Organisation

Created by

Anish Subramanian

Cards (77)

Cells 
Make up all living things
Tissue 
A group of specialised cells with a similar structure and function, can be made of more than one type of cell
Tissue examples 
Muscular tissue
Epithelial tissue
Organ 
Formed from a number of different tissues, working together to produce a specific function
Organ example 
Stomach
Organ system 
Organs working together to perform a certain function
Organ system example 
Digestive system
Organs in the digestive system
Glands (salivary glands and pancreas)
Stomach
Small intestine
Liver
Gall bladder
Large intestine
Rectum
Anus
Enzymes 
Biological catalysts, substances that increase the rate of reaction without being used up
How enzymes work (Lock and Key Hypothesis)
1. Substrate binds to active site of enzyme
2. Reaction takes place
3. Products released
Enzymes 
They can both break up large molecules and join small ones
They are protein molecules and the shape of the enzyme is vital to its function
Optimum pH and temperature for enzymes
Optimum temperature is around 37 degrees celsius (body temperature)
Optimum pH for most enzymes is 7, some have a low optimum pH
As temperature increases 
Rate of reaction increases up to optimum, then rapidly decreases
If pH or temperature is too high or low 
Enzyme is denatured and can no longer work
Types of enzymes 
Carbohydrases
Proteases
Lipases
Examples of carbohydrases, proteases and lipases
Amylase
Pepsin
Enzymes produced in pancreas and small intestine
Bile 
Alkaline to neutralise hydrochloric acid, breaks down large drops of fat into smaller ones (emulsifies)
Investigating effect of pH on enzyme controlled reaction
1. Use iodine to detect presence of starch
2. Warm amylase, starch and buffer solution
3. Take samples at regular intervals and test with iodine
4. Time when starch is completely broken down
5. Calculate rate using 1000/time
Rate of enzymatic reactions 
Rate = change/time
Heart 
An organ in the circulatory system, pumps blood around the body
Structure of the heart
Muscular walls
4 chambers
Valves
Coronary arteries
How the heart pumps blood
1. Blood flows into right atrium and right ventricle, then to lungs
2. Blood flows into left atrium and left ventricle, then around body
3. Valves ensure one-way flow
Natural resting heart rate
Controlled by pacemaker cells in right atrium
Artificial pacemaker 
Electrical device that produces signal to make heart beat at normal speed
Types of blood vessels
Arteries
Veins
Capillaries
Arteries 
Carry blood away from heart, have layers of muscle and elastic fibres
Veins 
Carry blood towards heart, have wide lumen and valves
Capillaries 
Allow blood to flow close to cells, have one cell thick walls
Rate of blood flow 
Volume of blood/number of minutes
Parts of the gas exchange system
Trachea
Intercostal muscles
Bronchi
Bronchioles
Alveoli
Diaphragm
Ventilation 
Ribcage moves up and out, diaphragm moves down, increasing volume and decreasing pressure, drawing in air
Gas exchange 
Oxygen diffuses from alveoli into blood, carbon dioxide diffuses from blood into alveoli
Alveoli 
Small and arranged in clusters, large surface area
Capillaries provide large blood supply
Thin walls for short diffusion pathway
Breathing rate 
Number of breaths/number of minutes
Components of blood 
Plasma
Red blood cells
White blood cells
Platelets
Red blood cells 
Biconcave disc shape, no nucleus, contain haemoglobin
White blood cells 
Part of immune system, have a nucleus, different types including those that produce antibodies
Alveoli 
Very thin, meaning there is a short diffusion pathway
Calculating breathing rate 
Divide the number of breaths by the number of minutes
Components of blood 
Plasma
Red blood cells
White blood cells
Platelets