Biochemistry of Nutrition Topic 12 Nutrition Methodology PDF

Summary

This document provides an overview of nutrition research methodology. It covers statistical concepts related to research, validity, accuracy, reliability, precision, and different types of studies. It also discusses in-vitro and animal models as well as human intervention studies.

Full Transcript

Biochemistry of Nutrition
BIOC1305
 Topic 12
Nutrition Research Methodology
 Statistical analysis and experimental design

In all areas of research, statistical analysis of results and data plays a pivotal role.
This chapter is intended to give students some of the very basic concepts of
statistics as it relates to research methodology

Validity
Validity describes the degree to which the inference drawn from a study is
warranted when account is taken of the study methods, the representativeness
of the study sample and the nature of its source population.

Validity can be divided into internal validity and external validity.
Internal validity refers to the subjects sampled.
External validity refers to the extension of the findings from the sample to a
target population.
Accuracy
It describes the extent to which a measurement is close to the true value, and it
is commonly estimated as the difference between the reported result and the
actual value.

Reliability
It refers to the consistency or repeatability of a measure.
Reliability does not imply validity.

A reliable measure is measuring something consistently but not necessarily
estimating its true value.

If a measurement error occurs in two separate measurements with the same
magnitude and direction, this measurement may be fully reliable but invalid.

Precision
Precision is described as the quality of being sharply defined

In a more restricted statistical sense, precision refers to reducing random error.

It can be improved by increasing the size of a study or using a design with higher
efficiency.
 Accuracy is a term used to describe the extent to which a measurement
is close to the true value, and it is commonly estimated as the difference
between the reported result and the actual value

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Sensitivity and specificity
Measures of sensitivity and specificity relate to the validity of a value.

Sensitivity is the proportion of subjects with the condition who are correctly classified
as having the condition.

Specificity is the proportion of persons without the condition who are correctly
classified as being free of the condition by the test or criteria.

Sensitivity reflects the proportion of affected individuals who test positive, while
specificity refers to the proportion of nonaffected individuals who test negative

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 Importance of generating and testing hypothesis

generating a testable working hypothesis is the first step towards conducting
original research. Such research may prove or disprove the proposed
hypothesis. Case reports, case series, online surveys and other observational
studies, clinical trials, and narrative reviews help to generate hypotheses.

A hypothesis should be tested by ethically sound experiments with meaningful
ethical and clinical implications.

The coronavirus disease 2019 pandemic has brought into sharp focus
numerous hypotheses, some of which were proven (e.g. effectiveness of
corticosteroids in those with hypoxia) while others were disproven (e.g.
ineffectiveness of hydroxychloroquine and ivermectin)
 Sample size calculation

One of the pivotal aspects of planning a clinical study is the calculation of
the sample size. It is naturally neither practical nor feasible to study the
whole population in any study.

Hence, a set of participants is selected from the population, which is less
in number (size) but adequately represents the population from which it
is drawn so that true inferences about the population can be made from
the results obtained. This set of individuals is known as the “sample.”

In a statistical context, the “population” is defined as the complete set of
people (e.g., Indians), the “target population” is a subset of individuals
with specific clinical and demographic characteristics in whom you want
to study your intervention (e.g., males, between ages 45 and 60, with
blood pressure between 140 mmHg systolic and 90 mmHg diastolic),
and “sample” is a further subset of the target population which we would
like to include in the study. Thus a “sample” is a portion, piece, or
segment that is representative of a whole.
 In vitro studies

In vitro studies represent part of the reductionist approach in nutrition research.

The range of techniques used is large:

Chemical analysis studies provide data on nutrient and non-nutrient content of
foods.

Digestibility techniques, in which a substrate is exposed to enzymes capable
of digesting the substrate, help to refine the gross chemical analytical data to
predict nutritional potential.

Intact organs such as the liver of experimental animals can be used in
studies such as perfused organ studies. In such studies, the investigator can
control the composition of material entering an isolated organ and examine the
output.
 Sections of organs can also be used, such as the everted gut sac
technique.

A small section of the intestine is turned inside out and placed in a solution
containing some test material

Another approach is the construction of mechanical models that mimic an
organ, usually the gut (in nutrition research).

Many of these models successfully predict what is observed in vivo and
have advantages such as cost and flexibility in altering the experimental
conditions with great precision.
 Animal models in nutrition research

Whole animal systems have been used in measuring the utilization,
function, and fate of nutrients.

There are many reasons for choosing an animal study over a human
study. We can and do subject animals to experimental conditions that
we would ethically not be allowed to apply to humans.

For example, to study how a nutrient influences the scale and
histopathology of atherosclerosis, animal studies are needed.

Just as studies with humans are governed by the rules of ethics
committees, so too are studies with animals.
 In general, the use of animals as models for human nutrition research can
be examined from three aspects:
the animal model
the experimental diet and its delivery
the experimental techniques available

The animal model
Many species have been used in the study of nutrition.
Many are pure-bred strains such as the Wistar rat, the Charles River
mouse, or the New Zealand white rabbit.

Some animal models have been specially selected to exhibit particular traits,
making them very useful models for research.

The Wattanable rabbit has defective low-density lipoprotein (LDL)
receptor function, making this animal model very useful for studying the
role of diet in influencing LDL receptor mediated arterial disease.
 The ob/ob mouse develops gross obesity because of an alteration in
a genetic profile (leptin synthesis).

In recent times there has been a rise in the use of transgenic animal
models that have been produced through advanced molecular genetic
techniques.

In such models, specific genes can be inserted or deleted to fulfill
specific functions.
For example, the peroxisome proliferator-activated receptor- alpha
(PPAR-) is not expressed in one knockout mouse model, giving rise to fat
accumulation.

Another example of a transgenic mouse presents an overexpression of
the Cu/Zn-superoxide dismutase enzyme.
 The experimental diet and its delivery

The nature of the diet and its mode of delivery are centrally important
in understanding the role of animal models in human nutrition issues.

There are several types of diets offered to laboratory animals.
Commercially available diets made to internationally accepted
nutritional norms are often referred to as chow diets or laboratory
chow.

For the vast majority of laboratory animals in studies where nutrient
intake is not the central area of interest, such chow diets are used.
However, when nutrition is the area of research, special diets will
almost always have to be formulated.

The type of diet that needs to be formulated will depend on the
nature of the research question.
 In ad libitum feeding the animals have free access to food; in controlled
feeding animals are offered a limited amount of food (restricted feeding) or
receive as much food as can be fed to them (forced feeding).

There are many reasons why pair feeding is critically important.

An experiment may seek to examine how a new protein source, rich in
some nutrient of interest, influences some aspect of metabolism.

Let us consider a compound in the protein source that may reduce blood
LDL cholesterol. A control diet is constructed based on casein.

In the experimental diets, this casein is replaced on an isonitrogenous basis
with the test protein source.

Other-wise the diets are identical.

After several weeks of ad libitum feeding a blood sample is taken and the
results show that blood cholesterol rose with the experimental diet
 The experimental techniques available

The outcome of variables of interest to be assessed condition the experimental
techniques to be applied, which may include growth curves, nutrient and energy
balance, nutrient utilization, and signaling, etc., using cellular, molecular, or other
strategies.

Another approach to investigating nutritional processes is to overexpress,
inactivate, or manipulate specific genes playing a role in body metabolism.

These new technologies allow the study of the regulation and function of
different genes.

The current standard methods for manipulating genes in nutrition research
depend on the method of introducing/blocking genes.

Thus, genetic manipulation can be sustained for generations by creating germline
transmission
 Human studies
In human nutrition, man is the ultimate court in which hypotheses are both
generated and tested.

Experimental human nutrition takes the hypothesis and through several
experiments, tries to understand the nature of the link between nutrients
and the metabolic basis of the disease.

Once there is a reasonable body of evidence that particular nutritional
conditions are related to the risk of disease, experimental nutritional
epidemiology examines how population-level intervention actually
influences the incidence of disease
 Human nutrition experimentation
The use of experimental animals for human nutrition research offers many
possible solutions to experimental problems.

However, the definitive experiments, where possible, should be carried
out in humans.

Studies involving humans are more difficult to conduct for two major
reasons.
First, humans vary enormously compared with laboratory animals. They
vary genetically, and they also vary greatly in their lifestyle, background
diet, health, physical activity, literacy, and in many other ways.
Second, it is far more difficult to manipulate human diets since we do not
eat purified or semi-purified diets.
 Experimental diets in human nutrition
intervention studies
In the 1950s, an epidemiological study across seven countries presented data to
suggest that the main determinant of plasma cholesterol was the balance of
saturated, monounsaturated, and polyunsaturated fatty acids (MUFAs and PUFAs).

To test this hypothesis, a series of studies was carried out on human volunteers using
“formula diets.” Dried skimmed milk powder, the test oil, and water were blended to
form a test milk with specifi c fatty acid compositions.

The volunteers lived almost exclusively on these formulae.
Although this type of study is simple to conduct, it does not represent the true
conditions under which normal humans live.

At the other end of the spectrum of options for manipulating human diets is that of
issuing advice that the subjects verify by way of a food record.

It is difficult to prove that subjects actually ate what they say they have eaten.
Sometimes, adherence to dietary advice can be ascertained using tissue samples
(blood, saliva, hair, fat) and biomarkers. For example, adherence to advice to
increase oily fi sh intake can be monitored using platelet phospholipid fatty acids.
 In the case of minerals and vitamins, it is possible simply to give out pills
for the volunteers to take and measure compliance by counting
unconsumed pills and perhaps using biomarkers.

When it comes to macronutrients, this is not generally possible.
Whereas asking someone to take a mineral supplement should not alter
their eating habits, asking someone to consume a liter of milk a day or a
bowl of rice bran per day will alter other aspects of the diets of the
volunteers.

It will not then be possible to attribute definitively an event to the
intervention (1 l/day of milk or 1 bowl/day of rice bran).

The only option in human intervention experiments is to prepare foods
for volunteers to eat, which differ only in the test nutrient.
 If the objective is to examine the effect of MUFAs relative to saturated
fatty acids (SFAs) on blood lipids, then fat-containing foods can be
prepared that are identical except for the source of the more foods and
dishes that can be prepared in this way, the more successful the
experiment will be.

The final dilemma is where the test foods will be consumed. A volunteer
may share the test foods, which are almost always supplied free of
charge, with friends or family.

To be sure of consumption, volunteers may be asked to consume the
test meal in some supervised space, usually a metabolic suite.

This, however, is a very costly option.
 Study designs in human nutrition
The randomized clinical trial is the most powerful design to demonstrate
cause-effect relationships.

It is unique in representing a completely experimental approach in
humans.

The major strength of randomized trials is that they are able to control
most biases and confounding factors even when confounding factors
cannot be measured.
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