AP, 12th edition, 2010
CO2 is the most powerful respiratory stimulant
38
Control of Respiration

Control of respiration is accomplished by
1) Local regulation
2) Nervous system regulation
Local regulation
? alveolar ventilation (O2), ? Blood flow to
alveoli
? alveolar ventilation (O2), ? Blood flow to
alveoli
? alveolar CO2, bronchodilation
? alveolar CO2, bronchoconstriction

39
Control of Respiration

Nervous System Control
Normal rhythmic breathing -gt DRG in medulla
Forced breathing -gt VRG in medulla
Changes in breathing
CO2 is most powerful respiratory stimulant
Recall H2O CO2 ? H2CO3 ? H HCO3-
Peripheral chemoreceptors (aortic/carotid bodies)
? PCO2, ? pH , ? PO2 stimulate breathing
Central chemoreceptors (medulla)
? PCO2, ? pH stimulate breathing

40
Breathing Reflexes

Protective Reflexes
Sneezing - Triggered by an irritation of the
nasal cavity
Coughing Triggered by an irritation of the
larynx, trachea, or bronchi
Both sneezing and coughing involve
A period of apnea
Forceful expulsion of air from lungs opening the
glottis (up to 100 mph or more!!)
Laryngeal spasms chemical irritants, foreign
objects, or fluids into the area around glottis
Temporarily closes the airway
Some stimuli, e.g., toxic gas, can close the
glottis so powerfully that it doesnt open again!

41
Life-Span Changes

reflect accumulation of environmental influences
reflect the effects of aging in other organ
systems
cilia less active
mucous thickens
swallowing, gagging, and coughing reflexes slow
macrophages in lungs lose efficiency
increased susceptibility to respiratory
infections
barrel chest may develop
bronchial walls thin and collapse
dead space increases

42
Clinical Application
The Effects of Cigarette Smoking on the
Respiratory System
Figure from Holes Human AP, 12th edition, 2010

cilia disappear
excess mucus produced
lung congestion increases lung infections
lining of bronchioles thicken
bronchioles lose elasticity
emphysema fifteen times more common
lung cancer more common
much damage repaired when smoking stops

43
Clinical Application
Figure from Martini, Fundamentals of Anatomy
Physiology, Pearson Education, 2006
44
Review

The atmosphere is composed of a mixture of gases
Each gas exerts a partial pressure (Pg)
Sum of all partial pressures atmospheric
pressure (14.7 lbs/in2,760 mm Hg., )
Gases move from a higher concentration (pressure)
to a lower concentration (pressure)
Function of the diaphragm is to create a lower
intrpulmonary pressure so that atmospheric gases
flow into the lungs

45
Review