homeostasis

Created by

Rayhaan Damania

Cards (33)

Homeostasis 
The maintenance of a constant internal environment
What homeostasis controls in the human body
Blood glucose concentration
Body temperature
Water levels
Control systems 
Receptors - cells that detect stimuli
Coordination centres - process the information received from the receptors
Effectors - bring about responses to bring the conditions in the body back to optimum levels
Response to a stimulus
1. Receptor cells convert a stimulus into an electrical impulse
2. Electrical impulse travels along sensory neurons to the central nervous system
3. Information is processed and the appropriate response is coordinated
4. Electrical impulse is sent along motor neurons to effectors
5. Effectors carry out the response
Reflex 
Automatic responses which take place before you have time to think
Reflex arc 
1. Stimulus is detected by receptors
2. Impulses are sent along a sensory neuron
3. In the CNS the impulse passes to a relay neuron
4. Impulses are sent along a motor neuron
5. The impulse reaches an effector resulting in the appropriate response
Synapse 
The gaps between two neurons
Reaction time 
How long it takes you to respond to a stimulus
Components of the brain
Cerebral cortex
Cerebellum
Medulla
Challenges in investigating brain function and treating brain damage/disease
It is complex and delicate
It is easily damaged
Drugs given to treat diseases cannot always reach the brain because of the membranes that surround it
It is not fully understood which part of the brain does what
Methods used by neuroscientists to map brain function
1. Studying patients with brain damage
2. Electrically stimulating different parts of the brain
3. Using MRI scanning techniques
Structures within the eye
Retina
Optic nerve
Sclera
Cornea
Iris
Ciliary muscles and suspensory ligaments
Accommodation 
1. To focus on a near object: Ciliary muscles contract, suspensory ligaments loosen, lens becomes thicker and more curved
2. To focus on a distant object: Ciliary muscles relax, suspensory ligaments tighten, lens becomes thinner
Myopia 
Short sightedness - the lens is too curved, so distant objects appear blurry
Hyperopia 
Long sightedness - the lens is too flat, so it cannot refract light enough
Treatment methods for eye defects
Spectacle lenses
Contact lenses
Laser eye surgery
Replacement lens
Thermoregulatory centre 
Monitors and controls body temperature
Has receptors that monitor the temperature of the blood
Has receptors in the skin that send impulses to the thermoregulatory centre
Human body temperature is 37.5 degrees celsius
Mechanisms to increase body temperature
1. Sweat is produced from sweat glands, resulting in increased energy transfer away from body
2. Vasodilation means more blood flows closer to the surface of the skin, resulting in increased energy transfer from the body
Mechanisms to decrease body temperature
1. Sweating stops
2. Skeletal muscles contract rapidly (shivering) to generate heat from respiration
3. Hairs stand on end to create an insulating layer, trapping warm air
4. Vasoconstriction means blood does not flow so close to the surface, resulting in less heat lost
Endocrine system 
Communication system that sends hormones (chemical messengers) around the body
Glands that make up the endocrine system
Pituitary gland
Pancreas
Thyroid
Adrenal gland
Ovary
Testes
The blood transports the hormone to a target organ or tissue where it has an effect
Compared to the nervous system, the hormonal system is much slower but it acts for longer
The concentration of glucose in your blood needs to be kept within a certain limit because glucose is needed by cells for respiration
Pituitary gland 
Secretes anti-diuretic hormone (ADH)
Adrenal gland 
Secretes adrenaline
Involved in the 'fight or flight' response (the body's response to stressful situations)
Ovary 
Secretes oestrogen
Involved in the menstrual cycle and the development of female secondary sexual characteristics
Testes 
Secretes testosterone
Involved in the production of sperm and the development of male secondary sexual characteristics
Control of Blood Glucose Concentration
1. Eating foods that contain carbohydrates increases the glucose levels in the blood
2. If the glucose levels are too high, the pancreas produces the hormone insulin
3. Insulin binds to cell in target organs (muscles and liver) causing glucose to move from the blood into muscle cells for respiration and excess glucose to be converted into glycogen which is stored in the liver
4. The blood glucose concentration is reduced
5. If glucose levels decrease, the pancreas produces the hormone glucagon
6. Glucagon binds to to the liver cells causing glycogen to be broken down into glucose
7. Glucose is released into the blood, increasing the blood glucose concentration
Your blood glucose concentration is kept constant through using these two hormones (insulin and glucagon). They work in a negative feedback loop
Negative feedback loop 
When blood glucose levels increase/decrease, a hormone is secreted to oppose the change. The action of this hormone cannot occur continually because when the blood arrives at a certain glucose concentration the other hormone is produced, resulting in the opposite effect
Type 1 diabetes 
The pancreas cannot produce enough insulin. Blood glucose level can rise to a fatal amount. Glucose is excreted with urine and lots of urine is produced leaving the individual very thirsty. It is treated with insulin injections at meal times, which results in glucose being taken up from the bloodstream. It is also advised to limit the intake of simple carbohydrates which contain lots of glucose