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Flashcards in Exam Revision Sem 1 Deck (101)
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1
Q

Function of mitochondria

A

Double membrane
Cellular respiration
Makes energy available for the cells activities

2
Q

Function of Golgi apparatus?

A

Modifies proteins and packages them for secretion from the cell

3
Q

Centrioles:

A

Involved in the reproduction of the cell

4
Q

Endoplasmic reticulum:

A

Provides a surface for chemical reactions

5
Q

Lysosomes:

A

Contain digestive enzymes
When particles/liquids enter the cell they form vesicles in cytoplasm, lysosomes join these vesicles and break down material

6
Q

Nucleus:

A

Membrane separates from cytoplasm, stores energy and genetic information (DNA)

7
Q

Why are cells so small?

A

All the requirements of a cell and the organelles must pass across the membrane

8
Q

Inclusions?

A

Chemical substances occurring as granules or liquid droplets in the cytoplasm

9
Q

Structure of the cell membrane?

A

Semipermeable
Separates cell from neighbouring cell
Separates intercellular fluid and extracellular fluid
Gives the cell structure

10
Q

Passive process?

A

Requires no energy, moves with the concentration gradient examples include diffusion, osmosis

11
Q

Active processes?

A

Require energy, move against the concentration gradient

Examples are active transport, vesicular transport

12
Q

What is osmosis?

A

Diffusion of water, requires channel proteins

Movement of water from a region of high water concentration to a region of low water concentration

13
Q

What is carrier-mediated transport?

A

When large molecules are too big to pass through channels, they attach to a binding site on the carrier (proteins are specific)

14
Q

What is vesicular transport?

A

Movement of substances in vesicles across the membrane.

15
Q

What is exocytosis?

A

Removing a liquid/solid out of the cell
Vesicle formed inside the cell via the Golgi apparatus
Vesicle then fuses with cell membrane and contents are pushed outside into extracellular fluid.

16
Q

What is endocytosis?

A

Taking liquids/solids into a cell
Cell membrane folds around the particle and encloses, forming a vesicle
Vesicle then suspended in the cytoplasm

17
Q

Pinnocytosis?

A

Movement of liquid into cell

18
Q

Phagocytosis?

A

Movement of solids into a cell

19
Q

What is homeostasis?

A

Where the body systems work together to make sure the cellular environment stays constant. (Temperature and fluid concentration)

20
Q

What is facilitated diffusion?

A

A passive process where particles move from an area of high concentration to low concentration, require no energy and move against the concentration gradient

21
Q

Three types of osmotic solutions?

A

Isotonic
Hypotonic
Hypertonic

22
Q

Isotonic:

A

There is the same concentration of solute molecules inside and outside the cell

23
Q

Hypotonic:

A

Solute outside the cell is low concentration (10%) inside the cell higher solute conc (90%)
When water moves into the cell osmotic pressure increases

24
Q

Hypertonic:

A

Greater concentration of solute molecules outside the cell rather than inside
Water moves outside the cell causing it to shrink.

25
Q

Epithelial tissue:

A

Covering or lining tissue, found in the heart, kidneys, intestines, liver (outside lining) as well as lining the inner layer of the heart, stomach and other hollow organs.

26
Q

Connective tissue:

A

Provides support for the body, cells are not close together like they are in epithelial tissue> separated by non-cellular material called the matrix eg cartilage, ligaments, tendons and bone

27
Q

Muscular tissues:

A

Skeletal muscle: muscles attached to the bones (voluntary movements)

Involuntary muscle: cells we cannot voluntarily contract > in the stomach walls, intestines, iris ams uterus

Cardiac muscle: heart muscle , makes up most of the heart , not voluntary

28
Q

Nervous tissue:

A

Made up of specialised nerve cells (neurons) found in the brain, spinal cord and nerves.

29
Q

Catabolism:

A

When large cell molecules are broken down into smaller molecules and release energy.

30
Q

Anabolism:

A

When small molecules are built up into larger molecules, require energy.

31
Q

Organic compounds:

A

Large molecules that contain carbon ie, carbohydrates, amino acids, proteins, lipids and nuclei acids

32
Q

Enzymes:

A

Proteins that allow for chemical reactions (breaking down and building up of substances) to take place at body temperature.
Are biological catalysts

33
Q

Five factors affecting enzyme activity:

A
  • Concentration of enzyme
  • Concentration of substrate
  • temperature (optimum temp is 37°)
  • PH level
  • co-factors (can denature activation site shape so the enzyme can bind with the substrate)
34
Q

Cellular respiration:

A

When organic molecules (food) is broken down to release energy.

  • carbs > glucose
  • proteins > amino acids
  • lipids > fatty acids and glycerol
35
Q

Cellular respiration formula:

A

Glucose + oxygen –> carbon dioxide + water + ATP

36
Q

What occurs in cellular resp?

A

60% of available energy is released as heat
40% used to from adenosine triphosphate (ATP)
Inorganic phosphate group joins in to from adenosine diphosphate (ADP)
The bond between ADP and the 3rd phosphate is easily broke

37
Q

Anaerobic respiration:

A
Occurs without oxygen
Allows cells to reproduce energy
Glycolysis --> 2 molecule sof pyurvic acid
Occurs in cytoplasm 
Incomplete glucose break down
Forms 2 ATP
38
Q

Aerobic respiration:

A
Require oxygen
Complete breakdown of glucose
Occur sin mitochondria 
Products are water + CO2 
Produces 34 ATP form electron transport, 2 ATP from krebbs cycle
39
Q

What do cells use energy for? (7)

A
  • building complex molecules
  • cell division and growth
  • movement of cell organelles
  • movement of whole cell
  • maintaining cell organisation
  • active transport
  • transmission of nerve impulses
40
Q

What is synthesis?

A

Combining of small molecules to make larger molecules

41
Q

Circulatory system functions: (5)

A
Transports oxygen 
Removal of carbon dioxide
Transport of nutrients 
Maintains body temperature 
Regulates PH levels in the blood
42
Q

What are the 4 components of blood?

A

Erythrocytes- RBC
Leucocytes- WBC
Thrombocytes- platelets
Plasma

43
Q

Function of erythrocytes?

A

Combine w oxygen and form oxyhemoglobin, produced in bone marrow, destroyed in spleen + liver

44
Q

Function of leucocytes?

A

Remove dead cells and invading microorganisms, live from minutes to years

45
Q

Function of Thrombocytes

A

Formed in red bone marrow, sticky, necessary for blood clotting (last 7 days).

46
Q

The Heart:

A

Double pump

  • As blood is pumped through the capillaries it loses most of its pressure
  • after going through lungs, blood pressure is so low it needs to be pumped through the heart before travelling to the body
  • the right side pumps blood to the lungs
  • the left side pumps blood to the rest of the body
47
Q

Blood vessels:

A

Arteries (away from heart)
Capillaries (between cells)
Veins (towards the heart)

48
Q

4 stages of blood clotting:

A
  1. Arteries construct to reduce blood flow
  2. Platelets stick to rough surfaces and attract more platelets, acting as a plug
  3. Platelets release vasoconstrictors
  4. Plug and constriction is enough to stop bleeding.
49
Q

Coagulation :

A

(Major damage)

  • clotting factors present in plasma form protein threads called fibrin
  • fibrin forms a mesh to trap blood cells, platelets and plasma
  • mesh threads contract and become denser and stronger, pulling blood vessel edges together (clot retraction)
  • serum is squeezed out and the clot dries forming a scab.
50
Q

What is the lymphatic system?

A
  • As blood enters the capillaries, the high pressure forces some of the fluid in the blood through the capillary walls into the tissues
  • main function is to collect the escaping fluid and return it to the circulatory system
51
Q

Lymph vessel:

A

Originate as blind-ended tubes in the spaces between the cells of most tissues

  • more permeable
  • network of lymph vessels join up to form 2 lymphatic ducts that empty lymph into large veins in the upper chest
52
Q

Lymph nodes:

A

Occur at intervals along the lymphatic vessels
Each surrounded by a capsule of connective tissue that extends into the node forming framework
The lymph passes through several nodes before entering the circulatory system.

53
Q

Outside the lungs:

A
  • membrane called the pleura covers the surface of the lungs
  • between 2 layers of membrane is the pleural fluid (holds the lungs against the inside of the chest wall and allows the lungs to slide when breathing.
54
Q

Inside the lungs:

A

Bronchi branch ends in bronchioles
The smallest bronchioles open into clusters of tiny air sacs called alveoli
Alveoli are the exchange surface for respiratory gases
Each alveolus is surrounded by a network of blood capillaries.

55
Q

The mechanics of breathing- inhaling (3 steps)

A
  1. Intercostal muscles contract to move ribcage up and outwards
  2. Lung volume increases, diaphragm contracts and moves down
  3. Air flows from high pressure external environment to area of low pressure into lungs
56
Q

The mechanics of breathing- exhaling (3 steps)

A
  1. intercostal muscles relax to move the ribcage down and inwards
  2. lung volume decreases, diaphragm relaxes and moves upwards
  3. Air flows from high pressure in lungs to low pressure external environment.
57
Q

Systole:

A

Pumping phase where the heart contracts

58
Q

Diastole:

A

The filling phase of the heart

59
Q

How are lungs well suited to gas exchange?

A

Large surface area
Rich supply of blood vessels
Thin membrane
Lungs positioned deep inside the body (to prevent excess fluid evaporation)
Lung volume can change by movement of respiratory muscles so that air can flow in n out of lungs

60
Q

Processes in gas exchange?

A
  • arteries bring deoxygenated blood, high in CO2 to the lungs
  • CO2 moves from high to low concentration and diffuses across membrane into alveolus
  • oxygen moves from high to low concentration and diffuses across membrane into blood
  • veins carry oxygenated blood, low in CO2 form the lungs
61
Q

How is the concentration gradient maintained?

A

Constant flow of blood

Movement of air in n out of lungs

62
Q

What are the 7 nutrient groups?

A
Carbohydrates
Proteins
Lipids
Water
Minerals
Vitamins
Fibre
63
Q

Digestion in the mouth:

A
Mastication occurs (chewing of the food)
Salivary glands secrete salivary amylase
64
Q

4 types of teeth:

A

Incisors- biting and cutting food
Canine- tearing
Premolars and molars- crushing and grinding food

65
Q

Digestion in the Oesophagus:

A

Movement of food down the tube (peristalsis)

Oesophagus secretes mucus to lubricate the bolus

66
Q

Digestion in the stomach

A

3 types of muscle- longitudinal, oblique and circular, contract, churn and mix the food with the gastric juices
Enzyme : pepsin
Substrate: protein
Product: polypeptide

67
Q

Digestion in the small intestine/ ileum:

A

Wave-like muscle contractions move the chyme along the tubing (segmentation) pancreatic and intestinal juices with enzymes are secreted

68
Q

Liver:

A

Produces bile, duodenum breaks down bile in a process called emulsification.

69
Q

Gall bladder:

A

Stores bile–> releases to small intestine, bile emulsifies liquids

70
Q

Pyloric sphincter:

A

Band of circular muscle that regulates material flow from stomach to duodenum.

71
Q

Pancreatic lipase:

A

Substrate: lipids, tri-glyceride
Products: fatty acid + glycerol

72
Q

Pancreatic protease:

A

Substrate: protein and polypeptides
Products: peptides

73
Q

Pancreatic amylase:

A

Substrate: starch
Product: dissachoride

74
Q

Intestinal lipase:

A

Substrate: lipids, triglyceride
Product: fatty acid and glycerol

75
Q

Intestinal amylase:

A

Substrate: disaccharide
Enzyme: monsaccharide (glucose)

76
Q

Pancreatic protease:

A

Substrate: peptide
Product: amino acid

77
Q

The 5 functions of the skeletal system:

A
Framework
Movement
Production
Storage
Protection
78
Q

Yellow bone marrow:

A

Storage of fat

79
Q

Compact bone:

A

Non porous, stores salts, strong, give support

80
Q

Periosteum:

A

Fibrous connective, covers the whole bone

81
Q

Red bone marrow sponge:

A

Cancellous bone, porous, production of RBC and WBC and platelets

82
Q

Articulate cartilage:

A

Smooth movement, made of collagen

83
Q

Absorption in the small intestine:

A

90% occurs in the small intestine
Absorbed by circular folds covered in tiny hair like features called villi, covered in microvilli. Connected to a network of blood capillaries allowing for a large surface area.

84
Q

Formula for cardiac output (ml/minute):

A

Stroke volume (mL) x heart rate (bpm)

85
Q

What is cardiac output?

A

The amount of blood leaving one of the ventricles every minute

86
Q

How to test for macro nutrients in different foods using chemicals ?

A

Iodine tests for starch
Benedict tests for glucose
Biuret tests for protein
Grease spot tests for fat

87
Q

Characteristics Fibrous joints:

A

No movement between the bones
Bones held in place by fibrous connective tissue
Very difficult to damage
Eg sultures of the skull

88
Q

Cartilaginous /slightly moveable joints characteristics:

A

Held in place by cartilage
Eg the junction of the two pelvic homes (the public symphysis), joints between adjacent vertebrae, joints between ribs + sternum

89
Q

Synovial/freely moveable joints:

A

Movement is limited by ligaments, muscles, tendons and adjoining bones
Eg shoulder, elbow,wrist,fingers,knee, hip

90
Q

Ball and socket joints:

A

Spherical head fits into a cup-like cavity

Eg scapula + humerus, femur + pelvis

91
Q

Hinge joints:

A

Allow movement in one plane only, form when the convex surface fits with concave surface
Eg elbow, knee

92
Q

Pivot joints

A

Rounded, pointed end of bone articulates with a ring (formed of bone +ligament)
Eg first vertebrae (atlas) and the second vertebrae (axis)

93
Q

Gliding joints

A

Movement in any direction (side to side, back and forth)

Eg carpal and tarsal bones, the sternum and clavicle

94
Q

Saddle joints

A

Only occurs where the thumb connects to the palm and convex in the other

95
Q

Condyloid joints:

A

Slightly convex surface into slightly concave depression

Eg the radius + carpal bones, metacarpal + phalanges

96
Q

3 muscle properties:

A

Contract
Extensibility
Elasticity

97
Q

3 types of muscle :

A

Smooth (involuntary)
Cardiac
Skeletal

98
Q

Skeletal muscle properties:

A
Elongated,
Mostly attached to bones
Allow movement at the joints
Mostly voluntary
Gove body shape
99
Q

Smooth muscle properties:

A

Spindle shaped with single nucleus
Occur in the muscles of internal organs
Involuntary

100
Q

Functions of the muscle:

A
Move bones by contracting
Stabilise body positions
Regulate organ volumes
Movement of substances within the body 
Create heat
101
Q

Actin and myosin:

A

Proteins that enable cells to shorten

Because the muscles are anchored