Nausea, Vomiting and Pain

Question 1

What is vomiting?

Answer 1

Vomiting (emesis) is a physical act:​

• expels contents of upper GI tract via mouth​
• forceful
• complex, co-ordinated reflexive events​
• associated with sensation of relief

Question 2

What is the relationship between nausea and vomiting?

Answer 2

Nausea is produced by the same stimuli as vomiting​
Nausea is generally a prodrome (premonitory symptom) of vomiting​

Nausea may clear up w/o triggering vomiting​AND vomiting can occur w/o prior nausea- eg sticking finger down throat

Question 3

List some causes of nausea and vomiting

Answer 3

Question 4

Why can obstruction cause vomiting?

Answer 4

Si hay obstruction in your intestines, hay que remove as much of the contents of your GI tract bc peristalsis will keep pushing that stuff down there.​
Your intestine wont be able to pass contents down so it will expand
It will stretch its walls and be v painful- could do a lot of damage.​

Question 5

How does our taste and smell protect us from toxins?

Answer 5

Question 6

How do our gastric and upper GI afferents protect us from toxins?

Answer 6

Gastric & upper GI afferents​ can expel harmful agents before they’re absorbed​
They’re associated w chemoreceptive cells that respond to: ​
naturally occurring toxins​
damaging chemicals​
inflammatory mediators

Question 7

why do some non ingested toxins, eg chemotherapy produce the vomiting reflex?

Answer 7

Chemoreceptor cells sit in the gut wall in tissue w good blood supply.​

Substances mix from capillaries into the ECF that surrounds those key receptive cells.​

So substances circulating in the blood can trigger responses from these cells which trigger responses from the efference. This produces the vomiting reflex.​

Question 8

How does the chemoreceptor trigger zone protect us from toxins?

Answer 8

Chemoreceptor Trigger Zone​
Found in the area postrema in the brainstem. Here the blood-brain barrier is “leaky”, so toxins can enter​
Hay chemoreceptors that can detect toxins in the blood ​
BUT again non-ingested toxins will have the same effect – eg chemotherapy, systemic infection, metabolic disturbance

Question 9

How does the chemoreceptor trigger zone protect us from toxins?

Answer 9

Chemoreceptor Trigger Zone​
Found in the area postrema in the brainstem. Here the blood-brain barrier is “leaky”, so toxins can enter​
Hay chemoreceptors that can detect toxins in the blood ​
BUT again non-ingested toxins will have the same effect – eg chemotherapy, systemic infection, metabolic disturbance

Question 10

How does the vestibular system protect against toxins?

Answer 10

Vestibular system​ is the organ of balance, but also a potent trigger for emesis​
Poisoning produces aberrant activity in vestibular neural pathways:
Axons from the receptors are sent out through the 8th cranial nerve (vestibulocochlear nerve) and straight into the NTS
BUT also triggers nausea and vomiting in response to un-natural motion

Question 11

How does learning and aversion protect us from toxins?

Answer 11

If we survive a mistake we avoid repeating it (unpleasantness reinforces learning) ​
Aversion may hard-wire avoidance​

BUT can create incorrect associations​

Question 12

Describe visceral afferents

Answer 12

Visceral afferents are the sensory nerves that run up into the brainstem.​

They get their input from chemoreceptor cells found in the walls of the stomach and the top of the small intestine.​
Chemoreceptors respond to toxins, irritants, inflammatory mediators.​

Also hay some afferent nerves that have endings that respond to abnormal distension of the GI tract.

Question 13

How does increased intracranial Pa cause nausea and vomiting?​

Answer 13

If intracranial Pa goes up, the brain swells. Extra volume gets squeezed out through the foramen magnum. The brain gets pressed down into area prostrema and the nucleus tractus solitarius.​

Those areas cause aberrant signals that will trigger nausea and vomiting.

Question 14

What is the mechanism of nausea and vomiting?

Answer 14

Our anti-poison defences are co-ordinated by the​ Nucleus Tractus Solitarius (NTS)​

Found in the medulla of the brainstem, it also integrates cardiac, respiratory and gastrointestinal functions

Question 15

Describe the higher centre input for n+v

Answer 15

Question 16

What is important about the area postrema and afferent pathways?

Answer 16

The two pathways that are involved in detecting actual poisons, area postrema and abdominal afferents, use 5-HT3 receptors as a key location.
Therefore 5-HT3 antagonists can be used to treat ONLY these two types of nausea and vomiting

Question 17

How does the NTS prepare for and trigger nausea and vomiting?

Answer 17

Question 18

Why does the NTS stimulate autonomic efferents to trigger nausea?

Answer 18

Increase in salivation gives protective fluid lining to your mucosa if you throw up v acidic stomach contents.​
Constriction in the GIT will reduce absorption from inside the GI tract into the bloodstream. This reduces the amount of toxin that gets into your bloodstream.​

The autonomic efferents also change the pattern of gut motility.

Question 19

Describe various processes controlled by efference in the vagus nerve to trigger nausea.

Answer 19

Question 20

Describe various processes controlled by efference in the vagus nerve to trigger vomiting

Answer 20

Question 21

What do these green pathways represent?

Answer 21

these green pathways come from throughout the GI tract. They’re associated w afferents which can detect damaging stimuli and which project to the spinal cord to the thoracic regions.
They converge onto the greater and the lesser splanchnic nerves.

Question 22

What are receptors for visceral pain?

Answer 22

“Pain” receptors respond to “noxious” stimuli, and are called “nociceptors”​

They respond to:​
Distension- abnormal levels of stretching cause pain​
Inflammation- inflammatory chemicals sensitise nociceptors​
muscle spasm

Question 23

What does this show?

Answer 23

Sensory afferents innervate the wall of the gut and produce action potentials.​

This shows a.potential firing for each level of distension.​
As distension increases, a.potential firing Hz increases.​
In normal distension, a.potentials give feedback to the neural network that controls gut movement, but it’s not producing sensation- you don’t feel anything​

​Once afferent activity reaches higher levels due to abnormal distension, signals are interpreted by the brain as damage to the system. Pain sensation is produced and will increase as a.potential firing rate increases.​

Question 24

What else do nocireceptors respond to apart from distension?

Answer 24

Nociceptors respond to inflammatory mediators, as well as stretching of the gut wall:
Inflammatory mediators are detected by sensitive afferent endings which depolarise​.
These endings release pro inflammatory mediators which increase inflammation again​, which increase depolarization etc- positive feedback

Question 25

What does this demonstrate?

Answer 25

Extra a.potentials from normal distension AND inflammation mean that pain threshold decreases

Question 26

How can the positive feedback loop of inflammation and depolarisation cause Chronic sensitisation of visceral pain?

Answer 26

The positive feedback loop increases responses This can produce long term potentiation of synapses, strengthening and increasing power of the synapses.

Both + feedback in the gut & strengthening of the synapses in the pathway produce bigger responses.​
It may produce a situation where people who have had a trigger which has been cured can STILL continue to feel GI pain.​

Question 27

Describe somatic pain

Answer 27

Pain in a precise area activates somatic nociceptors which project to the spinal cord and enter T3.​
Somatic nociceptors synapse w a pathway that carries the info to the somatosensory cortex.​
In the somatosensory cortex, hay a map of the body (somatosensory homunculus). This helps afferents from various parts of the body terminate in a very organised way.​

This pathway will carry the information to a v precise spot within the chest region of that map. Therefore sera a very highly localized pain sensation at that point.

Question 28

Describe viscero somatic convergence

Answer 28

Viscero-somatic convergence piggy backs onto the somatic pathway​

Hay v few nociceptors which make messy connections.​ This produces activity over an extended part of the somatosensory map.​

Therefore pain sensation is poorly localized, and is referred to the body wall even though it’s coming from a visceral organ.​
This is viscero-somatic convergence and results in referred pain

Question 29

Each organ has a…

Answer 29

Each organ has a specific pattern of referral​

initially the site of the pain is on the dermatome it was linked to in the embryo

Question 30

How does inflammation of the gallbladder lead to shoulder pain?

Answer 30

Referred pain from the gall bladder is in the T9 dermatome bc the gall bladder gets its innervation from T9​

Inflammation of the gall bladder can spread to surrounding structures, eg the diaphragm and parietal peritoneum- these get their innervation from C3 to C5 bc they get their innervation from the phrenic nerve.​

Therefore if gallbladder inflammation worsens/spreads it leads to shoulder pain

Question 31

describe characteristics of visceral pain.

Answer 31