B2

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Grace

Cards (107)

Cell 
The basic building block of a living organism
Tissue 
A group of cells with a similar structure and function working together. For example, muscular tissue contracts to bring about movement.
Organ 
A collection of tissues working together to perform a specific function. For example, the stomach contains glandular, muscular and epithelial tissues.
Organ system 
A group of organs working together to perform specific functions. For example, the digestive system contains organs such as the stomach, the small intestine and the large intestine.
Digestive system 
To digest food and absorb the nutrients obtained from digestion
Pancreas and salivary gland 
Glands which produce digestive juices containing enzymes
Stomach 
Produces hydrochloric acid - which kills any bacteria present and provides the optimum acidic pH for the protease enzyme to function
Small intestine 
The site where soluble food molecules are absorbed into the bloodstream
Liver 
Produces bile (stored in the gallbladder) which emulsifies lipids and allows the lipase enzyme to work more efficiently
Large intestine 
Absorbs water from undigested food, producing faeces
Enzymes 
Act as biological catalysts which speed up the rate of biological reactions (the breakdown of food) without being used up
Enzyme shape 
Enzymes have a specific active site which is complementary to their substrate
Metabolism 
The sum of all the reactions in a cell or an organism
Types of metabolic reactions catalysed by enzymes
Building larger molecules from smaller molecules
Changing one molecule to another
Breaking down larger molecules into smaller molecules
Lock and key hypothesis
The shape of the enzyme active site and the substrate are complementary, so can bind together to form an enzyme-substrate complex
Temperature effect on enzymes
Up to a certain point, increasing temperature increases enzyme action, as molecules have a higher kinetic energy. Above a certain temperature, the shape of the active site is altered and the enzyme becomes denatured, so it can no longer catalyse the reaction. The optimum temperature is around 37°
pH effect on enzymes
The optimum pH for most enzymes is 7 (apart from proteases in the stomach). If the pH is too extreme, the shape of the active site may be altered and the enzyme may no longer work
Locations of enzyme production
Carbohydrases: amylase - salivary gland and pancreas; maltase - small intestine
Proteases: pepsin - stomach; others - pancreas and small intestine
Lipases: pancreas and small intestine
Role of carbohydrases 
Break down carbohydrates into monosaccharides and disaccharides. Amylase breaks down starch into maltose, and maltase breaks down maltose into glucose
Role of proteases 
Break down proteins into amino acids
Role of lipases 
Break down lipids into fatty acids and glycerol
Use of digestion products 
They are used to build bigger molecules such as carbohydrates and proteins. Glucose is used as a substrate in respiration
Bile production and storage
Bile is made by the liver and stored in the gallbladder
Role of bile 
Neutralises the hydrochloric acid secreted by the stomach, and emulsifies lipids to form droplets - this increases the surface area for the lipase enzyme to work on
Heart 
An organ that pumps blood around the body
Circulatory system 
Carries oxygen and other useful substances to bodily tissues, and removes waste substances
Double circulatory system 
1. One pathway carries blood from the heart to the lungs - where the gaseous exchange of oxygen and carbon dioxide takes place
2. One pathway carries blood from the heart to the tissues
Blood flow from right ventricle 
The lungs
Blood flow from left ventricle
Body tissues
Importance of double circulatory system 
It makes the circulatory system more efficient - for example, oxygenated blood can be pumped around the body at a higher pressure by the left ventricle
Heart chambers
4 - right atrium, right ventricle, left atrium, left ventricle
Thicker left ventricle wall
The left ventricle has to pump blood at a higher pressure around the whole body
Main blood vessels associated with the heart
Aorta (left) - carries oxygenated blood from the heart to the body
Pulmonary vein (left) - carries oxygenated blood from the lungs to the heart
Vena cava (right) - carries deoxygenated blood from the body to the heart
Pulmonary artery (right) - carries deoxygenated blood from the heart to the lungs
Purpose of heart valves 
Prevent the backflow of blood
Purpose of coronary arteries 
Supply the heart muscle with oxygenated blood
Blood flow through the heart
1. Blood enters the right atrium via the vena cava, and the left atrium via the pulmonary vein
2. The atria contract, forcing blood into the ventricles and causing valves to shut
3. After the ventricles contract, blood in the right ventricle is pumped to the lungs, and blood in the left ventricle is pumped to the body
Purpose of valves in the heart
Prevent the backflow of blood
Blood flow through the heart
1. Blood enters the right atrium via the vena cava, and the left atrium via the pulmonary vein
2. The atria contract, forcing blood into the ventricles and causing valves to shut
3. After the ventricles contract, blood in the right ventricle enters the pulmonary artery (to the lungs) and blood in the left ventricle enters the aorta (to the body)
Epidermal tissue
Covers the entire plant
Has a waxy cuticle which helps reduce water loss from the leaf surface
The approximate value of the natural resting heart rate is 70 beats per minute