grant

How spinal afferent nerves cause vasodilation of mesenteric arteries [ 2004 - 2006 ]

Also known as: How nerves increase blood supply to protect the gut in times of need

Research Grant

[Cite as https://purl.org/au-research/grants/nhmrc/275530]

Researchers: Prof Simon Brookes (Principal investigator) ,  Prof Ashley Blackshaw

Brief description Healthy function of the gastrointestinal tract requires an adequate blood supply during periods of varying demand. Inadequate blood supply to the gut contributes to disorders ranging in severity from mild through to lethal. Reduced blood supply to the gut is a trigger for multiple organ failure syndrome; a leading cause of death in critically ill patients following major surgery, trauma or haemorrhage. It is believed that damage to the lining of the gut, during periods of reduced flow, trigger inflammatory mechanisms throughout the body. Mesenteric ischaemia is a disorder which occurs as a chronic, non-occlusive form, or as acute episodes, which are often lethal, . Temporary increases in blood supply are also known to play a vital role in protecting the gut from acid, toxins and attack by pathogens. The major mechanism underlying increases in bloody supply is dilation of arterial vessels. This occurs focally, at the site of damage, via local mechanisms, but this is supplemented by a more widespread dilation of arteries upstream, mediated by branches of sensory neurones that innervate blood vessels directly. Currently, there is no information about how these sensory neurones are activated. This is crucial to understand how they work. We hypothesise that these sensory neurones are activated by chemical and mechanical stimuli in the gut wall, which make them release vasodilator chemicals onto the arteries upstream and thus amplify the local increases in blood flow. We will test this by recording from sensory nerves, identifying the ones which project to blood vessels and determine which chemicals and mechanical stimuli they are excited by. We will then fill them with dye, using a method that we have recently developed, to visualise their branching patterns both inside and outside the gut wall. In this way, we will understand how this powerful protective mechanism is activated at times of need, and how it may fail under some circumstances.

Funding Amount $AUD 353,250.00

Funding Scheme NHMRC Project Grants

Notes Standard Project Grant

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