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S Afr Fam Pract
ISSN 2078-6190    EISSN 2078-6204 

© 2018 The Author(s)

REVIEW

Introduction

Confronted with the reality of an overweight and progressively 
obese society, clinicians are faced with one of the most serious 
medical dilemmas in modern history. In fact, 6 of the 10 most 
common causes of death in South Africa,1 three of which 
rank second, third and fourth, can be caused, exacerbated or 
complicated by being overweight.2-4 They are diabetes mellitus 
type 2, cerebrovascular-related diseases, heart diseases not 
related to cerebrovascular incidents, hypertension, chronic lower 
respiratory diseases, and ischaemic heart disease. Applying 
body-mass index (BMI) as a rough guide only, an overweight 
adult will present with a BMI of more than 25, while an obese 
adult will nominally have a BMI of greater than 30.5  In children 
under 5 years of age, a weight-for-height value greater than 
2 standard deviations above the World Health Organization 
(WHO) Child Growth Standards (CGS) median classifies as being 
overweight, while obesity is diagnosed if said value is greater 
than 3 standard deviations above the WHO CGS median.5  Based 
on these criteria, the South African prevalence of overweight and 
obesity, respectively, is considerable reason for concern (Table 1).

Although the treatment of overweight and obesity is a crucial first 

step in the prevention and treatment of secondary comorbidities, 

clinicians are increasingly faced with an overweight society 

in need of medical attention for conditions that may not 

necessarily be related to being overweight or obese. That said, 

having a higher than normal BMI contributes significantly to 

changing the clinical profile of patients and how they respond 

to therapeutic intervention. The current paper will therefore 

attempt to highlight key aspects of relevance with respect to 

the general principles that must guide clinical approaches to 

overweight and obese patients. Not focusing on the treatment 

of obesity per se, we will address the following areas of interest:

• How being overweight affects a normal physiological and 

pharmacokinetic profile, especially concerning aspects that 

can influence drug action and that are markedly affected by 

obesity; and

• Common comorbidities and secondary pathologies and how 

best to approach them in primary practice.

South African Family Practice 2018; 60(3):40-46
 
Open Access article distributed under the terms of the 
Creative Commons License [CC BY-NC-ND 4.0] 
http://creativecommons.org/licenses/by-nc-nd/4.0

Working Around the Problem: The Impact of Being Overweight and Obese on 
the Treatment of Clinical Illness 
Sarel Brand,a Linda Brand,b De Wet Wolmaransb*

a Unit for Environmental Sciences and Management, North-West University, Potchefstroom, South Africa
b Center of Excellence for Pharmaceutical Sciences, North West-University, Potchefstroom, South Africa
*Corresponding author, email: dewet.wolmarans@nwu.ac.za

Abstract

Overweight and obesity are not only two highly prevalent conditions in the South African society, but they also contribute to 
6 of the 10 most common causes of death. Further, being overweight not only results in significant metabolic and endocrine 
disturbances, it also changes how patients respond to most pharmacotherapeutic interventions for clinical illness. The present 
paper will attempt to elucidate some of the most common physio-pathological phenomena associated with being overweight 
and obese. We will briefly focus on the manner in which especially excessive visceral adipose tissue contributes to an altered 
physiological state and pharmacokinetic profile, while highlighting important clinical aspects of comorbid conditions that are 
frequently observed in this patient cohort.

Table 1 - Percentages of the South African population that are overweight and obese, respectively 
Adapted from6

% Overweight % Obese World Obesity Ranking

Men

Adults 41 15
105

Boys and Adolescents 20 10

Women

Adults 65 40
18

Girls and Adolescents 29 13



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Species aside, being overweight or obese changes 
almost everything else

A matter of location – visceral adipose tissue and the 
simulation of nutrient overload

Excessive adipose tissue changes the physiological functioning 
of the human body in several ways, none of which are 
advantageous.7 Importantly, visceral (i.e., abdominal) adipose 
tissue, and not so much lower body or subcutaneous fat, is reason 
for concern.8,9 Indeed, whereas excessive visceral body fat is 
associated with an increased risk of metabolic complications, e.g., 
diabetes, heart disease, and dyslipidemia, increased lower body 
fat mass carries no such risk.9 Moreover, waist circumference, in 
most instances an accurate measure of abdominal fat mass, is a 
better predictor of metabolic complications than BMI.10

Visceral adipose tissue contributes in a distinctly different 
manner from subcutaneous adipose tissue in altering the 
physiological processes of the human body. Not only is 
abdominal fat more lipolytically active than subcutaneous fat 
due to its higher expression of noradrenergic receptors, it is also 
resistant to the anti-lipolytic effects of insulin.11 This, together 
with its significant capacity to convert inactive cortisone to 
active lipolytic cortisol, results in a constant release of free fatty 
acids in the systemic circulation.11 Although metabolic responses 
to a constant elevation in free fatty acid concentrations differ 
between patients,12 accelerated processes of lipolysis can in 
simple terms be equated to a nutrient overload, as even when 
they are fasting, overweight and obese patients present with 
high free fatty acid levels. This phenomenon paves the way for 
noteworthy physiological consequences as free fatty acids and 
other nutrients must either be utilised in processes of growth 
or energy expenditure, or be stored. Considering that the 
adipose storage capacity in overweight and obese patients is 
already under significant pressure, and that visceral fat is prone 
to accelerated processes of lipolysis, free fatty acids for which 
there is no storage space in adipose tissue are unavoidably 
stored in non-adipose tissues.13 These include skeletal muscle 

cells, hepatocytes, capillary endothelium, and pancreatic β-cells. 
As these tissues are not suitable for the storage of triglycerides, 
a range of adaptive and maladaptive processes, i.e., systemic 
inflammation, are triggered; these in turn contribute to and 
exacerbate metabolic complications, e.g., insulin resistance and 
cardiovascular disease.14

Excessive adipose tissue adds another, not so friendly, 
endocrine organ

Adipocytes, especially abdominal cells, function as a collective 
endocrine organ that releases several hormones and cytokines 
into the blood stream.14 In a lean adult that has in the order of 
35 billion adipocytes, each containing 0.4–0.6 µg of triglycerides, 
these molecules function to regulate and maintain body 
energy stores.7 However, in overweight and obese patients 
who may present with up to 125 billion adipocytes which 
can store up to 1.2  µg triglycerides per cell, the endocrine 
functions of fat cells may have significant deleterious effects. 
These include an inability to feel satiated, the development of 
hormonal disturbances, e.g., hirsutism, anovulation, and insulin 
resistance, as well as pathological neuroinflammatory processes.  
Table 2 briefly summarises the likely physiological sequelae 
in overweight and obese patients resulting from the excessive 
secretion of hormones and cytokines by adipose tissue.

Adipose tissue – the architect that redesigns body 
compartments

The human body broadly consists of hydrophilic aqueous and 
lipophilic fatty compartments.26 Generally, lipophilic compounds, 
e.g., steroid and thyroid hormones and lipid soluble drugs, will 
demonstrate a greater volume of distribution and a longer half-
life in patients with a higher adipose mass, compared to those 
with a greater lean mass, while the opposite is true for most 
hydrophilic molecules, e.g., peptide hormones, catecholamines, 
and water-soluble drugs.27 Following release or administration, 
endogenous molecules and drugs are distributed to target 
tissues via the blood stream. As most compounds only exert 
clinical effect in their free forms, i.e., when they are not bound to 

Table 2 - Adipose tissue as an endocrine organ

Hormone Physiological Effect in Overweight and Obese Patients

Leptin • Excessive levels of leptin are associated with leptin resistance and an inability to feel satiated.15,16

Resistin • Increased levels of resistin are associated with insulin resistance, hyperglycemia and type 2 diabetes mellitus.17

Adiponectin
• Lower rates of adiponectin secretion are found in obese patients; however, this is associated with insulin 

resistance, hyperinsulinemia and type 2 diabetes mellitus.18

Estrogens

• Increased levels of estrogens in obese patients result from inherent expression of P450 aromatase in 
adipocytes, in this case especially those located in the lower body19 – aromatase converts androgenic 
precursors to estrogen;

• Physiological impact includes gynecomastia in men20 and anovulation, dysfunctional menstrual bleeding and 
polycystic ovary syndrome in women.21

Androgens
• Increased conversion of weak androstenedione to potent testosterone;22

• Physiological impact includes hirsutism, anovulation and polycystic ovary syndrome in women.22

Tumor Necrosis Factor-α
• Increased levels, though not detectable in plasma assays, have several paracrine effects, including interference 

in insulin signaling.23

Interleukin-6
• Excessive IL-6 production results in insulin resistance, systemic inflammation, pancreatic β-cell degeneration, 

and hyperglycemia.24

Plasminogen Activator 
Inhibitor-1

• Elevated levels, driven by increased IL-1, estrogen, TNF- α, and insulin increase the risk for thromboembolism, 
and myocardial infarction.25



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plasma carrier proteins or organ tissues, homeostatic control over 
endogenous substances is exercised based on the concentration 
of the unbound, free fraction in plasma, and not the fraction of 
the compound harbored in organs, tissues and the paracellular 
space. Changes in body composition can affect such regulatory 
processes in several ways. For instance, although some exceptions 
exist, lipophilic hormones and drugs that distribute into and are 
stored in adipocytes and other lipid-containing intracellular 
spaces will not only exhibit a longer half-life but will also take 
longer to reach a physiologically and therapeutically adequate 
steady state free fraction. To the contrary, most water-soluble 
compounds, e.g., peptide hormones and polarised drugs will, 
following release into the blood stream, exhibit shorter half-lives 
and reach steady state quicker in overweight or obese patients, 
compared to patients with a larger aqueous compartment. 
Another example of how changes in body composition may alter 
the pharmacokinetic properties of compounds can be found 
in altered plasma protein concentrations. Indeed, albumin,28 
sex hormone binding globulin7 and thyroid hormone binding 
globulin29 increase in obese patients and may result in a slower 
onset but longer duration of drug action as well as longer half-

lives. It suffices to say that changes in the ratio between the 

relative percentages of adipose and aqueous compartments, will 

yield distinctly different physiological and pharmacotherapeutic 

outcomes in different individuals. Table 3 summarises some of 

the most common phenomena from a therapeutic perspective 

in this regard.

Common comorbidities in overweight and obese 
patients of relevance for primary practice

As highlighted in Section 1, overweight and obese patients 

represent a large cohort of the South African society and 

clinicians will increasingly be challenged to treat medical 

conditions in these individuals. Moreover, it is likely that patients 

in this category that seek medical attention for specific common 

conditions, e.g., colds and flu, will either covertly or overtly 

present with other weight-related comorbidities. Although 

the treatment of these comorbid conditions must primarily be 

addressed by weight loss, this section will focus on some of the 

most common conditions that directly result from the bolstered 

endocrine capacity of excessive adipose tissue.

Table 3 - A summary of pharmacokinetic modifications in overweight and obese patients

Parameter altered Physiological and pharmacotherapeutic impact

Steady state • Steady state of lipophilic drugs, e.g., sex steroids and narcotics, will be delayed; however, it will not be affected as 
much following missed doses as in patients with a lower adipose mass.

Onset of action • Onset of action may be delayed for lipophilic drugs, e.g., opioids and benzodiazepines; if rapid relief is needed, 
loading doses should be calculated based on total body weight.

Duration of action • Due to its larger volume of distribution in obese compared to lean patients, lipophilic drugs will remain in the body 
for longer. As such, drugs may elicit a pharmacological or toxicological response for longer than anticipated.30

• Importantly! As most compounds function within a narrow therapeutic window with respect to the circulatory 
free fraction, it is unlikely that the slow release of drugs by fat stores will be sufficient to maintain an adequate 
therapeutic response. Steady state of lipophilic compounds is reliant on the equilibrium reached between the 
plasma protein bound and unbound drug fractions, respectively. However, in the event of drug withdrawal, a new 
state of equilibrium will be reached between the amount of drug stored in adipose tissue, and the concentrations 
released into the circulatory system. This process is, however, not only dependent on drug concentrations but can be 
affected by other factors, including diet changes, exercise, and cardiovascular function.

• Therefore, although some exceptions exist where this phenomenon is applied to a therapeutic advantage, i.e., oral 
isotretinoin or topical estrogen for dermatological conditions, it is highly unlikely that adipose stores of lipophilic 
drugs will contribute significantly to their therapeutic effect.

Efficacy • Efficacy is defined within the context of drug administration. For example, in the case of acute conditions, e.g., pain, 
analogous doses administered in lean and overweight patients, respectively, will elicit markedly different responses. 
However, where drug action is not related to acute conditions or where rapid increases in drug concentration are not 
needed, as is the case with high-dose glucocorticoids, efficacy will be less affected in overweight, compared to lean, 
patients.

Toxicity • As referred to above, fat stores of drugs will not necessarily contribute to maintaining an adequate therapeutic 
effect. However, they may contribute significantly to drug toxicity. In the case of amiodarone, a highly lipophilic 
antiarrhythmic drug that can be stored in adipose tissues for weeks after its administration, clinically significant 
thyroidal and mucosal inflammation can ensue drug withdrawal. Also, isotretinoin, a highly teratogenic compound 
used in the treatment of acne, can exert such effect for months after discontinuation. Therefore, as such residual 
drug effects can occur for longer in overweight and obese, compared to lean, patients due to the depot effect, great 
caution must be applied in such scenarios.

Therapeutically important 
fluctuations

• Under certain circumstances, fluctuations in endogenous molecules or exogenously administered drugs are 
important to facilitate therapeutic action. For example, most physiological functions related to sex hormone 
physiology, i.e., ovulation and menstruation, are dependent on rapid changes in hormone concentration. Further, 
successful treatment of related pathologies, e.g., amenorrhea, menorrhagia, and anovulation, depend on the same 
principles. For example, in the treatment of amenorrhea, high dose progesterone is administered for 7–10 days, 
followed by rapid, sudden withdrawal. Only then is the response in prostaglandin synthesis and neuroendocrine 
activation of the hypothalamus sufficient to induce menstruation and trigger gonadotropin releasing hormone 
(GnRH) release, respectively. In overweight and obese patients, such rapid fluctuations in the concentrations of 
lipophilic compounds are masked, leading to related pathologies and inadequate treatment responses in most 
patients.



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Fact Box for Clinical Practice:  Metabolically Normal Obesity
As opposed to the majority of obesity cases in which marked metabolic 
disturbances, e.g., insulin resistance, dyslipidemia, and elevated blood 
pressure, are observed, approximately 25–32% of patients present 
with no such symptomology.31 Attempts to elucidate this phenomenon 
resulted in the finding that metabolically normal obese patients, 
though presenting with equal percentages of body fat, have less 
visceral and hepatic fat stores, but more subcutaneous and peripheral 
fat deposits32,33. These patients, that in some cases have been followed 
and monitored for up to 11 years,34 did not present with elevated risks 
for cardio-metabolic pathology, compared to lean controls. In contrast, 
metabolically complicated patients, lean or obese, presented with a  
4- to11-fold increased relative risk for diabetes mellitus type 2, compared 
to metabolically normal individuals of average weight.35 These findings 
highlight the importance of not overly simplifying approaches to specific 
cohorts of patients.

Comorbid conditions in men

Gynecomastia

Gynecomastia manifests in adult men due to various underlying 
pathologies or treatments that either increase or potentiate 
the effect of oestrogen, or decrease or inhibit the effect of 
testosterone.36 In overweight and obese men, gynecomastia 
results from increased conversion of androgenic precursors to 

oestrogen (Table 2). Apart from surgical procedures to remove 
excess breast tissue, pharmacological options can also be 
considered. However, if conspicuous symptoms have been 
present for longer than 1 year, pharmacological intervention is 
unlikely to be effective. That said, some pharmacological options 
have shown demonstrable efficacy during the initial proliferative 
phases of breast development. These are summarised in  
Table 437,38:

Comorbid conditions in women

Hirsutism

Hirsutism, i.e., excessive hair growth in areas that are usually not 
hairy, e.g., on the face, is a clinical manifestation of the accelerated 
adipose synthesis of androgenic hormones (Table 2) and may be a 
significant problem in some overweight and most obese women. 
Normally, obesity-related hirsutism will be associated with other 
symptoms of masculinisation, e.g., acne, deepening of the voice, 
amenorrhea, clitoral hypertrophy, and increased muscularity.39 
Treatment is directed at either bolstering estrogenic stimulation, 
or inhibiting androgenic stimulation, or a combination of both. 
Appropriate strategies are listed in Table 5.40

Table 4 - Drugs recommended for the treatment of gynecomastia 
Important – none of the listed drugs are registered for use in gynecomastia; they are however used off-label.

Drug Dose Notes
Tamoxifen 

Kessar® / Novadex-D® / Tamoplex® / TamoxiHexal® 
/ Neophedan®

20 mg per day for 3 months
Adverse effects, including deep vein 
thrombosis are relatively uncommon

Anastrazole 
Arimidex® / Accord-Anastrazole® / Everdex®/Mylan-

Anastrazole® / Stradexa®

1 mg per day for 3 months depending on the 
therapeutic response

Adverse effects are uncommon. However, 
monitor for renal and hepatic disease

Letrozole 
Femara® / Accord-Letrozole® / Cipla-Letrozole® / 

Laradex® / Trozolt®

2.5 mg per day for 3 months depending on the 
therapeutic response

Adverse effects as for anastrazole

Exmestane 
Aromasin®

25 mg per day for 3 months, depending on the 
therapeutic response

Adverse effects as for anastrazole

Table 5 - Drugs recommended for the treatment of hirsutism
Drug / Formulation Dose Notes

Combination Oral 
Contraceptives 

Diane-35® / Minerva-35® / 
Ginette® / Marvelon® / Yasmin® / 

Femodene ED® / Nordette®

As treatment is indicated in overweight to obese 
patients, ethinyl estradiol doses should not be 
lower than 30 µg per day but should also not 
exceed 35 µg.

• Progestin components can either be androgen-neutral, 
e.g., gestodene, levonorgestrel, norgestrel, or desogestrel, 
or anti-androgenic, e.g., drosperinone, cyproterone, 
dienogest;

• Can be augmented with up to 50 mg cyproterone  
(see below) from day 1–21 of the active tablets;

• Adverse effects and contra-indications to be monitored 
and considered are related to the risk for deep vein 
thrombosis. Overweight to obese patients are especially 
at risk and need to be followed up every three months. 
Avoid use of COCs especially in women with a history of 
deep vein thrombosis, those presenting with migraine 
accompanied by prodromal aura, or in women who smoke 
more than 10 cigarettes per day.

Cyproterone 
Androcur® / Cipla-Cyproterone® / 

Cyproplex®

• In women with an established and regular 
menstrual cycle:  Initially, 10–50 mg per day 
from day 5–14 of the menstrual cycle, titrated 
upwards to a maximum of 100 mg if no clinical 
response is observed within 3 months;

• In anovulatory women presenting with 
amenorrhea and irregular bleeding, 10–50 mg 
per day, titrated upwards to a maximum of  
100 mg per day if no clinical response is 
observed within 3 months.

Most common adverse effects include vaginal xerosis and 
decreased libido

Spirinolactone 
Aldactone® / Spiractin® / Sandoz-

Spirinolactone®
-

Avoid. See “Fact Box for Clinical Practice:  The Jekyll-and-Hyde 
Personality of Spironolactone”



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Fact Box for Clinical Practice:  The Jekyll-and-Hyde Personality of 
Spironolactone

Spironolactone is predominantly an aldosterone receptor antagonist41 
and is used in the treatment of cardiovascular disease as a potassium 
sparing diuretic. However, it has long been known that administration 
of spironolactone in adult men and premenopausal women can cause 
significant endocrine disturbances related to both masculinisation in 
women and the development of female characteristics in men.41-43 As 
such, research has demonstrated that spironolactone most likely acts 
as a partial agonist on a range of steroid hormone receptors, including 
the glucocorticoid, androgen, and oestrogen receptors.27,44. The effects 
of all partial agonists are dichotomous in that they can elicit either an 
agonistic or antagonistic response, depending on the concentration of 
the endogenous ligands present. Thus, in men who normally present with 
high endogenous testosterone but low oestrogen levels, spironolactone 
will most likely express antagonistic properties, producing a softening of 
the voice and gynecomastia. However, in women who normally present 
with high oestrogen but low testosterone levels, spironolactone will 
often induce symptoms related to virilisation, including hirsutism and 
anovulation.

The use of spironolactone in women presenting with hirsutism is applied 
from the perspective that such patients already present with lower 
than normal oestrogen and higher than normal testosterone. Thus, the 
effect observed should be akin to that observed in men. Although this 
strategy has proved successful in numerous patients,41 the effects of 
spironolactone are intricately linked to physiological parameters, e.g., 
local concentrations of sex steroids in specific tissues, that its effect is 
unpredictable and inconsistent. For this reason, it is advised that women 
with symptoms related to virilisation rather be treated with more potent 
antiandrogenic compounds.

Anovulatory menstrual bleeding

Anovulatory menstrual bleeding describes any form of 

menstrual bleeding occurring in the absence of a normal 

ovulatory response and that is unrelated to uterine pathology.45 

Etiologies may include, among other, polycystic ovary syndrome 

(PCOS), hyperprolactinemia, thyroid disorders, and premature 

ovarian failure.46 The menstrual bleeding occurring in patients 

with anovulation is in fact not related to the normal hormonal 
changes associated with follicular development, but rather 
results from endometrial proliferation in response to the low, but 
relatively constant estrogenic stimulation of the endometrium. 
As very little progesterone is secreted to counter such 
proliferation, the endometrial tissue breaks down unpredictably 
and uncontrollably, resulting in patients experiencing irregular 
menstrual periods.46 In this instance, such stimulation is brought 
about by extragonadally derived estrogen, e.g., from adipose or 
adrenal gland tissue. However, ovarian estrogen from partially 
developed follicles may also contribute to a stable, although 
lower, estrogen tone.

The present section will focus on polycystic ovary syndrome 
for two reasons. First, in most patients, PCOS is closely related 
to excess weight. Second, PCOS is the most common cause of 
anovulatory bleeding and infertility in women of reproductive 
age47 and it is therefore likely that clinicians treating overweight 
and obese female patients will observe and diagnose PCOS at 
some stage.

Briefly, PCOS is characterised by 2 or more of the following signs 
and symptoms48:

• Oligo- or anovulation;

• Clinical or biochemical signs of hyperandrogenism;

• Polycystic ovaries, in the absence of other unrelated causes.

Other symptoms that may be present, but for which an accurate 
diagnosis is not required48 are:

• Insulin resistance;

• Impaired glucose tolerance;

• Increased LH levels; and 

• Increased LH/FSH ratio.

Table 6

Drug / Formulation Dose Notes

Combination Oral Contraceptives 
Diane-35® / Minerva-35® / Ginette® / 
Marvelon® / Yasmin® / Femodene ED® / 
Nordette®

As for hirsutism (Table 5)

• Contraceptive therapy is indicated to improve menstrual 
irregularities and treat comorbid symptoms of virilism;

• Contraceptive therapy will not improve insulin sensitivity, 
nor address issues of infertility;

• Progestin components as for hirsutism (Table 5);
• Adverse effects as for hirsutism (Table 5)

Metformin 
Glucophage® / Sandoz-Metformin® / 
Bigsense® / Accord-Metformin® / Austell-
Metformin® / Diamin® / Gluconorm®/ 
Metforal® / Metformin Alkem® / 
Metphage® / Mylan-Metformin® / 
Romidab® / Diaphage® / Mengen® / 
Metored® / Diabetmin®

Initiate with 500–850 mg per day. Titrate 
upwards to 1000 mg twice per day after 
2–3 weeks.

• Especially advised in patients with established impaired 
glucose tolerance, impaired fasting glucose or diabetes 
mellitus type 2.

Clomifene 
Clomid® / Fertomid® / ClomiHexal®

• Initiate with 50 mg per day for 5 days 
on days 3–5 of the cycle (if present) 
or following induction of a menstrual 
period;

• If no response is observed, titrate 
upwards to 100 mg per day for 5 days.

Reserve use for specialist supervision. Ovarian 
hyper-stimulation may be triggered in which case urgent 
medical care must be provided.

Lifestyle Change and Weight Loss

• Calorie controlled diets are to be 
introduced as soon as possible.

• Moderate exercise is advised as 
adjunctive therapy.

Weight loss is unlikely to be effective in women of normal 
weight and may even exacerbate the condition. Reserve for 
patients with a BMI of > 22 kg/m2



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The term ‘polycystic’ describes observations of partially 

developed follicles, usually arranged in the form of a pearl string 

in the ovaries of patients. Never developing up to ovulatory 

potential, these follicles encyst and remain in this state ad 

infinitum. The factors listed above act in concert to yield the 

clinical syndrome. First, overweight and obese women present 

with higher androgen concentrations compared to lean 

individuals (Table 2). Further, they are often insulin resistant, 

presenting with hyperinsulinemia and impaired glucose 

tolerance. While androgens suppress follicular development, 

high levels of insulin increases the LH/FSH ratio.49 Consequently, 

higher levels of LH drive further androgen synthesis, while lower 

levels of FSH contribute to inadequate follicular development.

How best to approach PCOS from a therapeutic perspective 

is still debated.50 However, strategies are largely directed at 

curbing androgen excess, treating menstrual irregularities and 

secondary symptomologies, e.g., hirsutism, improving insulin 

sensitivity and losing weight. These are summarised in Table 6.50

Fact Box for Clinical Practice:  Some Notes on Why We Become 
Overweight and Obese and the Role of Calorie Restriction
Broadly speaking, obesity is caused by an excessive intake of calories, 
in relation to energy expenditure over a chronic period of time.7 In 
fact, only minor daily excesses in calorie intake can cause significant 
increases in adipose mass. For instance, a relative daily excess of 
only 5%, can increase body mass with 5  kg within one year only. Over  
30 years, a daily excess of only 8 Cal more than utilised, can add 10  kg 
of body weight.51 Interestingly, genetic predisposition accounts for 
only 40% of the changes in the body weight in the average individual. 
Indeed, the majority of patients suffer from obesity due to poor lifestyles 
characterised by high caloric diets and inactivity. However, children 
born from one (or both) obese parents, or children who become obese 
after the age of 6 years, have a 79% risk of becoming obese adults.52 
These findings led to investigations to uncover the role for genetic 
predisposition in certain susceptible populations. As such, we know 
today that in a small minority of patients, obesity may indeed have an 
exclusively genetic basis. Patients presenting with monogenetic obesity, 
i.e., obesity in which only a single gene mutation is sufficient to trigger 
an abnormal metabolic response, demonstrate functional mutations 
with respect to genes that are involved in the functioning of two major 
endocrine systems, i.e., leptin and corticosteroid signalling.7 However, 
these account for fewer than 1% of all obesity cases, in which case 
specialist intervention is paramount. Considering weight loss, patients 
are often unenthusiastic, misinformed, and unwilling to appreciate the 
clinical severity of their condition and in taking personal responsibility 
for their health. Inaccurate and often plain false reporting in the 
layman’s media generally results in the misconception that it is near 
impossible to shed weight with calorie controlled diets and changes 
in lifestyle. Although morbidly obese patients will almost never shed 
sufficient weight only by dieting – these individuals only benefit from 
bariatric surgery in the long run53 – the majority of overweight and obese 
patients can benefit adequately from calorie restriction. It is broadly 
advised that patients with a BMI > 25 kg/m2 reduce their energy intake 
by approximately 500 Cal per day. Such interference will reduce body 
weight on average by 0.45 kg/week and will ensure a reduction of 10% in 
the initial body weight, within 6 months. In the event where personalised 
diets cannot be applied, the following guidelines for reduction in 
calorie intake have been suggested by the WHO for persons of different 
weights54:

• 68–90 kg:  1000 Cal/day
• 90–114 kg  1200 Cal/day
• 114–136 kg  1500 Cal/day
• 136–160 kg  1800 Cal/day
• > 160 kg   2000 Cal/day

Conclusion

Overweight and obesity are not only two highly prevelant 
conditions in the South African society, but they also contribute 
to 6 of the 10 most common causes of death. Further, being 
overweight not only results in significant metabolic and 
endocrine disturbances, it also changes how patients respond to 
most pharmacotherapeutic interventions for clinical illness. This 
paper attemped to elucidate some of the most common physio-
pathological phenomena associated with being overweight 
and obese that may influence pharmacotherapy. We briefly 
focussed on the ways in which especially excessive visceral 
adipose tissue contributes to an altered physiological state and 
pharmacokinetic profile, while highlighting important clinical 
aspects of comorbid conditions that are frequently observed in 
this patient cohort.

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