Calculation of Prevalence and Incidence of Nutrition-Related Diseases in the Population PDF

Summary

This document discusses the calculation of prevalence and incidence of nutrition-related diseases in a population. It explores the connection between diet and lifestyle, and the impact of diseases like obesity, diabetes, and heart disease. It also touches on malnutrition and its effects.

Full Transcript

by Reza Hashemi

Calculation of Prevalence and Incidence of
Nutrition-Related Diseases in the
Population
1. Introduction to Nutrition-Related Diseases
Although malnutrition status can be categorized into undernutrition, obesity, and
micronutrient deficiencies, interest in the correlation between diet and lifestyle has
shifted with noticeable changes in disease epidemiology in developed countries.
Western lifestyles have been modified through rapidly extending life expectancy,
changes in living conditions, urbanization, and technological advances, causing
obesity, diabetes mellitus, hypertension, hyperlipidemia, heart disease, stroke,
cancer, and other chronic diseases related to lifestyle. Nutritional and lifestyle
approaches involving weight management, physical exercise, smoking control, and
stress management are beneficial strategies to prevent such diseases among the
population. The connection between chronic diseases and behaviors associated with
food, physical activities, and other lifestyle factors has drawn the attention of the
scientific community. Both nutritional deficiencies and excesses in the population
are considered nutrition-related diseases despite the primary focus of nutritional
care on physiological and metabolic risk factors for the most widely recognized
chronic diseases. As an underlying cause, the concept involves malnutrition status.
The concept of malnutrition includes both the multiple etiological syndromes of
malnourished children from deprived living conditions, without access to adequate
health care, including both undernutrition and chronic undernutrition disorders, as
well as the multiple etiological syndromes found in obese individuals, associated
with several chronic diseases.

1.1. Definition and Classification of Nutrition-Related Diseases
Undernutrition, overnutrition, and malnutrition may all result in major clinical
problems. While much has been previously made of undernutrition and its
relationship to such clinically important topics as wound healing, aging, mobility,
hospital length of stay, readmission rates, and mortality, as well as more standard

1
outcome metrics such as rates of infection, length of ventilation, and pressure sores,
lesser emphasis may have been placed on the potential relationship between
overnutrition or obesity and these same outcomes. The field of nutritional science
attempts to understand the relationship between diet, health, and physiological
performance.

The concept of nutrition-related diseases is a key term within the model. In certain
circumstances, individuals have sufficient food in terms of quantity or calories yet
still may suffer from malnutrition or nutrition-related diseases because the dietary
content is inadequate in terms of the required nutrients such as macronutrients,
micronutrients, vitamins, or minerals. Nutrition-related diseases include
undernutrition or undernourishment and overnutrition. Undernutrition may occur
due to a diet inadequate in energy or nutrients such as protein, vitamins, and
minerals, or from problems with absorption of nutrients like diarrheal diseases,
parasitism, or the use of specific medications. Undernutrition is the term for
conditions in which there is a shortage of calories, nucleotides, essential amino
acids, or essential fatty acids. In its early stages, this results in energy being
provided by the body's stores, which are often first depleted. Later, physical features
such as a greater reduction in muscle mass and subcutaneous fat occur so that the
general appearance of the patient becomes thin, and muscle wasting results in poor
physical strength, lowered immune function, vulnerability to infection, susceptibility
to diseases, slow healing, and so on.

1.2. Importance of Studying Prevalence and Incidence
Prevalence and incidence are two important epidemiological indicators that assess
the distribution of the disease in the general population. Together, these parameters
provide information that is useful for planning both the prevention of diseases and
the provision of health services. Understanding the prevalence and distribution of
nutritional diseases can be useful in certain stages of program planning, as this
information will help to identify, locate, and describe the target population of those
programs.

Prevalence is the measure used to express the magnitude of a disease or risk factor
in a geographic area and at a specific time. In general, when prevalence is used as a
measure of the magnitude of the problem, incidence and duration are not
considered. Prevalence is the data generally used both for the logistic planning of
prevention and control services and to evaluate the effectiveness of the services.
The duration of an episode of disease is the most profoundly misunderstood aspect
of the disease concept. Failure to recognize the importance of the duration of a
health event is a frequent source of avoidable waste in studies of the magnitude and
distribution of health phenomena. When the incidence of a mental dysfunction,

2
signs, or symptoms is high, the prevalence may reach very high levels because the
duration of the signs, symptoms, or dysfunctions is short. In the course of disease
and malnutrition in a population, the variability of the duration is greater than that
of the incidence or the prevalence.

2. Epidemiology Basics
Public examination of the situation in the field of dietology is seen in frequently
fixed violations of the diet and weight mode. However, irrespective of the
improvement of diagnostic and treatment facilities of practitioners and specialists, it
does not guarantee a decrease in the rate of primary diseases of a dietary nature.
Rationalization of nutrition organization is possible, providing public health through
the obligatory application of a complex approach to dietology. Carrying out an
organization-diagnosed measure with the aim of assessing the degree of satisfaction
of consumers of dietary services, the condition of clinic-nutrition of the population,
and the estimation of the correlation between dietarians providing presumed
alimentary dysfunctions and their real weight of disease is a basic moment.

Disease statistics continue to grow and make up 60% of the population. Assessment
of the role of prevalence, distribution, and germogenity of anthropogenic diet-
related constituents in the structure of general morbidity is essential for the
foundation of an organization directing dietary activities for the population. The
conspicuousness and activeness in growing nosology related to a manner of healthy
and regular supply of medical advice – pernicious to the point of properly stating
the functions of nutritional services of many doctors of dietary nature, either in the
appearance of diseases or in their deterioration of movement.

2.1. Key Concepts in Epidemiology
Prevalence and incidence are key concepts in epidemiology and describe different
features of the occurrence of a disease in a population. Prevalence is defined as the
proportion of the population with a specific characteristic or disease at a specific
time or the percentage of a specific population that is affected by a particular
condition at a specific time. P is the common symbol to represent prevalence.
Incidence is a measure of the risk of a disease in a particular population over a
duration of time or the number of new cases developing in a given span of time.
Prevalence is the proportion of the population in which the event has already
occurred (the proportion of current cases), while incidence is the proportion of
cases that occur in the population within a specific time span. In general, incidence
is expressed as rates, which are measures of the frequency with which an event
occurs in a defined population in a defined period of time. The incidence rate is the

3
number of new cases of a disease in a defined period of time, divided by the number
of people in the affected population at the start of the period.

2.2. Measures of Disease Frequency
The calculation of prevalence and, particularly, of incidence is easy when the data
are from secondary sources, but it can be complicated or even difficult when the
data must be obtained during a specific period. These calculations provide
important information for public health. Currently, the prevalence of obesity can be
easily obtained from many different databases. Moreover, technology and
biochemistry allow for obtaining data about lipid status and blood glucose at a rate
previously unimagined. However, although some estimates of iron deficiency are
available, the assessment of the prevalence of deficiency of many other vitamins or
minerals is extremely difficult. Furthermore, the health impact of many nutrition-
related diseases, especially those that present as signs or symptoms unspecific to
the disease, is underestimated, simply because their prevalence is not known.
Though mortality data related to protein-energy malnutrition are easier to obtain in
underdeveloped countries than in more developed ones, they are not good
measures of the health impact of undernutrition. Likely, data on mortality and
incidence morbidity rates would be much more informative.

In addition to the calculation of incidence and prevalence measures, the evaluation
of the methodology used can increase the knowledge that investigators could obtain,
or the accuracy of the results. Measures concerning the concordance of the
diagnosis are of particular importance. In practical terms, these results are obtained
by the repetition of the evaluation, for example, by the same observer in different
time periods, different observers in the same persons for prevalence evaluation, or
in relation to a gold standard to achieve their accuracy. They are the measures that
objectively show the classification rates into true or false positives or negatives,
which are so important in public health. Accurately classifying an individual as
unhealthy, healthy, or at risk makes it possible to direct specific food/nutrient
interventions to those who can really benefit.

3. Prevalence Studies
Prevalence or incidence data are essential for planning both healthcare and primary
prevention. This chapter provides some guidelines for the design, planning, and
implementation of a survey addressing the clarification of the prevalence and
incidence of some chronic diseases related to nutrient intake. Such information is
useful for prioritization in the allocation of financial and human resources and to
assess the impact of preventive measures. Having some reference to the background
risk of chronic and degenerative diseases, which can potentially be modified by an

4
appropriate intake of food constituents, it is possible to evaluate the effects of other
determinants, such as nutrient and energetic intakes and physical activity levels. In
other words, this type of study allows the evaluation of the strength of associations
between chronic disease occurrence and its potential risk factors.

The majority of studies to establish the prevalence of malnutrition in different
settings are characterized by the use of a cut-off point of nutritional status derived
from the distribution of values in large surveys of the general population.
Unfortunately, this approach violates one of the principles of epidemiology: that the
cut point should be taken from an independent data set. Indeed, a low level of
nutrition is a sensitive indicator of risks, showing an increasing trend with
decreasing consumption of various dietary components. Due to the natural history
of malnutrition, there is often a long and complex latency period between the
potential cause and the actual symptoms of a diet-related disease becoming
clinically evident. Prevalence and incidence data can be used to infer causation only
when they have been derived from randomized control trials and other intervention
studies, or from comparisons of a patient study group with a suitable control group.
The criteria for diagnosing nutrition-related diseases are not always
straightforward, and explicit criteria for the diagnoses will have to be decided in
advance.

3.1. Types of Prevalence Studies
Nutritional epidemiology is a relatively recent branch of epidemiology that studies
the relationship between diet, nutritional status, and health, and the means by
which diet, food, and nutritional status may be antecedent to the etiology of
diseases. This means that prevalence can be calculated in terms of any disease for
which the corresponding parameters of incidence and survival are known. This is
because, at any time, the survival rate is multiplied by the incidence rate. This is the
basis of the prevalence-incidence proportion and rate formulas. For nutrition-
related diseases, it is not always possible to calculate prevalence because the data
required to estimate either the number of new cases or the duration of the disease
in other than a fraction of the population are often not available. This chapter shows
how these basic rates can be used to calculate prevalence and incidence of nutrition-
related diseases using an equation that links the respective parameters of disease
frequency.

There are two types of epidemiological studies: observational and experimental, and
two of each type: cross-sectional and case-control for the first, and cohort and
experimental for the second. The two types correspond to the prospective and
retrospective approaches. Cross-sectional studies, also known as prevalence studies,
are designed to describe the frequency that certain diseases or conditions or their

5
determinants are distributed in the population. When the disease frequency
parameter is prevalence, a cross-sectional study is usually performed that involves
selection of a sample that is thought to be representative of the population, based on
which implications for the whole population are made. Randomly means that the
individuals invited to take part in the research are selected by chance from a list,
while chance represents an equal likelihood for each individual to be included in the
study.

3.2. Calculating Prevalence Rates
How can you calculate the percentage of the population to which a society's rate of
malnutrition relates? The initial time or month of illness is the initial time in the
calculation period, and the initial time of the last disease registration or the time of
death that occurred in the study period is the final time. All the members of the
closed cohort have the duration of observation equal to the final time, with the
endpoints set by the initial and final time. The observed prevalence is calculated by
dividing the sum of the number of ill-affected individuals by the sum of the duration
of observation of all the members of the cohort. The study population, with missing
observation for some time during the study period, has the duration of observation
equal to the final observation minus the last date of the last time until disease
registration. After the estimation of the definite time duration, the case definition
before and after adjustment of loss to follow-up should be included to calculate the
observed prevalence.

3.3. Factors Influencing Prevalence Estimates
The process of estimating the prevalence and incidence of nutrition-related diseases
in a population includes several important steps that are frequently neglected,
leading to biased results. These steps include problem definition and design of data
collection, choice of study population, appropriate statistical methods, and taking
into account such factors as temporal and spatial heterogeneity. We will start this
chapter with a discussion of ways in which the four main parameters of the
prevalence of any chronic disease—incidence, average duration, the cure rate, and
mortality—affect the magnitude of prevalence estimates across countries and over
time.

There are many well-known factors that influence cross-country or cross-time
comparisons of clinical markers of disease: non-comparability of definitions,
differences in rates of diagnosis and severity levels, differences in risk factors, and
response error in epidemiological data. Much less attention has been given,
however, to the potential influence of these differences in quantitative disease
estimates. Epidemiologists tend to control for other possible confounders but tend

6
not to call into question the estimation of the actual prevalence or incidence of the
disease as measured in different populations or at different times.

4. Incidence Studies
The incidence of disease describes the occurrence of new cases over a period of time
and is an important measure used to describe the burden of disease in a population.
Both point and period prevalence measures only give a picture of the scope of a
health problem in existence. In contrast, incidence estimates show the dynamic
nature of the health problem and can provide evidence of the underlying disease
process. Incidence measures are needed not only for description, but they are used
to estimate the effect of an exposure, the dose-response association, and the
strength of the association, all important components of causal inference. Incidence
data are needed for prevention and health care planning. They provide the
numerical basis for the benefits that may potentially accrue from implementing new
health policies or interventions, and estimates of the costs to be incurred as well.

The vast majority of nutrition work uses sources of data that collect information
from cross-sectional studies. Period cohort data would also be collected from food
consumption surveys. However, point cohort designs would need to be utilized to
collect the type of data needed to estimate the incidence of nutrition-related
diseases. Therefore, data collected in nutrition research are often predominantly
derived from long-term population cohort studies, with some also utilizing case-
control and case-cohort study designs. These study designs are used to get as close
to incidence without waiting. Although these are very good study designs, the cost
and resource allocation to conduct them, especially if using assays, or if the disease
of interest is one with a low incidence, would be prohibitive to use exclusively for
population research. Furthermore, food consumption survey data are considered a
lower level of evidence due to the inherent problems of using self-reported dietary
data. Regardless, the original reason long-term population studies were established
was to study the etiology of diseases that are rare in the population. The primary
goal of conducting an incidence study is to identify new cases of the disease. The
most costly type of incidence study design is one that collects complete information
on all members of the study population. However, this type of study design is only
needed if the population is not currently being measured and the information is not
available. Complete information can be utilized to estimate incidence and other
measures, such as duration of disease, many times over many times. The most
detailed information is available from complete information studies.

7
4.1. Types of Incidence Studies
Incidence studies can be retrospective, based on pre-existing clinical or hospital
records, or prospective, based on defined samples of a population. Prospective
cohort studies can determine the incidence of a certain condition within a defined
follow-up time. They usually have an initial condition, known as the baseline, when
the defined sample of the population that will undergo follow-up is detected.
Descriptive data about the studied sample are collected at baseline. The sample is
then visited at defined time points until the end of the study, when the presence of
the disease or condition is assessed. Study of such groups allows tests of statistical
associations between the population and exposure characteristics, and the event's
incidence.

Incidence is calculated as the new events that occurred in the specified time period
in a defined study population at risk of the disease at the beginning of the period.
Any new cases that happened during the study period are recorded through a
combination of prospective visits and/or through the use of linkage to existing
medical records. A follow-up schedule involving regular contact, especially for
chronic and disabling diseases, is necessary to maintain accurate data for all
participants. In adults, if the condition is chronic or progressive, a baseline age of 20
to 30 years is suitable, and it is advisable to examine the person at regular intervals
until some 70 years of age, or earlier if the endpoint is likely to occur.

4.2. Calculating Incidence Rates
Quantifying the magnitude of nutrition-related health problems at the population
level is a critical first step of nutritional surveillance required to guide and set
priorities for intervention programs. This measure permits the identification of
subpopulations at risk, and it is essential to evaluate the impact of interventions on
these goals. Incidence measures the rate of occurrence of new cases of a disease or
condition in a population at risk during a specified period of time. It is defined as the
ratio of the number of new cases developing within a specified time period to the
population at risk during the same time period.

Incidence measures provide important information to enable assessment of the
magnitude and importance of the nutrition-related problem in the population, as
well as of the specific physiological, dietary, or lifestyle conditions associated with
disease development, information which is fundamental for guiding primary
prevention programs. For example, information on the incidence of diabetes
throughout the period of growth in childhood at the population level has been
important to alert countries to the need to ensure implementation of healthy
lifestyle conditions. Information on incidence is also important for setting priorities

8
in assigning funds and other resources to nutritional surveillance activities, such as
studies of risk factors for disease or those directed towards assessing disease
outcomes in study situations which would eventually be extended to the population
level.

4.3. Relationship between Prevalence and Incidence
To relate prevalence with incidence, we need to describe the sequence of states or
categories through which the individuals in the population associated with the
respective study must pass. Let there be an idiosyncratic risk associated with
developing a new onset disease that is distributed over the individuals in the
population, such that Yi is 1 if an individual i has this idiosyncratic risk, and 0
otherwise. Let Xi be the calendar time until the individual either is censored from
the study, dies from a cause other than the disease, or has a new onset disease, if Yi
is 1. Let Ii be a binary indicator, such that it is 1 if an individual has a new onset
disease in interval t, and 0 otherwise. From this description, it can now be shown
that the prevalence of a nutrition-related disease at time t (Prt) is a function of both
its incidence as well as its duration.

Prt is simply the number of diagnosed individuals in the population at time t divided
by the sample size, which can be expressed as the total number of individuals who
are not censored from the study on or before t. Based on the data from the
surveillance, Prt can also be determined for the normal individuals, such that Pnt
differs from Pt. To avoid having a double subscript, let Pii be 1 until I reaches the
value 1, and 0 afterwards. If there are a sufficient number of intervals in the follow-
up period, Prt can be approximated using data on the number of new onset diseases
in the population, such that writing this statistic with a “hat” on top makes Prt-hat.
Then, the prevalence of normal individuals at time t can be expressed as: Pnt = 1 -
Pd - Pt-hat. If a nutrition-related disease has a very long duration, the prevalence
equals the prevalence of normal individuals at some time in the future. For the
nutrition-related diseases, Prt can be greater or lower than the prevalence of normal
individuals, such that: P, Prt - %, or, P, Prt + %. To represent these relationships, the
equation describing the prevalence of a nutrition-related disease at time t during
the survival study has three combined parameters: I(Y). The explanations leading to
these relationships are as follows. Individuals who have risk of developing a
nutrition-related disease cannot have a new or existing diagnosis, thus Ii has no
relationship to IYj, and Ii is 0 when Yi = 0. A similar statement can be made that I(Yi)
can take on values: I(Y), non-I(Y), and Yi, such that I, II(Yi) = I(Y), non-I(Y), Yi.

If Prt = Pnt, these three parameters are independent of each other. If a nutrition-
related disease has a median duration that is much less than the available follow-up
time for all individuals in the study, Prt < Pnt if I(Y) > non-I(Y), Prt = Pnt if I(Y) =

9
non-I(Y), or Prt > Pnt if I(Y) < non-I(Y). Some nutrition-related diseases have a
relatively long median duration, and some have a very long median duration, such
that the incidence of the nutrition-related disease is similar to the incidence of the
disease itself. For some of these diseases, existing cases have a long duration too.

5. Epidemiological Methods in Nutrition Research
Epidemiology is a set of methods used to describe and understand the frequency,
distribution, and causes of health problems in human populations. In this chapter,
we will explain the methods used to calculate some of the measures that are most
often used in nutrition research, and we will discuss the limitations of these
methods. As will be seen, a full discussion of the research methods used to study
nutrition and health would go well beyond the limits of a single chapter in the
present context. Once the methods of surveillance have been described, some of the
most important contributions of nutrition surveillance to public health will be
outlined, using the results of national nutrition surveys that have been conducted in
Western European countries during the 1980s as examples.

In order to study the relationships between dietary intake and health status, it is
often necessary to calculate the prevalence or incidence of nutrition-related health
problems. Prevalence is the nearly ubiquitous measure of the frequency of diagnosis
of an ailment that is found in a given period. It is the proportion of a population or a
defined subpopulation that is found to have a condition at a specific time. If there is
no scientific interest in the duration of the illness or in the natural history of the
disease, the concept of incidence is of little importance, and prevalence deserves
greater attention. Incidence is the measure of the occurrence of new cases of an
ailment that are observed in a given period. Prevalence is the counting of the
number of cases of a recognized illness, while incidence measures how the disease
actually occurs in time; that is, the probability of occurrence of the disease. Injury
and mortality rates may be seen as the incidence of certain specific maladies, but
researchers usually make this distinction with special terminology.

5.1. Study Designs in Nutrition Research
To plan the prevention and treatment, as well as the education of the public and
health policy, it is necessary to estimate the size of the nutrition-related health
problems in populations. The calculation of the size and trend of nutrition-related
health problems requires the collection of comprehensive data for the estimation of
the prevalence and incidence of diseases. The present communication outlines the
basic elements and essential techniques for the epidemiologic estimation of the size
and pattern of nutrition-related diseases in the population. The estimation of the
size of the nutrition-related health problems in populations is based on the

10
information retrieved from two main approaches: the collection of information from
all existing cases of recognized diseases in a population and the collection of data
from a sample of the existing cases for the estimation of the mean duration and
case-fatality rate.

5.2. Data Collection and Analysis Techniques
In general, data on the prevalence or incidence of nutrition-related diseases that are
derived from self-reporting may need to be enhanced by gathering medical records
or questionnaires to the potential respondents' usual medical care providers. Thus,
researchers must weigh the potential burden imposed on respondents, their
families, their employers, or governmental agencies against the value they gain from
using medical records data rather than just relying on self-reported data. The
researchers who gather information from medical records must design and
complete the data collection form that requests this information in a manner that
minimizes potential concerns about privacy and accuracy, including issues related
to confidentiality and the nature of the sensitive information that has been collected.

In addition to meeting the requirements of the Privacy and Security Rules of
relevant regulations, it is important for researchers to be aware of all other relevant
local, state, or national human subjects protection regulations that must be followed.
In addition, researchers should be aware of any Institutional Review Board
requirements to report to these research review committees any issues that may
surface regarding the provision of medical care to the survey respondents while
these individuals are participating in the survey, as well as any issues that are
identified during the process of obtaining requested medical records. In sum, the
collection of medical records is a cost-effective means to enhance the accuracy of the
data used for population-based health analyses, but it involves a number of steps
that researchers need to undertake to minimize the potential concerns of both the
medical records custodians and the surveyed individuals.

6. Challenges and Limitations in Epidemiological Studies
of Nutrition-Related Diseases
The purpose of this chapter is to specifically address the strengths and weaknesses
of epidemiological studies on nutrition-related diseases with respect to the
identification of associations between diet and disease. This session aimed to
examine how studies deal with these points by circulating methodological pointers
before the meeting. As a result, the reports from the four workshops can be
compared with respect to the pooling of studies, reliability, and comparability of
data on dietary intake, on outcomes, and on the reliability of the tools assessing diet

11
and disease. A starting point is the logical flow of epidemiological studies. Together,
these problems contribute to the consistency rarely found in association studies, for
instance, in the field of nutrition and health. The chosen nutritional status
parameter, either calculated by prevalence studies or linked to dietary intake, will in
turn influence the outcome. Clearly, the recommendations and the discussions
reported below should also be taken into account in the deliberations on developing
research strategies and collecting important new data.

Within the exploration of the reliability of nutrition and pathology data, the issue of
pooling studies to be used in a meta-analysis was addressed. Workshop discussions
demonstrated that careful consideration needs to be given to the potential sources
of heterogeneity before forming groups. Turning to dietary intake, it was reported
that study data were inconsistent in some studies. Except for a study involving
middle-aged women, the participants were drawn from an older population such
that information on current nutrient intake was not likely to reflect the nutrition of
a segment of the population at considerable risk for cognitive decline and
degenerative disease. Furthermore, interview data that is collected with less
structured techniques or is based on infrequent measurement is subject to
unreliable measurement over time.

7. Case Studies and Examples in Nutrition Epidemiology
Setting. The large majority of nutritional surveillance programs take place in
developing countries. Conditions include deficiency diseases, both lack and excess;
epidemiologic data are typically generated through dietary assessments, in some
cases in combination with biochemical assessments at the population level.
Investigations of nutrition-related chronic diseases in developing countries, where
these diseases are becoming important, have utilized the methods in use in Western
countries.

Example 1: Anemia in Vietnamese Women The results of an anemia survey in
Vietnamese women of childbearing age illustrate the estimation of prevalence of a
simple clinical sign. A national survey enumeration of subsequent consecutive
sampling, designed to be representative at the commune level, of households with
women aged 15–45 years as of the set date was carried out, followed by
examination of all nonpregnant women in the selected households for hematocrit
values. The national prevalence of anemia in this group was 35.3 percent. Economic
trends in Vietnam, along with massive social changes and increasingly liberal
agricultural policies, have enabled Vietnam to escape from the nutritional crisis the
country was experiencing in the mid-1980s. Normative values for hematocrit to
serve as the basis for assessing the prevalence of anemia were 37 for a pregnant

12
woman, 36 for a non-pregnant woman, and 35 for a woman who was in her first or
second trimester of pregnancy.

13