Matching part: 30
7.3 Animal Hormones and Blood-Glucose Control
Compare hormone classes and nervous signalling, then model antagonistic insulin–glucagon feedback and diabetes.
Estimated time: 86 minutes
IB syllabus: D3.3 · SL and HL
Insulin and Glucagon Form an Antagonistic Control System
Blood glucose normally fluctuates within a regulated range as glucose enters from the intestine, is used in respiration, stored or released. Pancreatic β cells detect rising glucose and secrete insulin. Insulin promotes glucose uptake in responsive muscle and adipose tissue, glycogen synthesis in liver and muscle, and other storage pathways. These effects lower the deviation and reduce further insulin stimulation.
When glucose falls, pancreatic α cells secrete glucagon. In liver, glucagon promotes glycogen breakdown and formation of glucose from non-carbohydrate substrates, increasing glucose release into blood. Insulin and glucagon are antagonistic because their overall effects oppose one another. Negative feedback does not hold glucose at one unchanging number; it limits departures while demand, meals and activity continue to vary.
Blood-glucose feedback laboratory
Set blood glucose, β-cell function and insulin sensitivity to distinguish normal regulation, insulin deficiency and resistance.
Detect · transduce · integrate · respond
Cell communication laboratory
Diabetes Can Reflect Missing Signal or Reduced Response
Type 1 diabetes results from autoimmune destruction of pancreatic β cells, leading to severe insulin deficiency. Without treatment, glucose uptake and storage are impaired, blood glucose rises and glucose may appear in urine. Its osmotic effect increases urine production, producing dehydration and thirst. Cells also shift metabolism, and dangerous ketoacidosis can develop. Insulin replacement and glucose monitoring are essential.
Type 2 diabetes begins mainly with insulin resistance: target tissues respond inadequately even though insulin is produced, and β cells may initially compensate with greater secretion. Over time β-cell function can decline. Genetic predisposition, age, adipose-tissue biology, diet and physical activity influence risk. Calling it simply a lifestyle disease is biologically incomplete and can encourage stigma; modifiable risks interact with inherited and environmental factors.
Persistent high glucose damages blood vessels and tissues, increasing risks to retina, kidney, nerves and cardiovascular system. Management may include dietary pattern, exercise, weight management where appropriate, oral medicines, injected receptor agonists or insulin, depending on disease and individual needs. Continuous glucose monitors measure interstitial glucose and reveal trends, while insulin pumps can automate part of delivery; neither removes the need for feedback-informed decisions.
Correlation Alone Does Not Establish Hormonal Cause
A statistical association between a hormone concentration and disease could arise because the hormone affects disease, disease affects the hormone, or another factor affects both. Stronger causal inference can come from longitudinal data, interventions, mechanistic evidence and genetic variants that alter exposure. Large sample size narrows random uncertainty but does not automatically remove confounding or reverse causation.
Test Yourself
A patient has 10.8 mmol dm⁻³ blood glucose. Treatment and storage responses lower it by 35%. What concentration remains?
Test Yourself
Two patients have the same high fasting glucose. Patient X has almost no circulating insulin; patient Y has high insulin but weak target-cell signalling. Which interpretation is strongest?
Exam questions on this topic
Practice focused questions or see how IB combines this topic with ideas from elsewhere in the course.
Matching parts: 1(e), 1(f), 1(g), 1(h)