The Particle Model of Matter All matter is made up of particles but the particles in different substances may be different in size and composition. The particles of matter are constantly moving or vibrating; particles move least in solids and most in gases. Adding or taking away energy will affect the movement of particles. The particles of matter are attracted to one another or are bonded together. Particles have spaces between them that are smallest in solids, except for ice and greatest in gases. The spaces may be occupied by the particles of other substances.
Cycling of Matter in Living Systems 2.2 The Role of Cell
Membrane in Transport The cell membrane is the organelle
responsible for transport of gases, nutrients, and wastes into and
out of the cell. The substances that enter and leave the cell may
be ions or molecules, or in some cases micro-organisms or other
cells. These substances in a physical sense are particles, and
behave according to The Particle Model of Matter. The Particle
Model of Matter All matter is made up of particles but the
particles in different substances may be different in size and
composition. The particles of matter are constantly moving or
vibrating; particles move least in solids and most in gases. Adding
or taking away energy will affect the movement of particles. The
particles of matter are attracted to one another or are bonded
together. Particles have spaces between them that are smallest in
solids, except for ice and greatest in gases. The spaces may be
occupied by the particles of other substances. Diffusion Diffusion
is the natural movement of particles from an area of high
concentration to an area of low concentration. Since the particles
are in constant motion they move until they are equally distributed
throughout the room, resulting in a state of equilibrium. Adding
energy and increasing molecular movement (i.e. heat and stirring)
can increase the rate of diffusion. Diffusion can also occur in
cells.animated.gif The cell membrane is considered to be
selectively permeable because it allows certain particles to pass
through it, but not all particles. This is called a semi- permeable
membrane. Generally the passage of materials through the membrane
is determined by: The size of the molecules The charge of the
molecules The solubility of the molecules in lipids (must be
soluble) Diffusion In general, particles move from areas of high
concentration to areas of low concentration. Therefore Carbon
Dioxide diffuses out of the cell, an area of high concentration to
an area of low concentration. Oxygen diffuses into the cell (low
concentration) from outside of the cell where the concentration of
oxygen is high. Concentration Gradients Concentration Gradient Must
involve different concentrations In cells, different concentrations
are separated by a membrane Involves molecules or ions of a single
type e.g. different concentrations of sodium or potassium salts in
water Different molecules or ions move along their concentration
gradients independently of each other Drives diffusion and
osmosisdiffusion of food coloring artistic Osmosis The cell is an
open system, therefore is always interacting and responding to the
conditions of the environment. If the cell membrane is not
permeable to the solute mixed with water, the water will pass
through the semi-permeable cell membrane, leaving the solute
molecules outside of the cell. This is the process of osmosis.
Osmosis is the movement of water through a membrane in response to
its concentration gradient. The membrane is not permeable to the
solute. This is another form of passive transport. Water moves from
high [ ] to low [ ] Look at which side has higher water [ ], water
will leave this side and move to the other side, until equilibrium
is reached Side ASide B Water will move from side B to side A until
an equilibrium is reached. (High to Low) To predict the direction
in which a net movement of water will occur, the solute
concentration must be compared. Hypertonic ("hyper" means over) -
The concentration of the solutes outside is higher than it is
inside the cell. Therefore if the cell is put into this solution,
water will leave the cell Isotonic ("iso" means equal) - The
concentration of solutes outside the cell is equal to the inside of
the cell. Therefore if the cell is put into this solution, there is
no net movement of water molecules, just odd molecules moving in
and out of the cell. Hypotonic ("hypo" means under) - The
concentration of solutes outside is lower than it is inside the
cell. Therefore if the cell is put into this solution, water will
enter the cell. Hypotonic more water than in the cell Hypertonic
less water than in the cell Isotonic Same amount of water
Facilitated Diffusion There are two forms of protein mediated
transport for those molecules that are soluble in water but not in
lipids, and to cross the cell membrane. Channel proteins create
pores or channels through which small water-soluble particles are
able to move. These molecules move in response to the concentration
gradient. Carrier proteins have the ability to attach to larger
molecules that are not able to diffuse across the membrane. The
carrier protein changes shape and physically moves the molecules
across the membrane and into the cell. Once the molecules have been
transported, the protein returns to its original shape. This
process is a called facilitated diffusion, which is the movement of
substances in response to the concentration gradient but also
requires the presence of the protein facilitator. Both forms of
protein mediated transport are examples of passive transport,
because no added energy needed. Carrier proteins bind to larger
molecules, and change their shape so molecules can diffuse through.
Channel proteins provide water filled pores for charged ions to
pass through Active Transport Active transport requires energy
input to transport molecules. Active transport is necessary when
protein carriers need to carry molecules across the concentration
gradient, from areas of low concentration to areas of high
concentration. The energy required is produced in the mitochondrion
through the process of cellular respiration and comes from the
substances called adenosine triphosphate or ATP. A series of
chemical reactions occurs first in the cytoplasm then in the
mitochondrion, to break down glucose and produce the ATP. Molecules
move against the concentration gradient (low to high) Energy must
be provided (even when we are resting, 40% of our energy is spent
on active transport!) Endocytosis and Exocytosis When a molecule
needs to be taken in by the cell, but are too large to pass across
the cell membrane, even with the help of protein carriers, the
process of Endocytosis occurs. Endocytosis is the process that
occurs when a vesicle (a small temporary sac) forms around the
particle and the cell membrane pinches off around it so that the
vesicle is inside the cell. When a molecule needs to be secreted by
the cell, but are too large to pass across the cell membrane, a
vesicle surrounds the particle, then moves to the plasma membrane
and fuses with it. The vesicle then ruptures, releasing its
contents into the surrounding area of the cell. This process of
secretion is called exocytosis. Both exocytosis and endocytosis
require energy from ATP for the rearrangement of the cell membrane.
For substances the cell needs to take in (endo = in) or expel (exo
= out) that are too large for passive or active transport Homework:
Check and Reflect p. 283 # 1-7
https://www.youtube.com/watch?v=qpw2p1x9Cic
