W5 - Microgravity & G-Forces

Question 1

What is effect of Earth’s gravitational field on blood in body?

Answer 1

Pooling of blood in legs
Decreases venous return
Decreases cardiac output

Question 2

What reflex ensures MAP is re-established when going from lying to standing position?

Answer 2

Baroreceptor reflex

Question 3

What is Newton’s Law of Motion?

Answer 3

Any movement causes a force to be exerted upon the body

Question 4

What forces act on pilots in aerial displays/combats?

Answer 4

Transient forces up to 8G, can last several seconds

Question 5

What forces act on people in fairground rides?

Answer 5

Rarely more than 2-3G but can be experienced for minutes and act in all directions

Question 6

When is microgravity or weightlessness experienced?

Answer 6

When body is falling freely

Occurs in manned satellites

Question 7

What is formula for pressure of column of fluid?

Answer 7

P = h x p x C

h: distance measured in direction of acceleration force
p: density of fluid
C: acceleration force acting upon column

Question 8

What is relationship of pressure to acceleration?

Answer 8

Pressure gradient varies in size and direction in accordance with acceleration forces acting upon body

Question 9

What is relationship of pressure to body orientation and acceleration?

Answer 9

Pressure gradient varies with orientation of body with respect to direction of acceleration

Question 10

How do you study increased G-forces?

Answer 10

Subject sits in huge centrifuge

Force exerted determined from radius of turning circle and speed of rotation

Question 11

Why is brain function less susceptible to effects of acceleration than vision?

Answer 11

Perfusion of brain vascular bed is better preserved than that to eyes

Question 12

Describe role of skull and CSF in preserving brain function during acceleration.

Answer 12

Brain surrounded by indistensible skull, centre filled with CSF

Hydrostatic pressure of CSF changes equal to that in BV so little change in BV diameter

Eyes not protected by this mechanism

Question 13

Describe role of arteriovenous pressure difference in preserving brain function during acceleration.

Answer 13

Arteriovenous pressure difference is preserved as venous pressure falls as much as arterial pressure.

Question 14

What happens to blood flow when forces > 5G?

Answer 14

Blood flow drops dramatically

Pressure produced by heart has been largely dissipated by time base of skull is reached so vessels collapsed

Question 15

Describe role of hyperaemia in acceleration.

Answer 15

If brain perfusion does decrease, autoregulation of vascular tone occurs = hyperaemia

Blood flow to brain is maintained although deterioration in mental performance can occur

Question 16

What is the major stimuli to baroreceptor reflex activity?

Answer 16

Blood pressure changes monitored by carotid sinuses

Question 17

What symptoms constitute a grey out?

Answer 17

Peripheral vision is impaired, perception of colour and detail by fovea deteriorates

Question 18

When does a grey out occur?

Answer 18

If subject is suddenly accelerated in headwards direction with a force of 4G

Question 19

What happens to CNS when 4.5 - 5G experienced?

Answer 19

4.5-5G : vision is lost, still conscious = blackout

> 5G: unconsciousness

Question 20

What causes changes to CNS at 4.5-5G?

Answer 20

Inadequate blood flow to eyes, brain

Fall in intraluminal pressure of BV of eyes

Question 21

Why is peripheral vision impaired in a grey out?

Answer 21

Arteries in eye radiate outwards from optic nerve so vessels supplying retinal periphery are longer

Length is associated with resistance, so intraluminal pressures are lower so peripheral vessels are more susceptible to collapse

Pressure across peripheral vessel wall falls below critical closing pressure = retinal blood supply to fail at periphery

Question 22

What is the immediate consequence of headwards acceleration?

Answer 22

Decrease in cardiac output

Acceleration causes internal organs of body to move away from head which reduces intrathoracic pressure

Increased pooling of blood in dependent parts of body = decreases venous return

Question 23

How does acceleration affect breathing movements?

Answer 23

Headwards acceleration, movement of internal organs facilitates inspiration by pulling down diaphragm but hinders expiration

Acceleration away from head produces opposite effect, inspiration becomes difficult

Question 24

How does acceleration affect respiratory gas exchange?

Answer 24

Acceleration in headwards direction accentuates gradients of blood perfusion and alveolar ventilation.
Apex, base function poorly wrt gas exchange.
Alveolar deadspace at apex & venous shunts at base cause hypoxaemia and allow ischaemia to develop

Acceleration in opposite direction, reverses gradients

Question 25

Describe apical alveoli during headward acceleration.

Answer 25

Apical alveoli will be almost fully distended throughout respiratory cycle but receive very little ventilation, zero perfusion so ventilation/perfusion ratio is abnormally high

Question 26

Describe basal parts of lung during headward acceleration

Answer 26

Receive large amounts of blood (possibility of pulmonary oedema) but ventilation is not proportional so lowered ventilation/perfusion ratio

Question 27

What causes the major problems with acceleration?

Answer 27

Redistribution of blood flow in response to pressure changes

Question 28

What body position gives greater tolerance to G-forces?

Answer 28

When in supine position as thickness of body is less than height

Question 29

What methods prevent the fall in CO during acceleration but only last a few seconds?

Answer 29

Transient Valsalva manoeuvres
Shouting
Positive pressure breathing

Question 30

What are Valsalva manoeuvres?

Answer 30

Forced expiration against closed glottis

Question 31

What artificial aid was developed to combat fall in venous return?

Answer 31

Antigravity suit

Question 32

How does antigravity suit work?

Answer 32

Based on principle that immersing person in water counters gravitational effect by producing equal hydrostatic gradient outside body

Prevent venous pooling but also limit the descent of diaphragm

Keeps heart nearer to head so decreasing amount of pressure required to drive blood up to brain

Question 33

What countermeasures can be taken to reduce visual disturbances?

Answer 33

Goggles than enable extra-ocular pressure and pressure surrounding retinal vessels to be changed

Decreases in extra-ocular pressure act to promote retinal blood flow and combat high G forces in headwards direction

Question 34

How do you mimic effects of weightlessness?

Answer 34

Constant bed rest and water immersion techniques

Volunteers tilted at 6 degrees to horizontal

Question 35

Why 6 degrees to horizontal when mimicking weightlessness?

Answer 35

Position carotid sinuses to be level with aortic valve

Reduces pressure difference = 0

Mimics effect of microgravity more accurately

Question 36

How much fluid is redistributed during weightlessness?

Answer 36

2L of body fluids away from dependent parts of body and towards head, neck, thorax

Question 37

What is physical symptoms of weightlessness in the 3 days?

Answer 37

Head, neck feel bloated
Neck veins engorged
Legs become thinner

Question 38

What causes the weightlessness physical symptoms in the 3 days?

Answer 38

Diuresis takes place iniated by incr in pressure in volume receptors in atria, great veins

Decr in ADH, incr ANP

Diuresis corrects excess fluid in thoracic veins and so reduces increased CO and load on heart due to excess venous return

Question 39

What is effect on RBC/WBC count from weightlessness?

Answer 39

Drop in RBC, WBC counts
Production falls by more than decrease in plasma volume
Bone marrow activity almost ceases

Question 40

What is initial CVS change from weightlessness?

Answer 40

Increase in cardiac output due to lack of venous pooling

Question 41

What is impact of correction on CVS during weightlessness?

Answer 41

After correction, CO and HR fall

Adjustment to CVS to microgravity environment

Question 42

What causes adjustment of CVS to microgravity environment?

Answer 42

Decreased sympathetic tone
Increased parasympathetic tone
Reflects the amount of work that must be performed by heart has decreased

Question 43

What happens to CVS after longer periods of weightlessness (>50d)?

Answer 43

Degree of ventricular atrophy occurs

Question 44

What symptoms do astronauts experience the first few days in space?

Answer 44

Giddiness, disorientation, nausea, vomiting

Question 45

What causes astronaut symptoms in first few days in space?

Answer 45

Imbalance between different neural inputs to the brain

Skin, muscle, joint receptors (postural forces) and otolith receptors change considerably

Question 46

What input reflects angular acceleration?

Answer 46

Input from semicircular canals

Question 47

Which inputs relfect the postural forces acting on the body?

Answer 47

Inputs from skin, muscle, joint receptors

Question 48

Which input signals the orientation of the head in a gravitational field?

Answer 48

Otolith receptors

Question 49

What are the inputs that help with spatial orientation and balance?

Answer 49

Angular acceleration: semicircular canals
Linear acceleration and gravity: otolith organs
Proprioceptive system: limb positions
Tactile system: pressure on body

Question 50

What happens to muscles in astronauts in space?

Answer 50

Movement is limited by lack of cabin space
Less need for tonic activity in antigravity extensor muscle
Muscular atrophy occurs

Question 51

What in the urine indicates muscular atrophy is occuring?

Answer 51

Increased excretion of urea in urine

Question 52

What reflexes are exaggerated in continued weightlessness?

Answer 52

Postural reflexes

Question 53

What happens to bones when body is in microgravity?

Answer 53

Demineralisation of bones occurs at unchanged rate throughout period

Question 54

How do you measure loss of bone material?

Answer 54

Measured directly from densometric studies of individual bones

Indirectly from rates of urinary excretion of hydroxyproline & calcium

May increase incidence of renal calculi

Question 55

Which bones are most affected by demineralisation in microgravity?

Answer 55

The bones that normally bear weight of body

Question 56

What is rate of mineral loss in bones in microgravity?

Answer 56

0.5% of total per month

Danger of fractures when return to normal 1G environment 2 y after being in space

Question 57

What is the main issue of humans adjusting to microgravity environment?

Answer 57

Being able to withstand gravitiational field on return to earth

Question 58

What actions do astronauts do after return to earth?

Answer 58

Drink copiusly
Kidneys conserve salt
Number of circulating reticulocytes increases as anaemia is corrected

Question 59

How many months after return to Earth does it take astronauts to recover?

Answer 59

5 months

Osteoporosis is never fully corrected

Question 60

What countermeasures can be used to minimise side effects of microgravity?

Answer 60

Suction device = blood pooling in legs
Constant load suits
Bicycle ergometer/springs/isometric contractions
Exercise apparatus adapted so muscles pull against each other

Question 61

What countermeasures used just before astronaut return reduce CV deconditioning ?

Answer 61

Wear antigravity suits

Have body fluid volume deliberately expanded by drinking saline

Question 62

What is issue with countermeasures of antigravity?

Answer 62

Effect is not continuous
Gravity exerts effect continuously
Duplicate this by creation of artifical gravity by imparting spin to spacecraft