Lecture 1, Introduction to Energy Transfer

Question 1

Energy - The Capacity for Work

Answer 1

• as biologic work increases, energy transfer increases (energy can be hard to measure unless it is is transferred)
  
  • biologic work is expressed in mechanical units
  • emerges only when a change takes place
• energy can be thought of as stored work

Question 2

Bioenergetics

Answer 2

transfer of energy in biological systems that can be people (how we transfer energy from our environment through our bodies to do useful work like running up a hill, lifting a weight)
- flow and energy exchange within a living system

Question 3

Work

Answer 3

work = force x distance
- can calculate work with our bodies - easy to calculate work if we are going up a stair or a steep hill (body mass x height increase)
- cycle = distance wheel has travelled x amount of weight on wheel
- work is independent of time (as you are doing the exact amount of work but what changes is the power)

Question 4

Power

Answer 4

power = work / time (or work rate
- power is affected by time (determines who is better)
- if we do the amount of work in less time we have more power output (work rate)
- work is proportional to energy transfer (if we do work at a higher rate with higher power output, we have a higher rate of energy transfer)
- energy = the ability to do work (stored work)

Question 5

First Law of Thermodynamics

Answer 5

• energy cannot be created or destroyed, but only transforms from one form to another without being depleted (an expression of the conversion of energy principle)
• the body does not produce, consume or use up energy; instead it, transforms energy from one state into another as physiologic systems undergo continual change

Question 6

What are the 3 Forms of Biological Work in Humans?

Answer 6

chemical, mechanical and transport

Question 7

Chemical

Answer 7

biosynthesis of cellular molecules (go from one molecular form to another some work has to be done)
- when you from simple to complex molecule it requires a transfer of energy
- glycogen (a chain of glucose molecules put together) - every time we add glucose molecule to the chain we are doing chemical work and transferring energy

Question 8

Mechanical

Answer 8

muscle contraction (creating force to contract our muscles - shortening our muscle against the weight, running, jumping etc.)
- generate ATP causing muscle to contract and those muscles pull on the bone which allow us to measure force and displacement and then calculate work

Question 9

Transport

Answer 9

transfer of substances among cells (from one place to another)
- if something is moving down a concentration gradient we say nothing is happening or work is not being done but if it moving against its pressure gradient work is being done (requires ATP)
- for example pumping sodium and potassium against their concentration gradient that requires ATP is a type of work

Question 10

Biosynthesis (Chemical Work)

Answer 10

bound energy in one substance that directly transfers to other substances to increase their potential energy
- protein synthesis (taking amino acids we eat and combining them together to make proteins that is going to require a transfer of energy and work)
- glycogen synthesis (if we take glucose that we broken down from our food and combine it to make glycogen that requires chemical work)
- ATP synthesis (energy currency in our body - how we can be do work by breaking down ATP - how do we take energy stored in food and then put them in energy which is ATP

Question 11

What are the 2 Energy-Releasing and Energy-Conserving Processes?

Answer 11

exergonic (catabolic) and endergonic (anabolic)

Question 12

Exergonic (Catabolic)

Answer 12

reactions that release energy
- any physical or chemical process that releases energy to surrounding (“downhill” processes) with free energy decline
- catabolic are things that breakdown more complex molecules in simple molecules and going to release energy that can do work

Question 13

Endergonic (Anabolic)

Answer 13

reactions that require an input of energy (ATP)
- chemical reactions that store or absorb energy (“uphill processes) with free energy increase for biologic work
- taking simple molecule and putting them together to make complex molecule (protein) is going to be endergonic

Question 14

Interconversions of Energy

Answer 14

transfer of potential energy always proceeds in a direction that decreases capacity to perform work
second law of thermodynamics
- tendency of potential energy to degrade to kinetic energy of motion with a lower capacity for work
- energy transfer is always inefficient (cannot take given amount of energy and put that exact same energy somewhere else) - anytime there is a chemical reaction energy in lost to heat, sound etc.
- anytime there is mechanical work not all the energy will go where we want to go (have transferred energy from muscle to ground but lost some due to heat (big one for energy transfer in people), sound)
- the biggest source of energy loss is heat
- net increase in randomness and disorder with every reaction which means we are not 100% efficient
- all potential energy in a system degrades to the unusable form of kinetic or heat energy
- total energy in a system remains constant; a decrease in one energy form matches the equivalent energy increase in another form

Question 15

Inefficient Energy Transfer

Answer 15

chemical → mechanical
- heat is the biggest lose of energy (using ATP and we are inefficient at transferring energy so we create some heat)
- higher work rate (or power output) and higher rate that energy is being transferred leads us to be more inefficient and create more heat (as work rate increases we are going to have energy leak to places we do not want it to go and one of those is heat so we get hotter)

chemical → chemical
- take one molecule and changing it to another molecule will be inefficient
- increase in energy transfer associated with eating food (take complex molecules (proteins, fats, complex carbohydrates) and break them down into simple acid (fatty, amino) and sugars and bind them again in molecules that we can store (transfer of energy through these processes and every time it is inefficient there is a increase in heat production when there are chemical reactions in eating food)

Question 16

Enzymes

Answer 16

enzyme is always a protein that catalyses a reaction or changes the rate of chemical reaction, generally accelerating them without being used)
- protein catalysts: accelerate chemical reactions without being consumed or changed in the reaction
- substrate to product is done quicker (enzyme does not get used up, it stays there)
- rate of energy must increase so we can do more work

Question 17

Coenzymes

Answer 17

organic that are not proteins which can act to make enzymes work better or facilitate binding
- nonprotein organic substances: facilitate enzyme action by binding a substrate to its specific enzyme
- there are also not consumed just like enzymes - they can help transfer things around the cell or just bind to an enzyme allowing it to work better (ex. NAD+ ~ transfer hydrogens around the cell)
- if you do not have enough vitamin c (coenzyme) you cannot build properly structured collagen
- help to make enzymes work better by finding substrate to enzyme

Question 18

Lock and Key Mechanism

Answer 18

enzyme-substrate interaction
- enzyme turns on when its active site joins in a “perfect fit” with a substrate’s active site (which can speed up rate of reactions)
- ensures that the correct enzyme matches with its specific substrate to perform a particular function
- enzymes do not just fit one thing as they are more complex (work at different levels based on different regulators)

Question 19

Enzyme Regulation

Answer 19

• equilibrium (if you have more of one side of an equation (more substrate less products) we will have faster progression of an reaction whereas it will move slowly or opposite direction if it was more products less substrate) - the ratio between substrate and product will affect the rate at which the enzyme will work
• competitive binding - (cyanide - binds too tightly that we cannot transfer electrons across the chain) - violation of lock and key model (two things can bound to one enzyme and there is competition as some bind better than others)
• allosteric (something binds to an enzyme and makes it work better or worse) - calcium is a common allosteric regulator of lots of enzymes (bind to certain enzymes and make it work faster)
• covalent (some enzymes have an one and off form - can turn it on or off but adding a phosphate group for example) - active and inactive form

Question 20

Oxidation

Answer 20

oxidation (always involves electron loss) - involve transfer of hydrogen electrons or atoms (lost from one thing and transferred to another)
- reactions that transfer oxygen, hydrogen atoms, or electrons
- a loss of electrons always occurs with a net gain in valence
- cannot have oxidation without reduction and vice versa (redox reactions - work hand in hand)

Question 21

Reduction

Answer 21

always involves electron gain
- any process in which atoms in an element gain electrons, with a corresponding net decrease in valence
◦ LEO GER!
- oxidized when electrons are lost and when electrons are gained that it is called a reduction

Question 22

Reducing Agent and Oxidizing Agent

Answer 22

R = substance that donates or loses electrons as it oxidizes
O = substance being reduced or gaining electrons

• the reducing agent is the thing that is oxidized which causes the reduction
• the oxidizing agent is the thing that is reduced