2.  Homeostasis – Process by which organisms maintain a relatively stable internal environment; All organisms have ranges that are tolerated (i.e. pH and temperature)  Example - Paramecium contain contractile vacuoles that collect and remove excess water, thereby helping to achieve homeostasis

3.  Composed of a double-layered sheet called the lipid bilayer which includes: 1. Two layers of lipids (phosphate group + two fatty acids)  Creates a strong barrier that is flexible 2. Proteins that are embedded in the bilayer  Some form channels and pumps that help to move material across the cell membrane 3. Carbohydrate molecules that are attached to the proteins  Allows individual cells to identify one another

5.  Many substances can diffuse across biological membranes, but some are too large or too strongly charged to cross the lipid bilayer.  If a substance is able to diffuse across a membrane, the membrane is said to be permeable to it.  A membrane is impermeable to substances that cannot pass across it.  Most biological membranes are selectively permeable, meaning that some substances can pass across them and others cannot.

6.  Concentration - the mass of solute in a given volume of solution, or mass/volume  Example:  12 grams of salt in 3 liters of water  Concentration = 12 g/3 L (4 g/L)  If you had 12 grams of salt in 6 liters of water  concentration = 12 g/6 L (2 g/L) ***The 1st solution is 2X as concentrated as the 2 nd.

8.  Passive transport – Transport of materials from a higher to lower concentration. Energy is not required for this to occur.  Active transport – Transport of materials from a lower to higher concentration. Energy is needed for this to occur. high low Weeee!!! high low This is gonna be hard work!!

9. Three Types of Passive Transport: 1. Diffusion - Transport of substances 2. Osmosis – Transport of water 3. Facilitative Diffusion – Transport with the help of carrier proteins (for molecules too large to pass through the membrane without help)

10. Diffusion Diffusion - Movement of molecules from an area of HIGH concentration to an area of LOW concentration when the concentration of a solute is the same throughout a solution it has reached equilibrium (particles never stop once this is reached – ALWAYS in MOTION!)

11. Diffusion (Continued) DOES NOT require the cell to use energy. Examples…..

12. View Diffusion http://www.indiana.edu/~phys215/lecture/le cnotes/diff.html http://www.indiana.edu/~phys215/lecture/le cnotes/diff.html

14. OSMOSIS  Water passes easily across most membranes, but most solute does not.  Osmosis - Diffusion of water through a selectively permeable membrane  High to low concentration  NO ENERGY required by the cell

16.  There are more sugar molecules on the right. That means that the concentration of water is lower on the right than the left.  The membrane is permeable to water but not to sugar. As a result, there is a net movement of water from the area of high concentration to the area of low concentration.

17. OSMOSIS TERMS  Water will tend to move across the membrane to the left until equilibrium is reached.  Iso=tonic - when the concentration of two solutions is the same  Hyp o tonic - when comparing two solutions, the solution with higher concentration of water  Hyp e rtonic - when comparing two solutions, the solution with the lesser concentration of water

18. Facilitated Diffusion Facilitated Diffusion - Movement of specific molecules across cell membranes through protein channels Each protein channel only allows a particular substances to cross. The protein facilitates (helps) the diffusion across the membrane

20. Facilitated Diffusion and Energy Occurs with the following: 1. Charged molecules (ions) 2. When molecules are too large HIGH concentration → LOW concentration. DOES NOT require energy.

21.  Passive transport – Transport of materials from a higher to lower concentration. Energy is not required for this to occur.  Active transport – Transport of materials from a lower to higher concentration. Energy is needed for this to occur. high low Weeee!!! high low This is gonna be hard work!!

22.  Active Transport - Energy-requiring process that moves material across a cell membrane against a concentration difference.

23.  Move materials in the opposite direction— against a concentration difference.  Requires: 1. Energy 2. Transport proteins

24. 1. Endocytosis 2. Exocytosis

25.  Endocytosis - Process by which a cell takes material into the cell by infoldings or pockets of the cell membrane; Low → high concentration  Transports: 1. Larger molecules 2. Solid clumps of material

26. 1.Pinocytosis – For fluids, cell “drinking” 2.Phagocytosis – For solids, cell “eating” 3.Using vesicles

27. Macrophage (white blood cell) engulfing bacteria Amoeba engulfing food.

28.  Exocytosis - Process by which a cell releases large amounts of material; Low → high concentration  Vacuole fuses with cell membrane  Transports: 1. Larger molecules 2. Solid clumps of material

30.  For organisms to survive, they must have a way to balance the intake and loss of water.  Osmosis exerts a pressure known as osmotic pressure on the hypertonic side of a selectively permeable membrane.  Osmotic Pressure - The force exerted by osmosis that “pushes” water through a selectively permeable membrane to make the concentration of solutes the same on both sides.

31.  Turgor Pressure - The force behind the cell walls of plants, which allows them to keep their shape.  Very similar to osmotic pressure, but occurs in plants.  When the cells contents press the plasma membrane against the cell wall and the cell wall in turn presses against the membrane

33.  The cell is filled with salts, sugars, proteins, and other molecules.  If placed in a hypertonic solution.  Cell will shrink or become shriveled ( plasmolysis )  Water moves out of cell.  If placed in a hypotonic solution  Cell will be swell or become enlarged.  Cytolysis occurs when a cell ruptures or lyses.  Water moves into the cell.

34. Plasmolysis occurs as the cell shrinks. Cytolysis occurs when the cell bursts

35. ISOTONIC ENVIRONMENT

36. HYPOTONIC ENVIRONMENT HYPERTONIC ENVIRONMENT