NATS1560 Lecture 4.1 - Energy PDF

Summary

This document is a lecture on energy and food, focusing on the primary function of food as fuel for the body and measuring energy in foods. It explains the equivalence of energy and heat, measurement units, gross and metabolizable energy, Atwater Values and how to estimate the energy content of food. It also critically assesses the accuracy of the Atwater values and introduces the USDA Modified Atwater Values. Finally, it discusses the relationship between food intake and body weight.

Full Transcript

NATS1560:
Understanding
Food
Angela Cope
[email protected]

Week 2:
Energy Part 1
 LEARNING OBJECTIVES
To explain the equivalence between energy and
heat, and the primary function of food as “fuel”
for the body
To define the measurement units of food energy,
the kilocalories, and their moniker, “calories”
To explain the difference between the gross
energy and the metabolizable energy of food
To define the standard metabolizable energy
values of the macronutrients, also know as the
Atwater Values, and to apply the “4-9-4” rule to
estimate the metabolizable energy of a food
To assess critically the accuracy of the Atwater
Values, and to define and apply the USDA
Modified Atwater Values
To define and use the Acceptable Distribution
Ranges, or Dietary Reference Intakes for
macronutrients 2
 Human Nutritional Needs (Review):
Humans are omnivores and need a variety of
different foods to survive.
Nutrients: pure substances that scientists
have identified as capable of providing
nourishment to our organisms.
Nutrition science currently recognizes six
categories of nutrients needed for human
nutrition:
1. Proteins
2. Carbohydrates
3. Fats
Together, these are the Macronutrients.
These are the nutrients needed in the largest
quantities.

3
 Human Nutritional Needs
(Review):
Water
Minerals
Vitamins
(A seventh category, phytochemicals, is currently under
study.)

These are the micronutrients. Minerals and Vitamins. These
are needed in far smaller amounts than macronutrients.
Water is something we need in macro-quantities but provides
neither macro nor micronutrients (for the most part).

4
 WHY DO WE NEED FOOD?
Our body needs food for
 matter (atoms), needed for
the growth, repair, and
functioning of organs and
tissues
 energy (capacity to do work),
needed for all physiological
From the NBC show, Parks and Recreation
processes
Food does not “become”
Food is the source of matter and energy for the organism
energy
In all physiological processes, matter and energy are not
created, destroyed, or transformed into each other, but are
separately conserved
Metabolism: all the physical and chemical processes that
take place inside an organism
‒ a flow of matter and energy (from food) in, through, and out
the body 5
Metabolism:

… IS INCREDIBLY COMPLEX – WHAT IS PRESENTED IN
THE NEXT SLIDES IS A MASSIVE SIMPLIFICATION.
 FOOD ENERGY
Energy exists in different forms that can transform into one another:
kinetic energy (motion), thermal energy or heat (motions of
molecules), chemical energy (potential energy of chemical bonds),
and others
The cells of living organisms are able to extract chemical energy from
food molecules through the complex process called cellular
respiration
In cellular respiration, monomers from food molecules are oxidized,
producing many ATP (adenosine triphosphate) molecules and heat in
the process, and carbon dioxide and water as waste products
monomers cellular respiration
food
from + CO2 + H2O
O2 chemic
al
energy ATP molecules heat
The heat keeps the body warm
ATP molecules pack energy and take it to where it is needed for physiological
functions and muscle motion
The body stores unused food energy as chemical energy in glycogen and fat
molecules
The body uses its glycogen and fat molecules for energy when food is
insufficient 7
KILOCALORIES AND “CALORIES”
Energy for body’s use is extracted from food
when food molecules are oxidized inside
body cells
a process similar to burning fuel to produce
kilocalories heat
In nutrition, food energy is commonly
measured in units of heat: kilocalories, or
food calories, or large calories (kcal or Cal)
familiarly but inaccurately called “calories”

kilocalorie = amount of energy required to
raise the temperature of 1 kg of water 1°C at
standard atmospheric pressure
– kilo = 1000
– calorie = energy required to raise the temperature
of 1 g of water 1°C at standard atmospheric
pressure
 HOW MUCH ENERGY DO WE NEED?
Estimated Energy Requirement (EER): energy intake needed to
maintain body weight
An individual’s EER depends on many factors
- height ‒health condition
- weight ‒being pregnant or lactating
- body composition ‒nutritional state
(proportion of muscle ‒stress
mass and fat) ‒hormones
- age ‒environmental temperature
- physical activity level
HOW MUCH ENERGY DO WE NEED?

kilocalories
per day
 DOES FOOD “BECOME”
Food does not ENERGY?
become energy.
Food is the source mass of
of matter and exhaled CO2 +
energy for the body excreted H2O
body! mass
mass in = mass stored +
Food = = energy
mass out stored +
=
energy in energy out
=
chemical heat and
energy in motion
physiologic
al
molecules,
and in
body fat
and
glycogen
 DOES BODY WEIGHT “BECOME”
ENERGY?
Weight (= gravity) is No Metabolic processes cannot
proportional to mass. transform mass into energy.
!
You could lose weight When the body’s demand for
moving to a place energy exceeds the food
with lower energy intake, the body
gravitational resorts to its energy store:
attraction. glycogen and adipose fat
molecules.
On Earth, losing The process of cellular
weight commonly respiration extracts energy
means losing mass. from body glycogen and fat
molecules and converts
them into ATP, CO2 and H2O
molecules
CO2 and H2O are expelled.
 REVIEW
Why do we need to eat?
Does the food we eat transform into
energy?
How is cellular respiration similar to
combustion?
What is the unit used to
measure the energy of
food?
What is another name for
the “food calorie”, and
how is it related to the
calorie?
13
 Cellular Respiration:

Three Processes, from food
to energy:
1. Glycolysis
2. Krebs Cycle/Citric Acid
Cycle
3. Electron Transport Chain
(ETC)
 Glycolysis:
An anaerobic process – no oxygen involved.
Occurs in the cytoplasm of the cell.
Converts one glucose molecule to two pyruvate
molecules.
Actual process requires several steps, but you only
have to know that glycolysis converts one
glucose into two pyruvate and two ATP (the
energy for the body).
 Aerobic process, requires oxygen.
(‘respiration” part of cellular
respiration)
Occurs in the mitochondria of the

Citric Acid cell.
Pyruvate enters into Krebs cycle, gets

or Krebs converted through several steps (you
don’t have to know those steps) into
ATP
Cycle: Along with the Electron Transport
Chain, cellular respiration creates 34
ATP for every glucose molecule that
enters the system, for a total of 36
ATP.
 Measuring Energy in the Body:
The chemical energy stored in food is released and made
available via ATP, in a process called cellular
respiration.
The way we measure this energy is by the calorie.
Calorie: a unit of measurement of heat, technically
defined as the amount of energy required to raise the
temperature of one gram of water by one degree.
In food, however, we don’t use the calorie, even though
we call it that. What we are measuring in food is actually
the kilocalorie. (1000 calories).
 HOW MUCH ENERGY
DOES FOOD PROVIDE TO OUR BODY?
The only food molecules from which our body can
extract energy are those of the macronutrients:
− carbohydrates, fats, proteins
Energy from food = energy from carbs + energy from
fats + energy from proteins
Metabolizable energy of a food = energy in the food –
energy losses due to incomplete digestion and excretion
Standard values of
metabolizable energy, or
Atwater values:
- from carbs = 4 kcal/g
- from fats = 9 kcal/g
- from proteins = 4 kcal/g
- from alcohol = 7 kcal/g
- from anything else = 0 kcal/g 18
 THE 4-9-4 RULE
The standard values of metabolizable energy give us a simple
method to estimate, approximately and on average, how much
energy a food or meal provides to the body, when the quantities
in grams of macronutrients in the food or meal are known

- Metabolizable energy from carbs (kcal) = grams of carbs x 4
kcal/g
- Metabolizable energy from fats (kcal) = grams of fats x 9 kcal/g
- Metabolizable energy from proteins (kcal) = grams of proteins x
4 kcal/g

- Metabolizable energy from food = metabolizable energy from
carbohydrates + metabolizable energy from fats +
metabolizable energy from proteins
19
 HOW ACCURATE ARE
THE STANDARD ENERGY VALUES?
Carbs, proteins, and fats from different foods have different metabolizable
energy content
The standard energy values are averages calculated after measuring
macronutrient composition, gross energy and energy losses due to
incomplete digestion and excretion of many different foods
Originally estimated by American scientist, Wilbur O. Atwater around 1900
for an average diet of people of European descent in his time in the USA
Modified Atwater Values, from kcalori
newer experiments (USDA es
1955 and 1973) with a
variety of diets have yielded
- averages that differ little
(typically no more than 5%)
from Atwater’s standard
values
- but non-negligible differences
between different foods Source: M. Nestle and M. Nesheim, Why Calories Count (2012), p.
37.
 REVIEW
What are the energy-giving nutrients?
Approximately and on average, how much
metabolizable energy is provided by each
of the energy-giving nutrients?

How much energy do the
other nutrients (non-
energy-giving nutrients)
provide?
What is the “4-9-4 rule”?

21
HOW MANY CALORIES IN A FOOD?
EXERCISE USING THE 4-9-4 RULE
One 12 g chocolate chip cookie
contains
- 8 g of carbohydrates
- 3 g of fats
- 1 g of proteins
Metabolizable energy from the
cookie:
8 g x 4 kcal/g = 32 kcal from
carbs
3 g x 9 kcal/g = 27 kcal from fats

1 g x 4 kcal/g = 4 kcal from
proteins Source: M. Nestle and M. Nesheim, Why Calories Count
(2012), p. 73.
Total = 32 + 27 + 4 = 63 kcal 22
MACRONUTRIENT DISTRIBUTION

Also called Dietary Reference Intakes (DRIs) for
macronutrients

Carbohydrates are the body’s primary energy source.
A healthy diet provides at least 45% energy from
carbs
In a healthy diet for adults, 20-35% of the energy
comes from fat and 10-35% from proteins
23
 MACRONUTRIENT DISTRIBUTIONS
(USING THE STANDARD VALUES)
One 12 g chocolate chip cookie
− energy = 8 x 4 + 1 x 4 + 3 x 9 = 63
kcal
− 32 kcal/63 kcal = 51% from carbs
− 27 kcal/63 kcal = 43% from fats
− 4 kcal/63 kcal = 6% from
proteins
One chocolate chip cookie and one 100 g banana:
− (8 + 23) g x 4 kcal/g = 124 kcal from carbs
− (1 + 1.1) g x 4 kcal/g = 8.4 kcal from proteins
− (3+ 0.3) g x 9 kcal/g = 29.7 kcal from fats
− Total energy = 124 + 8.4 + 29.7 = 162.1 kcal
− 76.5% from carbs, 5.2% from proteins, 18.3% from
fats
24
 REVIEW
Does a diet of chocolate-chip cookies
and bananas provide an acceptable
distribution of macronutrients?
Is a very low-fat diet (less than 20% of
calories from fat) associated with
reduced risk of chronic diseases?
Is a diet that provides less than 45%
calories from carbohydrates associated
with reduced risk of chronic diseases?
Given that the amounts of carbs,
proteins, and fats in coffee can be
regarded as negligible, how much
energy do you get from a cup of black
coffee?
What percentage of calories in your
© Toby Bridson diet should come from vitamins and
minerals? 25