resp part2 - previous semester *GOOD REVIEW FOR RESP* Flashcards Preview

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1
Q

lung compliance

A

Shows “distensibility” of lungs and chest wall
Is inversely related to elastance, which depends on the amount of elastic tissue
Is inversely related to stiffness

2
Q

In middle range of pressure describe compliance

A

compliance is greatest and the lungs are most distensible

middle range is most compliant

3
Q

At high expanding pressure describe compliance

A

compliance is lowest, the lungs are least distensible , and the curve flattens.

4
Q

Compliance=

A

change in volume of lung (change ofV) for each unit change in pressure (change ofP). Pressure refers to transpulmonary pressure

5
Q

Changes in lung compliance

In patient with emphysema

A

lung compliance is increased and the tendency of the lung to collapse is decreased. Therefore , at original FRC, the tendency of lungs to collapse is less than the tendency of chest wall to expand. The lung-chest wall system will seek a new, higher FRC so that the two opposing forces can be balanced; the patient’s chest becomes barrel-shaped, reflecting higher volume.

6
Q

pneumothorax

A

If air is introduced into the pleural space (pneumothorax), the intrapleural pressure becomes equal to atmospheric pressure. The lung will collapse (its natural tendency ) and chest wall will spring outward (its natural tendency)

7
Q

fibrosis and lung compliance

A

In a patient with fibrosis , lung compliance is decreased and the tendency of lungs to collapse is increased. Therefore, at the original FRC, the tendency of the lungs to collapse is greater than the tendency of the chest wall to expand. The lung-chest wall system will seek a new lower FRC so that the two opposing forces can be balanced.

8
Q

Pleural space is a relative

A

vacuum

9
Q

The negative force always required to keep the lungs open.

A

-5cmH2O

10
Q

Alveolar Pressure

A

It is the air pressure in alveoli
Normally = 0 cmH2O
decrease in inspiration, increase in expiration
During normal quiet inspiration ,it is the major driving force for air flow into the lungs

11
Q

Transpulmonary Pressure =?

A

= Alveolar Pressure minus Pleural Pressure

12
Q

Transpulmonary Pressure -neonates first breath

A

First breath of neonates generates transpulmonary pressure of 40 to 80 cmH2O 

13
Q

Pleural Pressures

Resting ?
Inspiration?

A

Resting -5 cm H20

Inspiration -8 cm H20

14
Q

Alveolar Pressure at:
Resting
Inspiration
Expiration

A

Alveolar Pressure at:
Resting 0 cm H20
Inspiration -1 cm H20
Expiration +1 cm H20

15
Q

Alveolar pressure equals atmospheric pressure and is said to be ?

A

Alveolar pressure equals atmospheric pressure and is said to be zero (no flow)

16
Q

Pleural pressure ?

A

is always negative

17
Q

what is lung volume

A

FRC

18
Q

how do we measure pleural pressure?

A

by a balloon catheter in the esophagus

19
Q

how does the negative pressure get created in the intrapleural space

A

Elastic recoil of lungs trying to collapse and the chest wall trying to expand, creates a negative pressure in the intrapleural space

20
Q

as lung volume increases alveolar pressure becomes what?

A

alveolar pressure decreases to less than atmospheric pressure (becomes negative -1cmh20

21
Q

during inspiration pleural pressures becomes??

A

more negative than it was at rest -5- -8cmh20

22
Q

during expiration alveolar pressure

A

alveolar pressure becomes greater becomes positive +1cmh20 than atm pressure.

23
Q

Intrapleural pressure returns to its resting value during

A

Intrapleural pressure returns to its resting value during a normal (passive ) expiration. However, during a forced expiration, intrapleural pressure actually becomes positive. This positive intrapleural pressure compresses the airways and makes expiration more difficult

24
Q

SURFACTANT is secreted by?

A

type II alveolar cells

25
Q

surfactant is composed of?

A

phospholipid, proteins, and ca++

26
Q

how does surfactant work

A

Lines the alveoli, act as surface tension ‘reducer’ by disrupting the intermolecular forces (hydrogen bond) between the water molecules of liquid-act like “detergent”
This reduction in surface tension prevents small alveoli from collapsing and increases compliance, decrease work of inspiration allowing the lungs to inflate much more easily

27
Q

surfactant Synthesis starts week

A

24 week of gestation

Almost always present at week 35

28
Q

how do we check to see if surfactant is present for fetal lung maturity.

A

Lecithin-to- Sphingomyelin (L/S) ratio of > 2:1 in amniotic fluid is indicative of fetal lung maturity

29
Q

Neonatal respiratory distress syndrome: S&S?

A

Occurs in premature infants because of lack of surfactant. The infant shows atelectasis (lung collapse), difficulty reinflatting the lungs( as a result of decreased compliance) and hypoxemia because of  V/Q

30
Q

neonatal treatment for prematurity

A

Treatment
Maternal steroid shots before birth. This speeds up formation of surfactant in the fetus.
Artificial surfactant to infants by inhalation

31
Q

airflow equation

A

q=change p/R
q=airflow
change p= pressure gradient
r= air way resistant

32
Q

resistance to flow

A

R= resistance
= viscosity of the inspired gas
l = length of airway
r = radius of airway
Notice the powerful inverse fourth-power relationship between resistance and size ( radius) of airways.
If airway radius decreases by a factor of 4, then resistance will increase by a factor of 256(44) and air flow will decrease by a factor of 256

R= 8nl/PIEr4

33
Q

Contraction and relaxation of bronchial smooth muscles

Parasympathetic stimulation

A

irritants, slow reacting substance of anaphylaxis-A (asthma) constrict the airways,  the radius and  the resistance to airflow

34
Q

Contraction and relaxation of bronchial smooth muscles

Sympathetic stimulation

A

and sympathetic agonist dilate the airways , increase radius and decrease resistance to airflow via 2 receptor

35
Q

Low lung volumes

A

are associated with less radial traction and increased airway resistance

36
Q

High lung volumes

A

are associated with greater radial traction and decrease airway resistance. In asthma, pt “learn” to breath at higher lung volumes to offset the high airway resistance associated with their disease.

37
Q

Site of airway resistance

A

The major site of airway resistance in the medium-sized bronchi.
The smallest airways would seems to offer the highest resistance, but they do not, because of their parallel arrangement.

38
Q

“Work” of Breathing

A

During normal quiet condition, respiratory muscles ‘work’ only during inspiration and NOT during expiration.

39
Q

Work of inspiration:

3 things

A

Compliance work
Tissue Resistance Work
Airway Resistance Work

40
Q

Tidal Volume:

A

Tidal Volume: is the volume inspired or expired with each normal breath

41
Q

Inspiratory Reserve Volume

A

Inspiratory Reserve Volume: is the volume that can be inspired over and above the tidal volume. It is used during exercise

42
Q

Expiratory Reserve Volume

A

Expiratory Reserve Volume: is the volume that can be expired after the expiration of tidal volume

43
Q

Residual Volume

A

is the volume that remains in the lungs after a maximum expiration. It cannot be measured by spirometry

44
Q

Helium Dilution Method.

A

Pulmonary Volumes are recorded by Spirometer except Residual Volume which is measured by Helium Dilution Method.

45
Q

Vital Capacity (VC)

A

Is the sum of TV, IRV and ERV.

46
Q

How is pulmonary capacity determined

A

Pulmonary Capacity is combination of two or more pulmonary volumes

47
Q

Inspiratory Capacity

A

TV+IRV

48
Q

Functional Residual Capacity

A

ERV+ Residual Volume

Volume remaining in the lungs after a tidal volume is expired

49
Q

Total Lung Capacity

A

Is the sum of all four volumes.
It is the volume in lungs after a maximum inspiration
“Vital Capacity is everything but the residual volume”

50
Q

Functional Residual Capacity - FRC

A

Volume of air remaining in lung after normal tidal exhalation

Acts as RESERVIOR for O2 during airways obstruction or apnea

Prevents large SWINGS of PO2 by acting as buffer

51
Q

FRC=?

A

ERV+RV

52
Q

FRC is reduced by

A

Supine position
Obesity
Pregnancy
Anesthesia

53
Q

decreased from what 4 things will decrease FRC and predispose a patient to what?

A

Therefore, all these things predispose to HYPOXEMIA

54
Q

Implication: preoxygenation/denitorgenation does what to FRC?

A

PREOXYGENATION / DENITORGENATION before anesthetic induction is very important providing reservoir of O2, as this “fills” the FRC with 100% O2, allowing more time (upto10 min.) for airways manipulation, breath holding episodes etc.

55
Q

FRC Increases by:

A

PEEP , CPAP

Increase airway resistant – asthma

56
Q

Forced vital capacity (FVC)

A

Is the volume of air that can be forcibly expired as hard and as rapid possible, after taking maximum inspiration

57
Q

FORCED EXPIRATORY VOLUME IN 1ST SECOND ( FEV1)

A

Is the volume of air that can be expired in the first second of a forced maximal expiration as hard and as rapid possible

Is normally 80% of the forced vital capacity (FVC)
FEV1/FVC ratio = 4/5= 0.80 (80%)

FEV1 is low in both obstructive and restrictive diseases (trouble is blowing air out

58
Q

obstructive lung diseases what happens in FVC and FEV

A

In obstructive lung diseases such as asthma and COPD, FEV1 is reduced more than FVC so that FEV1/FVC is decreased (hallmark)

59
Q

restrictive lung disease what happens to FVC and FEV

A

In restrictive lung disease such as pulmonary fibrosis, pneumothorax, scoliosis, myasthenia gravis or ALS, both FEV1 and FVC are reduced and FEV1/FVC is either normal or is increased

60
Q

Forced expiratory flow (FEF 25-75) or Midmaximal expiratory flow

A

Is best of accessing small airway disease

61
Q

Obstructive Lung Disease ‘increase resistance to flow’

A

Obstruction of air flow, resulting in air trapping in the lung.

Emptying impaired-high RV , low VC
FEV1/FVC ratio decreases (hallmark)

62
Q

4 Types of Obstructive lung disease :

A

Bronchiectasis
Chronic Bronchitis
Emphysema
Asthma

63
Q

Restrictive Lung Disease ‘stiff lungs, decrease expansion’

A

Restricted lung expansion causes decreased all lung volumes ( VC and TLC), PFTs: FEV1/FVC ratio >80%

64
Q

Poor breathing mechanics (extrapulmonary)

A

Poor muscular effort: polio, M gravis

Poor apparatus: scoliosis

65
Q

Poor lung expansion (pulmonary)

A

Lungs are restricted; cannot expand
Defective alveolar filling: pneumonia, ARDS, pulmonary edema
Interstitial fibrosis: causes increased recoil (decrease compliance), thereby limiting alveolar expansion. Complications include cor pulmonale. Can be seen in diffuse interstitial pulmonary fibrosis and bleomycin toxicity. Symptoms include gradual progressive dyspnea and cough

66
Q

slide 47

A

slide 48

67
Q

PCWP

A

is an indirect measure of ‘left atrial pressure’

normally 10mmhg

68
Q

how do we measure right sided heart catheterization

A

Measure by Right Sided Heart Catheterization (SWAN-GANZ)

69
Q

PWP

A

is used in CHF to study pressure changes in left atrium
decrease BP decrease PCWP = Hypovolemic shock, give fluid
decrease BP increase PCWP = Failing heart, give inotrops

70
Q

Right atrium pressure

A

<5mmhg

71
Q

Right ventricle pressure

A

<25/<5mmhg

72
Q

Left atrium pressure

A

< 12mmhg

73
Q

Left ventricle pressure

A

<150/10mmhg

74
Q

Pulmonary trunk pressure

A

<25/10mmhg

75
Q

Aorta pressure

A

<150/90mmhg

76
Q

PCWP pressure

A

<12mmhg

77
Q

What is PCWP measuring?

A

PCWP (mmHg) is a good approximation of left atrial pressure. Measured with Swan

78
Q

Pulmonary artery Pressures

A
Systolic= 25 mmHg
Diastolic= 8 mmHg
Mean= 15 mmHg
Capillary= 7 mmHg
79
Q

Pressure and Cardiac output in the pulmonary circulation

Pressure

A

Are much lower in pulmonary circulation (15mmHg) than in the systemic circulation (100mmHg)

80
Q

Pressure and Cardiac output in the pulmonary circulation

Compliance

A

Is much higher

81
Q

Pressure and Cardiac output in the pulmonary circulation

Resistance

A

is much lower

82
Q

Pressure and Cardiac output in the pulmonary circulation

Cardiac output of the right ventricle

A

Is pulmonary blood flow

Is equal to CO of the left ventricle

83
Q

In lungs, alveolar hypoxia causes

A

In lungs, alveolar hypoxia causes vasoconstriction

84
Q

This diverts blood away from poorly ventilated, hypoxic regions towards well-ventilated regions of lung leads to?

A

decrease shunting of blood (protective)

85
Q

Fetal pulmonary vascular resistance is very high due to hypoxic vasoconstriction

A

decrease blood flow

86
Q

Oxygenation with first breath decreases pulmonary vascular resistance

A

increase blood flow

87
Q

Global hypoxia (breathing in thin air at high altitude)

A

vasoconstriction of entire lungs leads to pulmonary HTN leads to RVF

88
Q

Pulmonary vascular resistance (PVR)

A

PVR= P pul artery-P l atrium/C0 x 80

89
Q

SVR

A

SVR= MAP-CVP/CO x 80

normal value 900-1200