Pathophysiology for Dietetics 2 (Metabolic Stress) PDF

Summary

These notes summarize the concept of metabolic stress, covering physiological responses to starvation and various stresses. They explain the pathophysiology behind critical illnesses, touching on topics like sepsis, SIRS, MODS, burns and surgical procedures.

Full Transcript

Module Name : NDT2359 Pathophysiology for Dietetics 2
Topic Name : Metabolic stress and the critically ill (Part 1)
Lecturer's Name : Dr Chen Seong Ting
Lecturer's Email : [email protected]
 Lesson Outcomes
1. Describe the physiological response to starvation and stress

2. Explain the aetiology, pathophysiology and clinical manifestations of sepsis,
systemic inflammatory response syndrome (SIRS), multiorgan distress syndrome
(MODS), burns, surgery and wound healing
Physiological response to starvation

Starvation Metabolic stress

Inability to use nutrients
Inadequate nutrient supply
appropriately
Adequate intake cannot meet high
demand
Malnutrition
Malnutrition
Physiological response to starvation

Metabolic
Starvation
stress

Key difference
difference in energy and fuel
substrate requirements
Physiological response to starvation

Metabolic
Starvation
stress
Body reduces overall Increased energy
energy needs requirements

Reduces basal metabolic
rate

Fewer calories needed by
body
Physiological response to starvation

Metabolic
Starvation
stress
Primary fuel- Lipids for Primary fuel- Glucose for
energy energy

Next- ketones metabolism Next- Break down of lean
body mass
 Lesson Outcomes
1. Describe the physiological response to starvation and stress

2. Explain the aetiology, pathophysiology and clinical manifestations of sepsis,
systemic inflammatory response syndrome (SIRS), multiorgan distress syndrome
(MODS), burns, surgery and wound healing
Physiological response to stress
Metabolic hypermetabolic, catabolic response
stress to acute injury or disease
Physiological response to stress
Etiology
Metabolic consequence of injury and stress

- Hormone release
- Acute-phase protein synthesis
- Sustained inflammatory response
- Hypermetabolism
- Increased gluconeogenesis
- Shifts in fluid balance
- Decreased urine output
 Physiological response to stress
Clinical Manifestations
Ebb phase Flow phase Recovery or
-Hypermetabolism
resolution phase
-Immediate period after
injury (2–48 hours) -Catabolism Anabolism
-Shock -Altered immune and Normal metabolic rate
-Hypovolemia hormonal responses
-Decreased oxygen to
tissues
-Reduced blood volume
-Decreased cardiac
output
-Decreased urinary output
Pathophysiology of Metabolic Stress
Stress and injury activate the hormones

Glucagon
Cortisol Mobilize nutrient stores to meet the
Epinephrine immediate energy demand
Norepinephrine

Increased glucagon - increases glucose production from amino acids
(gluconeogenesis)

Increased cortisol – increase gluconeogenesis
increase free fatty acid mobilization
decreases overall protein synthesis
increases skeletal muscle catabolism
Pathophysiology of Metabolic Stress
Stress and injury activate the hormones

Glucagon
Cortisol Mobilize nutrient stores to meet the
Epinephrine immediate energy demand
Norepinephrine

Increased epinephrine and norepinephrine
- increases energy by glycogenolysis
- Increases fatty acids release
Pathophysiology of Metabolic Stress
Stress and injury activate the hormones

Glucagon
Cortisol Mobilize nutrient stores to meet the
Epinephrine immediate energy demand
Norepinephrine

Hyperglycemia
- increased gluconeogenesis
- Insulin resistance diminishes insulin effectiveness
Pathophysiology of Metabolic Stress
Stress and injury activate the hormones

Glucagon
Cortisol Mobilize nutrient stores to meet the
Epinephrine immediate energy demand
Norepinephrine

Increased gluconeogenesis
- Relies on protein
- Increased the need of alanine and glutamine to
produce glucose
- Increased skeletal muscle catabolism to release
alanine
- Negative nitrogen balance
Pathophysiology of Metabolic Stress
The immune system reacts to injury and trauma with a systemic
inflammatory response and a subsequent anti-inflammatory response.

The systematic inflammatory response drives the metabolic stress process
and leads to the effect on cell-mediated immunity that increases infection risk.
Pathophysiology of Metabolic Stress

Positive acute-phase proteins
- Markers of immune response and
metabolic stress

- Fibronectin, C-reactive protein,
ceruloplasmin, and serum amyloid A

- Release regulated by cytokines (acts
on target cells and causes
inflammation, fever, loss of appetite,
metabolic abnormalities)
Summary
What are the Metabolic Abnormalities in the
Stress Response
Increased levels of glucagon, cortisol, epinephrine, norepinephrine
Hyperglycemia and insulin resistance
Increased basal metabolic rate
Increased rate of gluconeogenesis
Catabolism of skeletal muscle
Increased urinary nitrogen excretion—negative nitrogen balance
Increased synthesis of positive acute-phase proteins—CRP, fibronectin,
ceruloplasmin
Decreased synthesis of negative acute-phase proteins—albumin, prealbumin