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Juliette

Cards (69)

Microscopes 
Normal light microscope can see cells and nucleus, electron microscope can see subcellular structures in more detail
Calculating cell size 
1. Measure image size
2. Divide by magnification
Eukaryotic cells 
Have a nucleus containing DNA
Prokaryotic cells 
Do not have a nucleus, DNA is in a ring called a plasmid
Cell structures 
Cell membrane
Cell wall (plant cells and bacteria)
Cytoplasm
Mitochondria
Ribosomes
Chloroplasts (plant cells)
Bacterial binary fission 
1. Number doubles every 10 minutes
2. Practical: Grow culture on agar plate, use aseptic technique, calculate growth rate
Diploid cells 
Have 23 pairs of chromosomes
Haploid cells 
Have 23 unpaired chromosomes
Mitosis 
1. Genetic material duplicated
2. Nucleus breaks down
3. Chromosomes pulled to opposite sides
4. New nuclei form
Specialised cell types 
Nerve
Muscle
Root hair
Xylem
Phloem
Stem cells 
Unspecialised cells that can differentiate into different cell types
Diffusion 
Movement of molecules/particles from high to low concentration, passive process
Osmosis 
Diffusion of water across a partially permeable membrane
Practical: Osmosis 
1. Cut potato cylinders
2. Weigh
3. Place in sugar solutions
4. Reweigh
5. Calculate % change in mass
6. Plot graph to find no change concentration
Active transport 
Using energy to move substances against a concentration gradient
Tissues 
Heart
Digestive
Digestive system processes
Acid in stomach
Bile and enzymes in small intestine
Emulsification of fats
Enzymes 
Biological catalysts, specific to certain substrates, work on a lock and key principle
Practical: Enzyme activity 
1. Mix amylase and starch
2. Test for starch every 10 seconds with iodine
3. Plot time to complete reaction against temperature or pH
4. Find optimum conditions
Food tests 
Iodine for starch
Benedict's solution for sugars
Biuret's reagent for proteins
Ethanol for lipids
Respiration 
Provides energy for cells, different to breathing
Gas exchange 
1. Air enters trachea
2. Diffuses into blood in alveoli
3. Oxygen binds to haemoglobin
4. Carbon dioxide diffuses into lungs and is exhaled
Circulatory system components 
Heart
Blood vessels (arteries, veins, capillaries)
Blood (red blood cells, white blood cells, platelets)
Blood flow through heart 
1. Deoxygenated blood enters right atrium
2. Passes through right ventricle to lungs
3. Oxygenated blood enters left atrium
4. Passes through left ventricle to body
Coronary arteries 
Supply blood to heart muscle
Non-communicable diseases 
Caused by factors within the body, e.g. cardiovascular disease, cancer, autoimmune conditions
Communicable diseases 
Caused by pathogens that can be transmitted, e.g. infectious diseases
Coronary artery 
Delivers blood to the heart muscle to supply oxygen
Coronary heart disease (CHD) 
Occurs when coronary arteries are blocked by fatty deposits, causing a heart attack
Stents 
Little tubes inserted into blood vessels to keep them open and allow blood flow
Statins 
Drugs that reduce cholesterol and fatty deposits
Heart valve replacement 
Artificial valves can replace faulty ones to prevent backflow
Blood components 
Plasma
Red blood cells
White blood cells (combat infections)
Platelets (clot wounds)
Cardiovascular disease (CVD) 
Non-communicable disease caused by factors within the body, e.g. obesity, diabetes, smoking
Communicable disease 
Caused by a pathogen (virus, bacteria, fungus, or parasite) that enters the body
Carcinogen 
Anything that increases the risk of cancer, e.g. ionizing radiation
Benign cancer 
Doesn't spread through the body and is relatively easy to treat
Malignant cancer 
Cancerous cells spread through the body, much worse
Plant organs 
Leaves (photosynthesis)
Roots (water and mineral absorption)
Meristem (new cell production)
Xylem 
Long continuous tubes that transport water upwards in plants