THE EFFECT OF THE EMBALMING FLUID, USED BY THE 
DEPARTMENT OF BASIC MEDICAL SCIENCES (UFS), ON THE 
VIABILITY OF MYCOBACTERIUM TB IN HUMAN CADAVER LUNG 
TISSUE 
 
by 
JANINE CARLA CORREIA 
 
A dissertation submitted in fulfilment of the requirements for the degree 
M Med Sc Anatomy and Cell Morphology 
(Magister in Medical Science) 
 
In the Department of Basic Medical Sciences 
Faculty of Health Sciences 
University of the Free State 
Bloemfontein 
 
Supervisor: Mr. J.L. Steyl 
Co-supervisor: Dr. H.C. de Villiers 
June 2012 
ACKNOWLEDGEMENTS 
 
I wish to express my sincere gratitude and appreciation to the following 
people: 
 
Mr. J.L. Steyl (Supervisor) and Dr. H.C. de Villiers (Co-supervisor) for all the 
guidance, support, and time spent reviewing this dissertation. 
 
Special thanks to Dr. Fanie Weyers (Pathcare Bloemfontein) for the advice, 
information, and assistance with all the diagnostic tests and the protocol.  
 
The Department of Basic Medical Sciences (UFS) for financial support.   
 
The Faculty of Health Sciences (UFS) for the postgraduate bursary.   
 
Mr. R. Botes and Dr. D. Raubenheimer for all the help with the proofreading 
and editing.   
 
Last, but certainly not least, my beloved mother, Tilly, for all the support, 
motivation, and inspiration.  
DECLARATION 
 
I certify that the dissertation hereby submitted by me for the Magister in 
Medical Science at the University of the Free State is my independent effort 
and had not previously been submitted for a degree at another 
university/faculty.  I furthermore waive copyright of the dissertation in favour 
of the University of the Free State.  
 
_______________                   
J.C. Correia   
 
 
 
 
 
 
 
 
 
 
TABLE OF CONTENTS 
       
1. INTRODUCTION        1 
1.1 Aim and objectives        4 
1.2 Cadavers          5 
1.3 Embalming fluid         6 
1.4 Pulmonary tuberculosis                  12 
1.4.1 Mode of transmission                              13 
1.4.2 Pathogenicity                 14 
1.4.3 Clinical signs and symptoms of pulmonary tuberculosis           17 
1.4.4 Tuberculin reaction test                18 
1.4.5 Laboratory identification of Mycobacterium tuberculosis           19 
1.4.5.1 Direct microscopy and staining              19 
1.4.5.2 Lowenstein-Jensen method              21 
1.4.5.3 Mycobacterium growth indicator tube culture method          22 
1.4.5.4 Polymerase chain reaction method              24 
1.4.6 Treatment and prevention of Mycobacterium tuberculosis          25 
1.5 Gross anatomy of the lungs               26 
1.5.1 Neurovascular supply                 30 
1.5.2 Lymphatic drainage of the lungs               32 
1.5.3 Surface anatomy of the lungs                35 
15.4 The lungs and Mycobacterium tuberculosis             37 
 
2.  MATERIALS AND METHODS              38 
2.1 Study design                 39 
2.2 Study participants                 40 
2.3 Ethical aspects                 41 
2.4 Pilot study                  42 
2.5 Closed needle biopsy                43 
2.6 Embalming process                49 
2.7 Diagnostic laboratory methodologies              51 
2.7.1 Standard operating procedures for Ziehl-Neelsen stain           51 
2.7.2 Standard operating procedures for Mycobacterium growth  
 indicator tube culture                54 
2.7.3 Standard operating procedures for Tuberculosis Polymerase chain  
 reaction identification                55 
2.8 Statistical analysis of results                 58 
 
3. RESULTS                  59 
3.1 Pilot study                  59 
3.2 Main study                  61 
 
4. DISCUSSION                 69 
4.1 Pilot study                  69 
4.2 Main study                  71 
4.2.1 Resistance of Mycobacterium tuberculosis             74 
4.2.2 Risk of transmission of Mycobacterium tuberculosis           76 
 
5. CONCLUSIONS                 79 
5.1 Limitations                  79 
5.2 Value of study                 80 
5.3 Further recommendations               82 
 
6. SUMMARY                 83 
 
7. REFERENCES                 89 
 
APPENDIX A: Pre-printed request/information form (Pathcare)        100
    
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
LIST OF ABBREVIATIONS 
 
AFB    Acid-fast bacilli  
BCG    Bacilli calmette-gluerin  
DNA    Deoxyribonucleic acid 
CFU    Colony-forming unit 
LJ    Lowenstein-Jensen 
MDR-TB   Multi-drug resistant tuberculosis 
MGIT   Mycobacterium growth indicator tube 
MOTT   Mycobacterium other than tuberculosis 
MTB    Mycobacterium tuberculosis 
NaOH   Sodium Hydroxide 
PANTA   Polymyxin B, Amphotericin B, Nalidixic Acid,  
    Trimethoprim, and Azlocillin 
PCR    Polymerase chain reaction 
PPD    Purified Protein Derivative 
PTB    Pulmonary tuberculosis 
TB    Tuberculosis 
UFS    University of the Free State 
UVGI   Ultraviolet germicidal irradiation 
WHO    World Health Organization  
ZN    Ziehl-Neelsen 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
LIST OF TABLES 
 
  Page 
Table 1.1 Number of cadavers received from 2009 – 2011 at the 5 
department of Basic Medical Sciences (UFS) and the 
number of deceased due to Mycobacterium tuberculosis 
according to the death certificates. 
Table 1.2 Embalming fluid recipe. 9 
Table 1.3 List of bronchopulmonary segments of the left and right 30 
lung. 
Table 2.1 Reporting results for Ziehl-Neelsen staining according to 53 
the WHO guidelines. 
Table 3.1 Percentage of samples with a positive and negative TB 60 
result, with the first line screening technique in the pilot 
study (n=5). 
Table 3.2 Percentage of samples with a positive and negative growth 60 
in the pilot study (n=5). 
Table 3.3 Cause of death according to death certificate and the 66 
number of days the MTB is still viable in the cadavers. 
Table 3.4 Comparison between the number of right and left lungs 67 
and male and female cadavers tested. 
 
  
LIST OF FIGURES 
 
  Page 
Figure 1.1 Scanning electron micrograph of Mycobacterium 13 
tuberculosis bacilli. 
Figure 1.2 In the hilus is the Ghon complex, a small yellow 15 
granuloma in a hilar lymph node next to the bronchus. 
Figure 1.3 Main symptoms of pulmonary tuberculosis. 17 
Figure 1.4  Medial view of right and left lung. 28 
Figure 1.5 Embalmed and plastinated lungs. 29 
Figure 1.6 The diagram of the lymphatic drainage of the superior 34 
and inferior regions of lungs. 
Figure 1.7 Surface anatomy of the right and left lungs, parietal 36 
pleurae are indicated by the blue line. 
Figure 2.1 Pro-cut biopsy needle. 43 
Figure 2.2 Obtaining hilar samples through the 3rd intercostal space. 44 
Figure 2.3 Cross section of the thoracic cavity at the level of the 3rd 45 
costal cartilage (T5) illustrating the direction and depth of 
the needle. 
  
Figure 2.4 Obtaining tissue sample from apex of lung through the 46 
supraclavicular space, view from superior looking into 
the right thoracic inlet.  
Figure 2.5 Anterior view of a plastinated specimen of the thorax.  47 
The anterior thoracic wall has been removed and the 
arrow indicates the direction and depth of needle to 
obtain the apical sample. 
Figure 2.6 Pre-labelled container with saline as transport medium. 48 
Figure 2.7 Workshop technician embalming a cadaver through the 50 
radial artery. 
Figure 2.8 Body cabinets in the mortuary where the cadavers are 50 
kept for 6 months. 
Figure 3.1 Graph depicting the percentage of 1st samples with a 62 
positive and negative TB result, with the first line 
screening technique (n=20). 
Figure 3.2  Graph depicting the percentage of 2nd samples with a 63 
positive and negative TB result, with the first line 
screening technique (n=18). 
Figure 3.3 Graph depicting the percentage of 1st samples with a 64 
positive and negative TB result, with TB growth (n=20) 
Figure 3.4 Graph depicting the percentage of 2nd samples with a 64 
positive and negative TB result, with TB growth (n=18). 
 
1 
 
1. INTRODUCTION 
 
Embalming fluid contains substances such as formalin, ethanol, phenol, and 
other solvents to temporarily prevent decomposition.  These agents disinfect, 
preserve, and/or sanitise (Pretorius 1995).  An embalming fluid formula 
should have the following requirements: fixative, bactericide, fungicide, 
humectant, and colour enhancer (Pretorius 1995).  Formalin and ethanol are 
used as fixatives by denaturing the cellular proteins, meaning the proteins 
cannot act as a source of nutrients for the bacteria.  Phenol is used as a 
bactericide to destroy a broad spectrum of organisms and promotes good 
colour retention to muscle tissue (Pretorius and Brune 1992).   
 
The risk of contracting a disease such as tuberculosis (TB) among persons 
who are in close contact with recently deceased people, is high (Gerston, 
Blumberg, Tshabalala and Murray 2004) and the risk varies according to 
occupation.  Workers at anatomy departments and embalmers are some of 
those people who are at a greater risk of contracting tuberculosis carried by 
cadavers.  This increased risk may be due to the exposure to this organism 
during the embalming process, which involves the inhalation of infectious 
aerosol (Sterling, Pope, Bishai, Harrington, Gershon, and Chaisson 2000).   
2 
 
Embalming does not guarantee that the growth of TB bacteria is halted.  In 
1949, Meade and Steenken already reported the growth of Mycobacterium 
from embalmed cadavers although not much detail was given.  Sterling et al. 
also reported a case where an embalmer contracted TB after handling an 
infected cadaver (Sterling et al. 2000).  Another study by Gerston et al. (2004) 
attempted to culture TB from formalin-fixed lungs.  Of the 138 cases, 
Mycobacterium was grown from 12 cases (9%).  Gerston et al. (2004) also 
found that Mycobacterium tuberculosis (MTB) was isolated from formalin-
fixed tissue up to 45 days after fixation.   
 
Nevertheless, in medical circles it is a perception that once tissue is fixed in 
formalin, the risk for contracting TB is greatly reduced or eliminated (Gerston 
et al. 2004).  A subsequent study by Weed and Baggenstoss showed that MTB 
remains infectious for at least 24 – 48 hours after embalming (Weed and 
Baggenstoss 1951).  Demiryürek, Bayramoglu, and Ustaçelebi stated that 
formalin is an effective tuberculocidal (Demiryürek et al. 2002).   
 
MTB causes granuloma (a mass of inflamed granulation tissue) and the 
effective penetration of embalming agents into these sites raises questions.  
The granuloma that forms typically appears cheese-like (caseation) and this is 
3 
 
known as a tubercle (Thomas 1983).  MTB infection rarely occurs in the 
anterior segments of the lungs, but commonly in the apical segments of the 
upper and lower lobes as well as the hilus region of the lung (Brink and de 
Kock 1973).  MTB is an aerobic bacterium and thus multiplies better in the 
apex of the lung where oxygen concentration is higher. 
 
There also seem to be a lack of guidelines for the effective and safe handling 
of formalin-fixed autopsy tissue that has been infected by MTB.  Both the 
Centres for Disease Control and Prevention (CDC 1994) and the Occupational 
Safety and Health Administration (OSHA 1996) lack to mention these 
guidelines.  Based on this, the disinfection properties of fixatives for MTB 
infected tissue thus remain unclear.   
 
 
 
 
 
 
 
 
4 
 
1.1 AIM AND OBJECTIVES 
 
The aim is to investigate if MTB is still viable in human cadaver lung tissue 
and especially in granulomatous tissue after embalming has taken place.   
 
Thus, the objective of this research study is to test the efficacy of the 
embalming fluid used at the department of Basic Medical Sciences (University 
of the Free State) on eliminating Mycobacterium tuberculosis in human 
cadaver lung tissue.  
 
  
5 
 
1.2 CADAVERS 
 
The department of Basic Medical Sciences (UFS) receives approximately 80 – 
100 human cadavers per year for research and educational purposes (Table 
1.1).  The cadavers are obtained as human donations and unclaimed bodies.  If 
bodies are not claimed within 14 days after death, the Inspector of Anatomy is 
notified.  The department is according to The Human Tissue Act, Act 65 of 
1983, the only authorised institution at the UFS to receive human cadavers 
(Pretorius and Brune 1992) and is authorised by the Inspector of Anatomy to 
perform research on these cadavers.   
 
According to the number of MTB infected cadavers recorded during 2010, 
approximately 25% is expected to have TB as seen in Table 1.1.   
 
Table 1.1 Number of cadavers received from 2009 – 2011 at the department 
of Basic Medical Sciences (UFS) and the number of deceased due to 
Mycobacterium tuberculosis according to the death certificates. 
Year Total number of Number of cadavers % of cadavers with 
cadavers with TB (according to TB (according to 
received death certificate) death certificate) 
2009 90 22 24% 
2010 103 26 25% 
2011 81 11 14% 
 
6 
 
1.3 EMBALMING FLUID 
 
A simple definition for embalming is the disinfection, temporary preservation, 
and restoration by way of injection of embalming fluid into the radial artery of 
the cadaver (Pretorius 1995).  According to Creely (2004), embalming is also 
to restore a more life-like appearance for presentation.  According to Pretorius 
and Brune (1992), embalming fluid formula should have the following 
requirements: fixative; bactericide; fungicide; humectant and colour enhancer. 
 
A fixative is a stabilizing or a preservative agent.  Fixation methods fall in two 
classes: cross-linking agents and organic solvents.  The result of adding a 
fixative such as formalin to embalming fluid is to react with proteins to create 
“cross-links”.  These “cross-links” cause the firmness of embalmed tissue and 
inactivate the enzymes that are responsible for post-mortem autolytical 
processes.  Autolysis (self-digestion) is the process of self-destruction that 
starts soon after cell death creating an enzyme attack that causes protein 
breakdown and eventually liquefaction of the cells.  In the absence of 
embalming, putrefaction (stage of decomposition) will take place (Pretorius 
and Brune 1992).  Autolysis can be halted by disabling the enzymes by adding 
a fixative.  By changing the pH level in the body or by placing the body in 
7 
 
temperatures well below normal body temperature are also ways of stopping 
autolysis (Pretorius and Brune 1992).  The microorganism involved in the 
process of decomposition is not pathogenic (Morgan 2004) and is mostly 
normal flora found in the gastro-intestinal tract.  The putrefactive stage of 
decomposition is mainly driven by anaerobic bacteria within the gastro-
intestinal tract.  Organic solvents such as alcohol (e.g. ethanol) remove lipids 
and dehydrate the cells.  The dehydrated firm tissue is less attractive for 
bacterial consumption (Pretorius and Brune 1992). 
 
A bactericide is an agent or a substance capable of destroying bacteria or 
inhibiting the growth of bacteria.  These agents need to be effective against a 
broad spectrum of bacteria.  Bactericides can work in various ways, either by 
stopping cell division of the bacteria or by interfering with the formation of 
the cell walls or even by stopping the bacteria to multiply (Ajmani 1998).   
 
A fungicide is an agent or a chemical substance capable of killing fungi or 
inhibiting the growth of fungi.  Fungicide thus prevents the spread of fungi on 
cadaver tissue.  Most fungal infections on human cadavers are saprophytic and 
multiply in untreated or poorly embalmed cadavers (Ajmani 1998).  A fungal 
infection will appear as blue, green, or purple “fur” on the surface of the body.   
8 
 
A humectant (moistening/wetting agent) is a hygroscopic substance.  
Hygroscopic refers to the ability to absorb water from the air.  A humectant is 
added to prevent hardening and distorting and help restore the tissue 
dehydrated by the formalin to a more natural hydrated condition (Pretorius 
and Brune 1992). 
 
A colour enhancer gives the cadaver a more natural look.  Certain chemicals 
act on the blood pigment to restore the red colour after fixation.  Other 
chemicals give a better colour contrast between the different types of tissue 
(Pretorius and Brune 1992).   
 
The department of Basic Medical Sciences (UFS) uses a standardised 
embalming formula for the embalming of the cadavers.  Table 1.2 shows the 
recipe for the embalming fluid for 1 cadaver. 
 
 
 
 
 
 
 
 
9 
 
Table 1.2 Embalming fluid recipe (Pretorius and Brune 1992). 
20 L 96% Ethanol 
1 L 40% Formalin 
1.5 L Pine Oil 
7.5 L Water 
1.5 L 80% Liquid Phenol 
 
The formal name for formalin is formaldehyde (HCHO), the British Chemist; 
August Wilheld Von Hofmann (Dixit 2008) discovered it.  According to 
Pretorius and Brune (1992), formalin is the best fixative but it has the 
following disadvantages: slow in penetrating tissue; the fumes may irritate 
mucous membranes of air passages; limits suppleness of tissue and does not 
promote good colour retention (Pretorius and Brune 1992).  It is a colourless, 
highly flammable gas at room temperature with a distinct odour.  
Commercially it is available as formalin, which is formaldehyde gas in water.  
A study conducted by Coleman and Kogan (1998) found that 0.5 L 37 – 40% 
formaldehyde per body is adequate for embalming purposes.  Formalin 
usually also contains methanol, which inhibits polymerisation.  Formalin acts 
as a high-level germicide (Demiryürek et al. 2002).    
 
10 
 
The fumes of the formaldehyde are intensely irritating to mucous membranes 
of the eye, nose, and upper respiratory tract.  There are also indications that 
formaldehyde has a carcinogenic effect (Pretorius and Brune 1992).  
According to Pretorius and Brune (1992), asthma and allergies are more 
prevalent in humans if they are exposed continuously to fumes of 
formaldehyde.   
 
Ethanol (Table 1.2) acts as a fixative, bactericide, and fungicide but is highly 
flammable and may dehydrate tissue (Pretorius and Brune 1992).  Ethanol is 
however ineffective against prions, endospores and nonenveloped viruses 
(Demiryürek et al. 2002).  Pine oil (Table 1.2) acts as a humectant and a 
colour enhancer.  It also improves the smell of the embalming fluid by giving 
it a “pine” odour (Pretorius and Brune 1992). 
 
Phenol (carbolic acid) acts as a bactericide and fungicide but has a few 
disadvantages: it is expensive, toxic, has an unpleasant smell, and if splashed 
on skin it can cause serious burns (Dixit 2008).  At the right concentrations, 
phenol is used as a colour enhancer of muscle tissue giving muscle tissue a 
suitable brown colour (Pretorius and Brune 1992). 
 
11 
 
According to Dixit (2008), the toxic effects of the fumes of formaldehyde 
during embalming may be reduced by installing good ventilation systems in 
the embalming rooms.  Embalmers should be educated about the potential 
health hazard of the fumes, wear protective clothing and masks during the 
embalming process, and avoid spillage of the embalming fluid. 
 
Six months after embalming, the cadavers are ready for dissection purposes 
(Pretorius and Brune 1992).  In the dissection hall, the cadavers are wrapped 
in cloths and plastic to prevent the cadavers from drying out and discolouring.  
The cloths are dipped in a wetting fluid consisting of a mixture of 250 ml pine 
oil and 250 ml 80% liquid phenol.   
12 
 
1.4 PULMONARY TUBERCULOSIS 
 
Pulmonary TB (PTB) is a contagious, bacterial lung disease but it can also 
affect the central nervous system, the lymphatic system, the circulatory 
system, the genitourinary system, bones, joints, and even the skin (Bloom and 
Murray 1992).  PTB is caused by Mycobacterium tuberculosis, a rod-shaped 
bacterium (Figure 1.1) with a lipid-rich cell wall.  Mycobacterium infections 
are intracellular and cause granulomatous lesions (Strohl, Rouse, and Fisher 
2001).  MTB has the following characteristics:  non-motile; non-spore 
forming; acid-fast and aerobic.   
 
MTB was first isolated by Robert Koch in 1882 (Bloom and Murray 1992) 
and today it is the leading cause of infectious disease according to the World 
Health organisation (WHO 2011) second to HIV.  An estimated 1.3 million 
people died of TB in 2008.  In 1993, the WHO declared TB a global health 
emergency (WHO 1993).  Eight to ten million new cases of TB are reported 
each year, according to the WHO (2011).  In South Africa TB has been the 
leading cause of death since 1997 accounting for about 13% of the deaths in 
the country according to Statistics South Africa (2008).  The emergence of 
multi-drug resistant TB (MDR-TB) in recent years has added to the control of 
13 
 
TB (Leung 1999).  MDR-TB is strains that are resistant to one or more of the 
primary drugs (Strohl et al. 2001).   
 
 
Figure 1.1 Scanning electron micrograph of Mycobacterium tuberculosis 
bacilli (CDC 2006). 
 
1.4.1 Mode of transmission   
 
Transmission of the bacillus is human-to-human.  TB is spread by the 
inspiration of aerosol infected with large numbers of the organism (Leung 
1999).  MTB can remain viable in the environment due to the resistance to 
desiccation (Strohl et al. 2001).  Infected aerosol droplets are produced when 
persons with pulmonary TB cough, sneeze, speak, or sing.  A single cough can 
14 
 
produce about 3000 droplet nuclei that contain the tubercle bacilli (CDC 
1994).   
 
1.4.2 Pathogenicity 
 
After the tubercle bacilli have been inhaled, MTB multiplies slowly in the 
terminal alveoli of the lungs and in the lymph nodes of the corresponding 
drainage areas, this is known as the primary infection (Strohl et al. 2001).  The 
Ghon complex is a lesion that consists of calcified focus of infection and an 
associated lymph node as seen in Figure 1.2.  The Ghon complex is the 
characteristic appearance associated with primary infection.  The bacilli are 
ingested by alveolar macrophages but also by alveolar epithelial type II 
pneumocytes (Smith 2003).  If the alveolar macrophage cannot destroy or 
inhibit the MTB, the bacilli multiply within its intracellular environment, 
causing the host macrophage to burst (Leung 1999).  Within 2 – 4 weeks, 
many of the macrophages die and release the bacilli.  When MTB multiplies 
within the alveolar macrophages, this causes more macrophages to migrate to 
the area, causing an early tubercle (Strohl et al. 2001).  The released bacilli 
form a caseous centre in the middle of the tubercle.   
 
15 
 
Subpleural granuloma 
Ghon complex 
 
Figure 1.2 In the hilus is the Ghon complex, a small yellow granuloma in a 
hilar lymph node next to the bronchus  (Klatt n.d.). 
 
A dormant phase may occur after this stage.  In the majority (90 - 95% in HIV 
negative patients) of the cases, the pulmonary lesions will gradually heal 
(Leung 1999).  The lesion may stop and become fibrotic and calcify, if not, a 
mature tubercle is formed and the caseous centre enlarges and forms a cavity 
in which the bacilli multiply.  The centre can burst and spread to other body 
systems via lymph to the hilar or mediastinal lymph nodes and through the 
16 
 
bloodstream to more distant sites in the body (Leung 1999).  Other known risk 
factors for the development of active TB include conditions that are associated 
with defects in T-lymphocyte and/or macrophage function, such as 
malnutrition, drug and alcohol abuse, coexistent medical conditions and 
corticosteroid or other immunosuppressive therapy.  
 
MTB has the ability to grow in immunologically activated macrophages and 
remain viable by inhibiting the fusion of phagocytic vesicles to lysosomes.  
MTB produces no endotoxins or exotoxins.  MTB stimulates a humoral and 
cell-mediated immune response (Strohl et al. 2001).  Tubercle bacilli are 
immunogenic meaning they enhance immunonologic responsiveness non-
specifically.   
 
Miliary (disseminated) TB is a form of tuberculosis that spreads through the 
entire body through blood and lymph vessels (Strohl et al. 2001).  This can 
take place during primary and active infection.  Common sites for this 
extrapulmonary infection are the meninges, lymph node, bones, joints, and the 
genitourinary tract.  Miliary TB occurs in about 15% of TB patients (Bloom 
and Murray 1992). 
 
17 
 
1.4.3 Clinical signs and symptoms of pulmonary tuberculosis 
 
Commonly, symptoms of infection of pulmonary tuberculosis include chest 
pain, coughing up blood, fever, anorexia, fatigue, night sweats, and weight 
loss that may persist for weeks to months (Leung 1999).  These symptoms are 
illustrated in Figure 1.3.  Extrapulmonary symptoms depend on the site of 
infection.   
 
 
Figure 1.3 Main symptoms of pulmonary tuberculosis (Häggström 2012). 
18 
 
1.4.4 Tuberculin reaction test 
 
This is also known as the Mantoux test or Purified Protein Derivative (PPD) 
test.  The tuberculin skin test is an expression of delayed-type hypersensitivity 
to protein antigens of the bacterium.  Tuberculin is a glycerol extract of the 
tubercle bacilli (Strohl et al. 2001). 
 
The Mantoux test entails the following according to Strohl et al. (2001); a 
standard dose of tuberculin units is injected intradermally in the forearm and is 
read 48 – 72 hours later.  The reaction is read by measuring the diameter of 
palpable raised hardened area across the forearm in millimetres.  If there is no 
induration, the result should be recorded as "0 mm".  An induration of  5 mm 
or greater than 5 mm is interpreted as positive if the person was in contact 
with persons infected with TB; persons with abnormal chest X-rays; HIV 
infected and other immunosuppressed persons.  An induration of 10mm or 
more is interpreted as positive in the following populations: Recent arrivals 
(less than 5 years) from high-prevalence countries; prisoners, residents of 
nursing homes, and other institutions; health care workers; injection drug 
users; mycobacterial laboratory personnel; persons with clinical conditions 
that place them at high risk; children less than 4 years of age, or children and 
19 
 
adolescents exposed to adults in high-risk categories.  An induration of 15 mm 
or more is positive in persons with no known risk factors for TB.  The Tine 
test is not quantitative and is useful for population screening (Strohl et al. 
2001). 
 
1.4.5 Laboratory identification of Mycobacterium tuberculosis 
 
1.4.5.1 Direct microscopy and staining 
 
This is usually done as a first line screening because it is fast and allows for 
rapid illumination of infective patients (Mackie, Duguid, Marmion, 
McCartney and Swain 1978).  The sensitivity is directly proportional to the 
number of acid-fast bacilli present.  Direct microscopy can be performed on 
tissue fluid obtained through aspiration of granulomatous tissue as a method 
of rapid diagnosis.  Sensitivity for the detection of acid-fast bacilli is 
significantly lower than with culture techniques.  10 000 organisms per ml 
sample is needed to obtain a positive result and the sensitivity is about 60 - 
70% (Blumberg 1995).  Variations of this method are the Ziehl-Neelsen (ZN) 
stain and the fluorescent microscopy method.   
 
20 
 
In the ZN technique, also known as the acid-fast bacillus (AFB) stain, the 
MTB is stained with carbol fuchsin and then washed with alcohol or acid 
(Strohl et al. 2001).  MTB, however, retain the carbol fuchsin stain, appear 
pink, and slightly curved (Strohl et al. 2001).  Mycobacterium species contain 
large amounts of lipid substances in their cell walls, which resist staining by 
ordinary methods unless the dyes are combined with phenol (Strohl et al. 
2001).  When these organisms are stained with a basic dye, e.g. carbol fuchsin, 
with phenol added, and heat is applied, the stain can penetrate the cell wall 
and reach the cell cytoplasm.  Once the cytoplasm is stained, it resists 
decolourisation with acid-alcohol, which cannot dissolve and penetrate 
beneath the cell wall.  Under these conditions of staining, the bacilli are said to 
be acid-fast (Strohl et al. 2001).  Other bacteria whose cell walls do not 
contain high concentrations of lipid are readily decolourised and are non-acid-
fast.  A counterstain (e.g. methylene blue or malachite green) is used to show 
structures and cells and to form a contrast with the red-stained bacilli. 
 
Fluorochrome stain is used in the fluorescent microscopy method that allows 
for easier identification of fluorescent bacilli (Strohl et al. 2001).  The 
identification of Mycobacterium with auramine dye is possible due to the 
affinity of the mycolic acid in the cell walls for the fluorochromes.  The dye 
21 
 
will bind to the Mycobacterium, which appears as bright yellow, luminous 
rods against a dark background.  Slides, which are stained with auramine, may 
be restained with ZN stain directly.  This helps confirming and differentiating 
the morphology of the positive or query slides.  The fluorochrome stains are 
recommended for specimen examination because of the increased sensitivity 
and speed (Mackie et al. 1978). 
 
1.4.5.2 Lowenstein-Jensen method 
 
This method is the traditional method; it consists of an egg-based medium, 
and takes about 2 - 6 weeks to culture (Strohl et al. 2001).  Only 100 – 1000 
bacilli per ml of sample need to be present to detect MTB using the 
Lowenstein-Jensen (LJ) method (Blumberg 1995).  Positive results indicate 
that the MTB is viable, but further growth and identification is needed for a 
definitive diagnosis (Blumberg 1995).  Middlebrook and Cohn (1958) 
described an agar-based medium for more rapid detection, but it still requires 
3 – 4 weeks to culture. 
 
 
 
22 
 
1.4.5.3 Mycobacterium growth indicator tube culture method 
 
Mycobacterium growth indicator tube (MGIT) is an automated method to 
detect the production of an indication substance released from specific 
reactions when active growth of acid-fast bacilli takes places.  The purpose 
thus is to detect the viability of the tubercle bacilli.  This method is the most 
widely used method of detecting MTB infection (Leung 1999) and will be the 
mainstay detection method for MTB in this study.  Although culture according 
to this method extends over 6 weeks before it can be regarded as negative, the 
greater majority (probably more than 90%) of positive results are obtained 
within 2 weeks (Leung 1999).  This method has a shorter time of detection 
than that of the LJ method (Blumberg 1995).   
 
The BACTEC MGIT 960 instrument is an in vitro diagnostic instrument 
designed and optimised for the rapid detection of Mycobacterium in clinical 
samples other than blood.  Specimens are collected, processed, and inoculated 
into Mycobacterium growth indicator tubes.  These tubes contain a liquid 
broth medium consisting of modified Middlebrook broth base and when 
supplemented with MGIT Growth Supplement and an antimicrobial mixture 
23 
 
(PANTA), it provides optimum medium for growth (Siddiqi, Libonati, Carter, 
Hooper, Baker, Hwangbo and Warfel 1988).   
 
The decontamination recommendation is based on a procedure using sodium 
hydroxide (NaOH) with N-acetyl L-cysteine (Siddiqi et al. 1988).  NaOH is 
bactericidal for contaminating bacteria but is to a much lesser extent harmful 
to Mycobacterium.  N-acetyl L-cysteine has no decontamination properties.  
NaOH and N-acetyl L-cysteine helps in liquefying the specimen.   
 
A fluorescent compound is embedded in the silicone on the bottom of the 
tubes and is sensitive to the presence of oxygen dissolved in the broth.  
Initially the large amount of dissolved oxygen quenches emissions from the 
compound.  Later, actively respiring microorganisms consume the oxygen and 
allow the fluorescence to be detected.  The tubes entered into the system are 
continuously incubated at 37°C and monitored for increasing fluorescence 
(Siddiqi et al. 1988).  Analysis of the fluorescence is used to determine if the 
tube contains viable organisms.  The intensity of the fluorochrome is directly 
proportional to the extent of oxygen depletion.  In case of MTB, at the time of 
positivity, there is approximately 105 – 106 colony forming units (CFU) per ml 
24 
 
of medium. A tube is declared negative if it remains negative for 6 weeks (42 
days).   
 
1.4.5.4 Polymerase chain reaction method  
 
Polymerase chain reaction (PCR) method is for testing the presence of genetic 
material of MTB.  This method is extremely useful but lack sensitivity in 
some specimens with very low bacterial counts and is not able to determine 
whether the bacilli are viable or not.  Consequently, false positive results can 
be obtained (Blumberg 1995).  The method forms the basis for differentiating 
MTB from other Mycobacterium species (Mackie et al. 1978).  
 
 According to a study done by Salian, Rish, Eisenach, Cave and Bates (1998), 
this method can be used to detect MTB DNA in formalin-fixed tissue.  With 
this method deoxyribonucleic acid (DNA) is extracted from a sample using an 
automated DNA extraction system.  A small portion of a predetermined target 
region of MTB DNA is amplified to differentiate between MTB complex and 
Mycobacterium other than TB (MOTT). 
 
 
25 
 
1.4.6 Treatment and prevention of Mycobacterium tuberculosis 
 
Some strains are resistant to drug therapy, but several chemotherapeutic 
agents are effective against MTB (Blumberg 1995).  Isoniazid, rifampicin, 
pyrazinamide, ethambutol, and streptomycin are first-line anti-tuberculosis 
drugs (Strohl et al. 2001) and needs to be taken for 2 months.  The reason for 
this extensive course is that the bacilli are located intracellular, the caseation 
blocks the penetration of the agents, and the bacilli grow slow and can become 
metabolic inactive (Strohl et al. 2001).   
 
Bacilli calmette-gluerin vaccine (BCG) is available and mostly given to 
tuberculin-negative individuals with a high risk of infection (Strohl et al. 
2001).  Isoniazid is used prophylactically for individuals who are tuberculin 
positive but asymptomatic. 
 
 
 
 
 
 
26 
 
1.5 GROSS ANATOMY OF THE LUNGS 
 
The lungs are found in the thorax within the pulmonary cavities.  The 
pulmonary cavities are situated laterally to the mediastinum and are lined with 
parietal pleura, whereas the lungs are covered by visceral pleura.  Each 
pulmonary cavity (left and right) is lined by the parietal pleura as well as the 
superior surface of the diaphragm and the lateral surfaces of the mediastinum 
(Moore, Dalley, and Agur 2009).  The potential space between the parietal and 
the visceral layers is the pleural space containing serous pleural fluid.  At the 
hilus of the lung (Figure 1.4), on the medial area on the lung where the 
bronchus and pulmonary vessels enter and leave the lung, the visceral pleura 
is continuous with the parietal pleura.  Cadaveric lungs are shrunken, hard, 
and discoloured (Moore et al. 2009). 
 
The parietal pleura consists of the costal, mediastinal, diaphragmatic, and the 
cervical parts.  The costal pleura lines the internal surface of the thoracic wall.  
The mediastinal pleura covers the lateral parts of the mediastinum (Moore et 
al. 2009).  The diaphragmatic pleura covers the thoracic part of the 
diaphragm.  The cervical pleura (pleural cupola) covers the apices of the lungs 
and is the superior continuation if the costal and mediastinal part of the 
27 
 
parietal pleura (Leonard 1995).  The cervical pleura is strengthened by an 
extension of the endothoracic fascia that attaches on the internal border of the 
first rib and transverse process of C7; the suprapleural membrane or Sibson’s 
fascia (Moore et al. 2009). 
 
The lungs are the organs of respiration, roughly cone-shaped and each has an 
apex a base (Figure 1.4), lobes, three surfaces (costal, mediastinal and 
diaphragmatic) and three borders (anterior, inferior, and posterior).  The 
anterior, posterior, and lateral surfaces are in contact with the ribs and known 
as the costal surface (Figure 1.4).  The apex is covered by cervical pleura and 
found above the level of the first rib in the root of the neck.  The base lies in 
relation to the diaphragm (Moore et al. 2009).  The anterior border (Figure 
1.4) of the right lung is straight but the anterior border of the left lung has an 
angular indentation known as the cardiac notch (Drake, Mitchell, and Vogl 
2005).  The lingula is formed in the superior lobe by this cardiac notch, 
presented as a tongue-like projection inferior to the notch (Moore et al. 2009).  
 
 
 
28 
 
 
Figure 1.4 Medial view of right and left lung (Drake et al. 2005). 
 
The right lung consists of three lobes divided by the oblique and horizontal 
fissure (Figure 1.5) whereas the left lung consist of two lobes divided by the 
oblique fissure (Moore et al. 2009).  The three lobes of the right lung include 
the superior, middle, and inferior lobe.  The left lung is divided into a superior 
and inferior lobe (Moore et al. 2009).   
29 
 
Apex 
Left superior  
Right lobe 
superior lobe 
 Horizontal 
 fissure 
Oblique fissure 
Right 
middle lobe Left inferior  
lobe 
 
Figure 1.5 Embalmed and plastinated lungs (Personal photograph by author: 
02 June 2011). 
 
Bronchopulmonary segments are a pyramidal shaped segments of the lung 
covered by visceral pleura, separated by septa from adjacent segments, 
supplied by a segmental branch of the pulmonary artery and is named 
according to the segmental (tertiary) bronchus that supplies it.  The trachea 
bifurcates at the level of 4th or 5th thoracic vertebrae into left and right main 
bronchi.  The main bronchi further divide into lobar bronchi and then into 
segmental bronchi (Moore et al. 2009). Each segmental bronchus supplies a 
specific bronchopulmonary segment. The right lung has 10 bronchopulmonary 
30 
 
segments while the left lung has 8 to 10 bronchopulmonary segments as seen 
in Table 1.3. 
 
Table 1.3 List of bronchopulmonary segments of the left and right lung 
(Moore et al. 2009). 
Right lung Left lung 
Superior lobe:   Superior lobe: 
• Apical • Apical Apicoposterior 
• Posterior • Posterior 
• Anterior  • Anterior 
• Superior lingular 
Middle lobe:   • Inferior lingular 
• Lateral 
• Medial 
Inferior lobe: Inferior lobe: 
• Apical basal • Apical basal 
• Medial basal • Medial basal Anteromedial 
• Anterior basal • Anterior basal 
• Lateral basal • Lateral basal 
• Posterior basal • Posterior basal 
 
1.5.1  Neurovascular supply  
 
The parietal pleura is supplied by the intercostal nerves and vessels except the 
inner portion of the diaphragmatic and mediastinal pleura which is supplied by 
the phrenic nerve and the pericardiophrenic vessels (Moore et al. 2009).   
 
31 
 
The pulmonary artery conveys deoxygenated blood to the lungs from the right 
ventricle of the heart (Drake et al. 2005).   Each pulmonary artery gives rise to 
lobar and segmental arteries and end in pulmonary capillaries around the 
alveoli. The pulmonary veins commence in the pulmonary capillaries and 
carry the oxygenated blood to the left atrium of the heart.  
 
The bronchial arteries (which supply the lung tissue) are branches of the 
thoracic aorta (left bronchial artery) or from the superior posterior intercostal 
artery (right bronchial artery).  The bronchial veins are formed at the root of 
the lung and drain into the azygos or hemiazygos vein (Drake et al. 2005). 
 
The lungs are supplied by the pulmonary nervous plexus, which is found 
anterior and posterior to the root of the lung (Drake et al. 2005).  The 
parasympathetic fibers originate from the vagus nerve (cranial nerve X): 
motor to the smooth muscle of the bronchial tree (bronchoconstrictor), 
inhibitory to the pulmonary vessels (vasodilator) and secretory to the glands of 
the bronchial tree (secretomotor).  The sympathetic fibers (from from T1 - T4 
via the sympathetic trunk) are bronchodilators, vasoconstrictors and inhibit 
glandular secretion (Drake et al. 2005). 
 
32 
 
1.5.2 Lymphatic drainage of the lungs  
 
The lymphatic drainage of the lungs consists of the superficial lymphatic 
draining the visceral pleura (subpleural network) and the deep lymphatic 
accompanying the bronchi and the pulmonary veins (peribronchial network).  
These two networks communicate at the pulmonary hilum and convey lymph 
mainly to the tracheobronchial lymph nodes.  The tracheobronchial lymph 
nodes are also known as the carinal nodes because the nodes are associated 
with the carina of the trachea found at the bifurcation of the trachea (Moore et 
al. 2009). 
 
The subpleural network drains (Singh 2009) the visceral pleura and the 
superficial lung.  The superficial lymphatic vessels course around the borders, 
surfaces and fissures of the lungs and convey lymph mainly to the 
bronchopulmonary lymph nodes and then to the tracheobronchial lymph 
nodes.   
 
The peribronchial network consist of intrapulmonary and bronchopulmonary 
nodes.  The intrapulmonary nodes are found in the lung tissue at the divisions 
of the segmental bronchi and lie in the bifurcation of the smaller branches of 
33 
 
the pulmonary artery.  The bronchopulmonary lymph nodes are further 
divided into two groups, the interlobar nodes found at the division of the lobar 
bronchi, and the hilar nodes found at the lower portions of the main bronchi. 
 
Lymph flows from the tracheobronchial lymph nodes to the paratracheal 
(Figure 1.6) lymph nodes (situated in the superior mediastinum) and to the 
bronchomediastinal trunks.  There are three groups of tracheobronchial nodes: 
superior, inferior and anterior.  The superior tracheobronchial nodes (Figure 
1.6) are found in the angle between the trachea and the left and right bronchi.  
The inferior tracheobronchial nodes (Figure 1.6) lie in the angle of the 
bifurcation of the trachea (Singh 2009) and the anterior nodes are anterior to 
the distal end of the trachea. 
 
The main lymphatic flow from the superior lobe of the left lung, and the 
superior  and middle lobes of the right lung (the superior region) is to 
bronchopulmonary, superior tracheobronchial and paratracheal lymph nodes; 
the inferior lobes of both lungs (the inferior region) drain to 
bronchopulmonary, inferior tracheobronchial and pulmonary ligament lymph 
nodes as seen in Figure 1.6.  Pulmonary ligament nodes lie within the 
pulmonary ligament (Topol and Masłoń 2009). 
34 
 
 
Figure 1.6 The diagram of the lymphatic drainage of the superior and 
inferior regions of lungs.  1—bronchopulmonary lymph nodes, 2—superior 
tracheobronchial lymph nodes, 3—inferior tracheobronchial lymph nodes, 4—
pulmonary ligament lymph nodes, 5—paratracheal lymph nodes (Topol and 
Masłoń 2009). 
 
The left and right bronchomediastinal trunks are found in the superior 
mediastinum.  Efferent vessels of the tracheobronchial, parasternal and 
brachiocephalic nodes unite to form the trunks (Drake et al. 2005).  The right 
bronchomediastinal trunk may drain into the right lymphatic duct and the left 
trunk may drain directly into the thoracic duct.  The trunk may also drain into 
the deep veins at the root of the neck.  
35 
 
1.5.3 Surface anatomy of the lungs  
 
The lines of reflection of the parietal pleura mark the extent of the pleural 
cavities and consist of the sternal, costal, and diaphragmatic parts.  Posterior 
to the superior part of the sternum the sternal lines of pleural reflection 
approach each other in the midline.  On the right side, the line descends in the 
midline to the xiphoid process (6th costal cartilage) where it turns laterally.  On 
the left side, at the level of the 4th costal cartilage, the line moves laterally to 
the sternum (6th costal cartilage) to make space for the heart (cardiac notch) as 
seen in Figure 1.7.  The costal lines of pleural reflection are continuations of 
the sternal lines from the 6th costal cartilage.  The costal line of pleural 
reflection crosses the 8th rib in the midclavicular line, the 10th rib in the 
midaxillary line and the 12th rib posteriorly (Moore et al. 2009). 
 
Peripheral areas where the diaphragmatic and the costal pleura come in 
contact are known as costodiaphragmatic recesses (Drake et al. 2005) and the 
areas where the costal and the mediastinal pleura come in contact are known 
as costomediastinal recesses (Figure 1.7). 
 
36 
 
The cervical pleura and apices of the lungs are found 2 – 4 cm superior to the 
medial third of the clavicle in the supraclavicular fossa, but do not extend 
above the neck of the 1st rib (Drake et al. 2005).  The hilum of the lungs is 
found at the level of the 3rd and 4th costal cartilage (vertebral level T5 – T7).   
 
 
Figure 1.7 Surface anatomy of the right and left lungs, parietal pleurae are 
indicated by the blue line (Drake et al. 2005). 
 
The oblique fissure begins at the level of the spinous process of T2 vertebra 
posteriorly and runs anteriorly to the level of the 6th costal cartilage.  The right 
horizontal fissure begins at the oblique fissure at the level of the 4th rib and 
costal cartilage (Moore et al. 2009).  The lower limit of the lungs are found 2 
37 
 
costal spaces above the line of pleural reflection as illustrated in Figure 1.7,  
6th rib in the midclavicular line, the 8th rib in the midaxillary line and the 10th 
rib posteriorly. 
 
1.5.4 The lungs and Mycobacterium tuberculosis 
 
MTB occurs in the anterior segments of the lungs, but commonly in the apical 
segments of the upper (superior) and lower (inferior) lobes as well as the hilus 
region of the lung (Brink and de Kock 1973).  MTB is a strictly aerobic 
bacterium and therefore multiplies better in pulmonary tissue, in particular at 
the apex, where oxygen concentration is higher. 
 
 
  
38 
 
 2. MATERIALS AND METHODS 
 
Closed needle biopsies were performed on 20 cadavers to obtain lung tissue 
from the apical and hilar areas. With the use of a pro-cut biopsy needle a 
sample of lung tissue was obtained by inserting the needle through the 3rd 
intercostal (hilar sample) and the costoclavicular space (apical sample). The 
first sample was taken before embalming. The second sample 3 weeks after 
embalming. Tissue was then retrieved and deposited into a sterile specimen 
container and transported to the pathology laboratory (Pathcare: Drs Dietrich, 
Voigt, Mia, and partners). MTB samples were then tested using the ZN stain, 
Mycobacterium growth indicator tube (MGIT) culture method and 
identification using PCR techniques.  The study took place over a 3-year 
period from 2009 to 2011. 
 
 
 
 
 
 
 
 
39 
 
2.1 STUDY DESIGN  
 
The study design was a before-after study. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
40 
 
2.2 STUDY PARTICIPANTS 
 
The human cadavers were accompanied by their death certificates indicating 
the cause of death.  Only cadavers whose certificates indicated that the cause 
of death was TB were selected to be included in the study.  Twenty cadavers 
were tested during this time for MTB.  Two of the cadavers were claimed 
before the second sample could be taken.  The first 5 cadavers were used to 
perform a pilot study and were included in the sample size of the main study. 
 
 
 
 
 
 
 
 
 
 
 
 
 
41 
 
2.3 ETHICAL ASPECTS 
 
The protocol was submitted to the Ethics committee (Faculty of Health 
Sciences) of the UFS for approval before commencement of the study 
(ECUFS nr. 05/08).  Consent was obtained from Dr. S. van Zyl, Head of the 
department of Basic Medical Sciences, in order to do research on the cadavers.   
 
The cadavers’ identities were not disclosed but only reference numbers were 
used to distinguish between them.  This ensured that they stayed entirely 
anonymous.  The results of the test will remain confidential and only a limited 
amount of people handled the samples as well as the results.  If any of the 
information or results from this study were to be published or used at a 
seminar or congress, no specific information regarding the cadavers or their 
identity will be revealed.  The information gathered during this study is the 
property of the department of Basic Medical Sciences. 
 
 
 
 
 
 
42 
 
2.4 PILOT STUDY 
 
A pilot study was done on 5 cadavers to determine the feasibility of the study.  
The 5 cadavers were included in the main study.  The method of the pilot 
study did not differ from the main study and the cadavers could thus be 
included in the main study.  The samples were taken, like in the main study, 
before embalming and 3 weeks after embalming but a third sample was taken 
6 months after embalming.  Only the first 2 cadavers of the pilot study were 
tested after 6 months.  Samples were taken just before the cadavers were 
released to the medical students for dissection purposes.   
 
Two different samples were taken from the hilus area of the lung at different 
depths and 2 different samples at different depths in the apical area.  It was 
recorded as Hilus 1 and 2 and Apex 1 and 2.  In the pilot study the needle was 
inserted until soft lung tissue could be felt in the apex and hilus, this was Hilus 
1 and Apex 1.  This depth was noted and another sample was taken 1 cm 
deeper and marked Hilus 2 and Apex 2.  The follow up samples (3 weeks after 
embalming) were taken from exactly the same locations as the initial samples 
to prevent inaccurate and not comparable results.  
  
43 
 
2.5 CLOSED NEEDLE BIOPSY  
 
Closed needle biopsies using a pro-cut biopsy needle (Figure 2.1) were 
performed on the cadavers to obtain lung tissue.  Two samples, hilar and 
apical samples, were taken from each cadaver during different stages of the 
routine embalming process:  
 
• The first sample was taken before embalming. 
• The second sample 3 weeks after embalming to determine whether the 
embalming was sufficient to eliminate the MTB. 
 
 
Figure 2.1 Pro-cut biopsy needle (Personal photograph by author: 07 June 
2011). 
44 
 
The procedure was performed using standard precautions.  Protective gloves 
and a mask, specifically for the prevention MDR-TB, were worn.  The 
cadaver was placed in a supine position.  A pro-cut biopsy needle was used to 
obtain a sample of lung tissue by inserting the needle through the third 
intercostal and the supraclavicular spaces respectively.  
 
The hilar sample was obtained by inserting the needle in the third intercostal 
space as seen in Figure 2.2.  The needle was inserted 1 cm lateral from the 
body of the sternum.   
 
 
Figure 2.2 Obtaining hilar samples from the 3rd intercostal space (Personal 
photograph by author: 07 June 2011). 
45 
 
The needle was inserted directly inferiorly, making a 90-degree angle with the 
table.  Figure 2.3 illustrates the direction of the needle.  The needle depth of 
each sample was recorded for each cadaver to ensure consistency.  The sample 
that was taken 3 weeks after embalming was inserted in the same puncture 
opening used to get the first sample and at exactly the same depth.  
 
The arrow indicates the direction 
 
and depth of the biopsy needle to 
obt ain sample from the hilar area. 
 
Figure 2.3 Cross section of the thoracic cavity at the level of the third costal 
cartilage (T5) illustrating the direction and depth of the needle (Author 
unknown 2006). 
 
46 
 
The apical sample was obtained by inserting a needle through the 
supraclavicular space as seen in Figure 2.4.  The entrance of the needle was 
superior to the medial third of the clavicle.  The needle was inserted posterior 
to the clavicle and the first rib as illustrated by the arrow in Figure 2.5 through 
the superior thoracic inlet.  Cadaver lungs are shrunken and deflated; the 
needle was inserted until the soft lung tissue could be felt of the apical 
segment of the superior lobe.  As with the hilar sample, the needle depth and 
direction was recorded.   
 
Sternal  
ends of 
clavicles 
 
Figure 2.4 Obtaining tissue sample from apex of lung through the 
supraclavicular space, view from superior looking into the right thoracic inlet 
(Personal photograph by author: 07 June 2011). 
47 
 
 The arrow indicates the direction and 
depth of the biopsy needle to obtain 
 
sample from the apical area. 
 
 
Figure 2.5 Anterior view of a plastinated specimen of the thorax.  The 
anterior thoracic wall has been removed and the arrow indicates the direction 
and depth of needle to obtain the apical sample (Personal photograph by 
author: 02 June 2011). 
 
The hilar and apical samples were taken either on the left side or on the right 
side.  When the cadavers arrived at the department, rigor mortis had already 
set in, and their necks were usually either to the left or right side.  The 
48 
 
supraclavicular space that was exposed was used to obtain the apical as well 
as the hilar sample. 
 
Tissue was then retrieved from the instrument and deposited into a sterile 
specimen container, with saline as transport medium.  The specimen 
containers were provided by the laboratory (Pathcare: Drs Dietrich, Voigt, 
Mia, and partners) with a specific volume of normal saline.  The container was 
then transported to the pathology laboratory within 4 hours of the specimen 
being obtained.  The container (Figure 2.6) was pre-labelled, and pre-printed 
request/information forms (see Appendix A) accompanied the specimen to the 
laboratory.  The cadaver’s identity was not disclosed, only a reference number 
was used for identification purposes.  Leakage from the specimen containers 
was prevented through the usage of parafilm sealant.  
 
 
Figure 2.6 Pre-labelled container with saline as transport medium (Personal 
photograph by author: 07 June 2011). 
49 
 
2.6 THE EMBALMING PROCESS 
  
A standardised embalming formula (see Table 1.2) is used at the department 
of Basic Medical Sciences at the UFS for the embalming of the cadavers as 
discussed previously (Pretorius and Brune 1992).  This formula is injected by 
the workshop technicians (embalmers) into the radial artery of the cadaver 
under pressure (1 – 1.5 kPa), until the cadaver is completely filled (Pretorius 
1995) as seen in Figure 2.7.  More or less 30 L of the embalming fluid is used 
for a 70kg cadaver.  The embalming fluid is injected into the radial artery, the 
blood flows into the veins, and the empty arteries are injected with Latex 4 - 6 
weeks after embalming. 
 
The cadaver is stored in a suitable polyethylene bag (Figure 2.8) after the 
embalming process.  The cadavers are stored in the mortuary of the 
department of Basic Medical Sciences each on a stainless steel body tray and 
stored in a body cabinet (Figure 2.8) at room temperature between 16 - 18oC.  
The cadavers are then stored for a minimum of 6 months until they are taken 
to the dissection hall for dissection purposes.   
 
50 
 
 
Figure 2.7 Workshop technician embalming a cadaver through the radial 
artery (Personal photograph by author: 21 May 2012). 
 
 
Figure 2.8 Body cabinets in the mortuary where the cadavers are kept for 6 
months (Personal photograph by author: 21 May 2012). 
51 
 
2.7 DIAGNOSTIC LABORATORY METHODOLGIES 
 
Taken into consideration the sensitivity, specificity, and technical 
shortcomings of the methods available (as discussed in 1.4.5), the following 
diagnostic laboratory methodologies were used by Pathcare Laboratory (Drs 
Dietrich, Voigt, Mia, and partners), to test the samples for MTB:  
• Ziehl-Neelsen staining and direct microscopy from aspirates (lungs in 
the case of PTB or from granulomatous lesions). 
• MGIT culture method. 
• Identification using PCR techniques, if tested positive with the MGIT 
culture method. 
 
2.7.1 Standard operating procedures for Ziehl-Neelsen stain 
 
A smear from the yellow purulent portion was made in a bio-safety cabinet 
and allowed to dry.  A smear should be 2 cm by 3 cm in size and neither to 
thin or too thick.  The slide was then passed through a flame 3 - 4 times or by 
placing the smear on a hotplate (heat fixation) and covered with concentrated 
carbol fuchsin.  The smear was allowed to stain for 5 min while heat was 
applied 3 times at 1-minute intervals.  The slide was washed with distilled 
52 
 
water and then covered with 3% acid alcohol.  The red colour of the smear 
will change to yellowish brown.  After about 1 min in the acid, the slide was 
washed with distilled water.  The film will appear faintly pink after 
decolourisation.  The slide was then washed with distilled water and 
counterstained with methylene blue or malachite green for 15 – 20 s.  The 
slide was then washed (distilled water), blotted and allowed to dry.   
 
The smears were examined with a 100x oil immersion objective and a 10x 
eyepiece (1000x total magnification for ZN smears).  A series of systematic 
sweeps over the length of the smear was made and examined.  Each field 
should be examined thoroughly.  A useful field is one in which cellular 
bronchial elements (leucocytes, mucous fibres and ciliated cells) are observed.  
The fields with no such cells should not be included in the reading.  At least 
100 fields were examined before reporting the smear negative.  After 
microscopic examination, the result was reported.   
 
The immersion lens should be cleaned between examinations of different 
clinical specimens to prevent contamination.  Smears are graded according to 
the WHO guidelines (Table 2.1). 
 
53 
 
Acid-fast bacilli stain bright red, while the cells and other organisms stain blue 
or green according to the counterstain used.  Tubercle bacilli look like fine red 
rods, slightly curved and more or less granular.  It can appear isolated, or in 
pairs or groups, and stand out clearly against the blue background.  Individual 
bacilli may show heavily stained areas, referred to as “beads” and areas of 
alternating stain may produce a banded appearance.  Mycobacterium other 
than tuberculosis (MOTT) appears pleomorphic (capable of assuming 
different shapes).  Ranging from long rods to coccoid forms, with more 
uniform distribution of staining properties. 
 
Table 2.1 Reporting results for Ziehl-Neelsen staining according to the WHO 
guidelines (2006). 
Number of acid fast bacillus Fields Report 
0 Per 100 fields Negative 
1 - 9 Per 100 fields Scanty (Low Positive) 
10 - 99 Per 100 fields Positive 
1 - 10 Per field Positive 
>10 Per field Positive 
 
54 
 
2.7.2 Standard operating procedure for Mycobacterium growth indicator 
tube culture method 
 
The tissue was homogenized in a tissue grinder with a small quantity of sterile 
saline or water (2 - 4 ml) in a bio-safety cabinet.  The specimen was then 
decontaminated by using 4% NaOH with N-acetyl L-cysteine, mixed by 
gentle inversion, placed in a vortex and allowed to stand for 15 min.  The 
specimen was spun at 2500 – 3000g for 20 min using a refrigerated centrifuge, 
and the supernatant poured off.  Phosphate buffer (5 ml) was added to the 
deposit, placed in vortex and spun for 20 min.  After resuspension of the 
sediment with the phosphate buffer, 0.5 ml of the concentrate was inoculated 
into the MGIT 960 tube.  Contamination was further reduced by adding 0.8 ml 
PANTA (Polymyxin B, Amphotericin B, Nalidixic Acid, Trimethoprim, and 
Azlocillin) prior to the inoculation.  Once inoculated, the MGIT tubes were 
placed in the instrument within 12 hours of inoculation.   Smears (ZN) were 
prepared from all processed specimens before inoculation into the medium (as 
described in 2.7.1).  The temperature of the instrument was maintained at 
37°C; the instrument read all the tubes every hour for a maximum period of 6 
weeks.  
 
55 
 
The MGIT medium was prepared per 1000 ml of purified water by adding 
modified 5.9 gm Middlebrook broth base and 1.25 g Casein pepton.  The 
MGIT growth supplement contains: Bovine albumin, dextrose, catalase, oleic 
acid and polyoxyethylene stearate (Siddiqi et al. 1988), and was added in a 
bio-safety cabinet to avoid contamination of the medium.   
 
When growth is detected, the instrument will illuminate the positive light and 
an alarm will sound.  The relevant positive tube indicated by a red light was 
removed and observed visually.  Mycobacterial growth will appear granular 
and not very turbid (clear).  In a liquid broth medium, MTB will appear 
granular.  Once a MGIT tube is positive by fluorescence or by visual 
observation, a smear can be prepared to help with the tentative differentiation 
of MTB from other mycobacteria.   
 
2.7.3 Standard operating procedure for Tuberculosis polymerase chain 
reaction identification  
 
Two different procedures for the identification from a liquid culture and a 
solid culture were used.  A screw top tube (2 ml) was labelled and a vertical 
line was made with a marker on the smooth side of the tube, to ensure that the 
56 
 
technologist knows where the pellet will settle.  The tubes were then placed in 
an Eppendorf centrifuge, the labelled marked facing to the front. 
 
For a liquid culture, the MGIT tube was placed in a vortex and the liquid taken 
out by using a pastette (Pasteur pipette).  The stem of the pipette was filled 
until just below the bulb and the liquid transferred to the already labelled 
screw top tube and centrifuged at 14k rpm for 5 min.  The supernatant was 
taken off with a pastette without disturbing the pellet.  Water (200 µl) was 
added, placed in a vortex to resuspend the pellet, and incubated at 100oC for 
30 min in a heating block.  The specimen was left to cool for 5 min and 
centrifuged at 14k rpm for 5 min.  100 µl was transferred into a Magna pure 
LC sample cartridge and covered with optical adhesive cover. DNA was 
extracted from the secondary sample using an automated DNA extraction 
system.  The region of interest was amplified using the sequence specific 
primers to differentiate between MTB complex and MOTT. 
 
For a solid culture, a sterile plastic disposable loop was used to pick up as 
many colonies as possible, and the loop was transferred to an already labelled 
screw top tube containing 200 µl of water.  The loop was swirled until clean 
and incubated at 100oC for 30 min in a heating block.  Left for 5 min to cool 
57 
 
and centrifuged at 14k rpm for 5 min.  100 µl was transferred into a Magna 
pure LC sample cartridge and cover with optical adhesive cover.  DNA was 
extracted from the secondary sample using an automated DNA extraction 
system.  Region of interest was amplified using the sequence specific primers 
to differentiate between MTB complex and MOTT. 
 
A copy of the sample form with the results was returned to the TB lab where a 
technologist will enter the results on the TB sheet and then into a computer.  
Results were either TB PCR positive, which is MTB complex positive or TB 
PCR negative, which is MOTT positive.  All positive specimens were kept for 
3 months in the fridge.  The standard operating procedures was supplied by 
Pathcare (Drs Dietrich, Voigt, Mia, and partners). 
 
 
 
 
 
 
 
 
58 
 
2.8 STATYSTICAL ANALYSIS OF RESULTS  
 
Microsoft Excel was used to perform the descriptive statistical analysis to 
decisive frequencies (number of positive and negative for the tests) and 
percentages (percentage of positive and negative for the tests). 
 
  
59 
 
3. RESULTS 
 
3.1 PILOT STUDY 
 
From the outcome of the pilot study it is clear that between the first (before 
embalming) and second (3 weeks after embalming) sample, using the first 
line screening technique or the ZN stain, the same percentage of samples 
returned a positive and negative result with the exception of Apex 2 as seen in 
Table 3.1.  In the first sample, 40% of the Apex 2 samples tested positive with 
the first line screening method, while the second sample 0% of the samples 
tested positive with the first line screening method (Table 3.1). 
 
The pilot study also demonstrates that with the first sampling round, for TB 
growth, 3 of the 4 sampling areas tested positive for TB (Table 3.2).  
However, with the second sampling round none of the 4 sample areas returned 
a positive result as seen in Table 3.2.  The first 2 cadavers tested in the study, 
were also tested 6 months after embalming to ensure that before the cadavers 
are released for dissection purposes, no viable MTB is present.  After 6 
months, the first line screening and the TB growth tested negative for both 
these samples. 
60 
 
Table 3.1 Percentage of samples with a positive and negative TB result, 
with the first line screening technique in the pilot study (n=5). 
 1st Sample 2nd Sample 
(Before embalming) (3 weeks after embalming) 
n=5 Negative Positive Negative Positive 
Apex 1 80 20 80 20 
Apex 2 60 40 100 0 
Hilus 1 80 20 80 20 
Hilus 2 100 0 100 0 
 
Table  3.2 Percentage of samples with a positive and negative growth in the 
pilot study (n=5). 
 1st Sample 2nd Sample 
(Before embalming) (3 weeks after embalming) 
n=5 Negative Positive Negative Positive 
Apex 1 40 60 100 0 
Apex 2 60 40 100 0 
Hilus 1 60 40 100 0 
Hilus 2 100 0 100 0 
 
  
61 
 
3.2 MAIN STUDY 
 
We conducted the main study and examined all the cadavers with the first line 
screening technique and for TB growth.  The results of the pilot study (Table 
3.2) indicated that one sample should be taken from in the apex (Apex 1) and 
one sample in the hilus (Hilus 1).  The Apex 1 and Hilus 1 samples of the 5 
cadavers of the pilot study were included as control or reference samples 
 
The results of the first line screening technique are shown in Figure 3.1 and 
Figure 3.2.  The results from the first sampling round (before embalming) are 
shown in Figure 3.1 while the second sampling round (3 weeks after 
embalming) is shown in Figure 3.2.  The first round sampling results of the 
first line screening showed that 15% of the samples tested positive for the 
presence of TB in the Apex area.  In the hilus area, 25% of the samples 
yielded a positive result as seen in Figure 3.1. The first line screening 
technique, both the first and second sampling rounds yielded a larger 
percentage of TB positive samples in the hilus area of the lung.   
 
62 
 
It is important to note that during the study families of the deceased claimed 2 
cadavers before the second sample could be taken.  This is the reason for 
n=20 for the first sample and n=18 in the second sample in Figure 3.1 and 3.2 
 
First line screening - 1st Sample
100 15 25
80
60
85 Pos.
40 75
Neg.
20
0
Apex 1 Hilus 1
Sample area  
Figure 3.1 Graph depicting the percentage of first samples with a positive 
and negative TB result, with the first line screening technique (n=20). 
 
Percent
63 
 
First line screening - 2nd Sample
100 11 22
80
60 Pos.
89
40 78 Neg.
20
0
Apex 1 Hilus 1
Sample area
 
Figure 3.2 Graph depicting the percentage of second samples with a positive 
and negative TB result, with the first line screening technique (n=18). 
 
The first round sampling results of the growth in the main study showed that 
50% of the samples tested positive for the presence of TB in the Apex area.  In 
the hilus area, 40% of the samples yielded a positive result as seen in Figure 
3.3.  With the second sampling round, none of the samples in both the apex 
and hilus areas tested positive for TB growth (Figure 3.4).  When looking at 
TB growth, the first sampling round yielded a 50% and 40% positive TB 
growth in the apex and hilus areas respectively, yielding a larger percentage of 
TB positive samples in the apical area of the lung.   
 
Percent
64 
 
Growth - 1st Sample
100
80 50 40
60 Pos.
40 50 60 Neg.
20
0
Apex 1 Hilus 1
Sample area
 
Figure 3.3 Graph depicting the percentage of first samples with a positive 
and negative TB result, with TB growth (n=20). 
 
Growth - 2nd Sample
0 0
100
80
60 100 100 Pos.
40 Neg.
20
0
Apex 1 Hilus 1
Sample area
 
Figure 3.4 Graph depicting the percentage of second samples with a positive 
and negative TB result, with TB growth (n=18). 
 
Percent
Percent
65 
 
The results are summarized in Table 3.3 on the next page.  Thirteen of the 20 
cadavers (Table 3.3) had a viable strain of MTB before embalming either in 
the apical or hilus area as tested with TB growth.  Fourteen of the 20 cadavers 
had died of pulmonary TB (PTB), 4 of Miliary TB, 1 of bronchogenic TB 
spread and 1 of tuberculous meningitis, according to their death certificates.  
Table 3.3 also indicates the days between date of death and embalming.  It is 
of special interest to mention that cadaver 56-11 still had viable MTB 36 days 
after death. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
66 
 
Table 3.3 Cause of death according to death certificate and the number of 
days the MTB is still viable in the cadavers. 
Reference Cause of death Number of Viable MTB Viable MTB 
(according to days between before 3 weeks after 
death certificate) date of death embalming embalming 
and embalming (TB growth) (TB growth) 
22-09 PTB* 25 Yes No 
24-09 Miliary TB 29 Yes No 
34-09 PTB* 17 No No 
38-09 Bronchogenic TB 18 Yes No 
40-09 PTB* 22 Yes No 
42-09 PTB* 23 Yes No 
44-09 Miliary TB 23 Yes No 
55-09 PTB* 19 Yes No 
56-09 PTB* 29 No No 
75-09 PTB* 25 Yes No 
78-09 Miliary TB 19 Yes Claimed 
80-09 Miliary TB 27 Yes No 
10-10 PTB* 11 No Claimed 
13-10 PTB* 12 No No 
14-10 PTB* 14 Yes No 
25-10 PTB* 40 No No 
29-10 PTB* 29 Yes No 
38-11 TB meningitis 21 No No 
53-11 PTB* 10 No No 
56-11 PTB* 36 Yes No 
*PTB = Pulmonary TB 
 
67 
 
Table 3.4 shows the number of male and female cadavers tested for the study.  
Samples were taken from 16 male and 4 female cadavers.  From the 16 male 
cadavers, 11 samples were taken from the left lung and 5 from the right lung.  
From the 4 female cadavers, 2 samples were taken from the left lung and 2 
samples from the right lung.  The positive and negative indicate if the sample 
tested was TB growth positive or negative thus containing viable MTB (Table 
3.4) before embalming.   
 
Table 3.4 Comparison between the number of right and left lungs and male 
and female cadavers tested. 
 Left lung Right lung Total 
 Total Positive Negative Total Positive Negative  
Male 11 8 3 5 2 3 16 
Female 2 2 0 2 1 1 4 
Total 13 10 3 7 3 4 n = 20 
 
In Table 3.4 for the male cadavers tested, 10 of the specimens out of the 16 
(62.5%) tested contained viable MTB in either the apical or hilus area.  Three 
of the 4 female cadavers tested contained viable strains of MTB (75%) in 
either the apical or the hilus area.  Thirteen samples were taken from the left 
lung and 10 of those samples tested positive for MTB (77%).  Seven samples 
68 
 
were taken from the right lung and 3 of those samples tested positive for MTB 
(43%). 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
69 
 
4. DISCUSSION 
 
4.1 PILOT STUDY 
 
Only 2 of the cadavers (in pilot study included in main study) were tested after 
6 months.  The reason, after six months the cadavers are released to the 
medical students for dissection purposes.  The reason why only 2 cadavers 
(22-09 and 24-09 in Table 3.3) were tested is that none of the samples tested 
contained viable MTB 3 weeks after embalming and thus it was not necessary 
to test them again after 6 months.  The financial implication of the test also 
played a role in only testing the 2 cadavers.  The 2 cadavers tested after 6 
months tested negative with the ZN stain as well as no growth was detected 
after 6 weeks.  This indicates that the medical students and embalmers can 
handle the cadavers after 6 months of embalming with minimum safety 
precautions concerning TB.   
  
The results from the pilot showed that three weeks after embalming none of 
the tested cadaver’s lungs contained viable MTB.  Although some of the 
samples had positive results after 3 weeks with the ZN staining, these samples 
70 
 
contained non-viable MTB as no growth was detected after 6 weeks.  ZN 
staining only tests the presence of MTB and not the viability.  
  
71 
 
4.2 MAIN STUDY 
 
From the results, it is clear that the embalming fluid is effective in rendering 
the bacilli non-infectious because no growth was detected 3 weeks after 
embalming with the MGIT culture method.  Before embalming, 40% and 50% 
of the apical and hilus samples tested positive with the TB growth respectively 
and no growth was detected 3 weeks after embalming.  The culture method 
(MGIT) can differentiate between dead and live bacilli.  This indicates that the 
embalming fluid effectively rendered the bacilli non-viable.   
 
When using the ZN stain, both the first and second sampling rounds yielded a 
larger percentage of TB positive samples in the hilus area of the lung.  
Although positive samples were observed with the ZN stain 3 weeks after 
embalming, this technique only tests for the presence of acid-fast bacilli, not 
the viability of the bacilli.  The sensitivity is directly proportional to the 
number of acid-fast bacilli present (Mackie et al. 1978), and can be a reason 
for the higher concentration of bacilli present in the hilus area.  
 
TB growth in the first sampling round yielded a 50% and 40% positivity in the 
apex and hilus areas respectively, yielding a larger percentage of TB positive 
72 
 
samples in the apical area of the lung.  This indicates that more viable MTB is 
found in the apical area of the superior lobe than in the hilus region.  
Experiments conducted with macrophages demonstrated that a high oxygen 
pressure promote growth of the MTB bacilli (Cardona and Ruiz-Manzano 
2004).  Thus the apical area with higher concentration of oxygen is an optimal 
environment for the aerobic MTB bacillus (Martin, Cline and Marshall 1953).  
Another reason for the higher concentration of MTB in the apical area may be 
the impaired lymphatic drainage in the apical area according to Leung (1999). 
 
Thirteen of the 20 cadavers (Table 3.3) had a viable strain of MTB before 
embalming either in the apical or hilus area as tested with TB growth.  
Although all 20 cadavers’ death certificates indicated that the cause of death 
was PTB, miliary TB or tuberculous meningitis, 7 of the samples still tested 
negative for viable MTB as no growth was detected on the MGIT culture 6 
weeks after embalming.  A reason for this might be that they were on TB 
treatment before death, which rendered the bacilli non-viable, thus resulting in 
the negative results for MTB.  
 
As seen in the results (Table 3.3), 14 of the 20 cadavers had died of 
pulmonary TB (PTB), 4 of miliary TB, 1 of bronchogenic TB and 1 of 
73 
 
tuberculous meningitis according to the death certificates.  Miliary TB, as 
discussed in Chapter 1, is the spread of MTB to the rest of the body.  The 
name comes from the pattern that one can see on a chest X-ray, the tubercle 
looks like tiny spots on the lung, resembling a millet seed.  Miliary TB can 
occur after the primary infection or during reactivation of a latent infection in 
about 15% of TB patients (Bloom and Murray 1992). 
 
Bronchogenic is defined as originating in the bronchi, thus bronchogenic TB 
spread is the spread of TB through the bronchi.  Endobronchial TB is MTB 
infection in the tracheobronchial tree.  Endobronchial TB may be a result of 
the direct implantation of the MTB bacilli in the bronchus, another cause may 
be from rupture of caseous material from lymph nodes (Ip, So, Lam and Mok 
1986).  Lymphatic spread along the bronchial tree and haematogenous spread 
is less common (Ip et al. 1986).  It clinically resembles bronchogenic 
carcinoma.    
 
Tuberculous meningitis is a form of disseminated TB and the most devastating 
type of meningitis according to Haldar, Sharma, Gupta, and Tyagi (2009).  If 
left untreated, the case fatality rate is 100%.  In tuberculous meningitis, the 
bacilli travel in the blood to the meninges where they form small subpial foci, 
74 
 
called Rich foci (Thwaites, Chau, Mai, Drobniewski, McAdam, and Farrar 
2000).  If these foci rupture, the bacilli are discharged into the subarachnoid 
space.  
 
Sixteen male cadavers and 4 female cadavers were included in the sample.  
Eighty percent of the cadavers tested were male, and died of PTB or a TB 
related infection.  Adult men are diagnosed more often with TB, according to 
the WHO (2002).  Diwan and Thorson (1999) also stated that more males than 
females are infected with TB.  They attribute this difference to immune 
response differences between the two genders.  Difference in roles in society 
may also influence the risk of exposure to MTB (WHO 2002). 
 
4.2.1 Resistance of Mycobacterium tuberculosis 
 
According to previous studies, after death, MTB can remain infectious for 
about 8 days in unembalmed lung tissue (Nolte 2005), up to eight days at 20 - 
25oC and up to 14 days if stored between 2 - 4o C in sputum (Collins and 
Grange 1999).  From the results in this study, it is clear that MTB can survive 
in dead bodies with significant post-mortem intervals.  The MTB remained 
viable for 14 – 36 days before embalming took place as seen in Table 3.3.  As 
75 
 
mentioned previously, after death, the dead bodies are stored in the mortuary.  
If not claimed, the department of Basic Medical Sciences is notified.  These 
bodies are kept in a fridge at -5 – -9oC. 
 
MTB has very simple growth requirements, multiply slowly (every 20 hours), 
grows optimally in about 38°C (Devi, Shaila, Ramakrishnan and Gopinathan 
1975), and is able to grow in harsh conditions.  MTB is also highly resistant to 
extreme temperatures, as it remained viable for 36 days in cadaver 56-11 
(Table 3.3) in cold temperatures ranging between -5 – -9oC.  MTB can be 
preserved by freezing on glass beads at -70oC.  A study by Giampaglia, de 
Brito, Martins, Ueki, Latrilha, de Oliveira, Yamauchi and da Silva Telles 
(2009) showed that 94% of the strains preserved at −70°C on glass beads 
could be recovered within 30 days. 
 
The high lipid content of the MTB bacilli is responsible for the resistance 
against acid and alkali.  Thus, the high lipid content also makes it more 
resistant to disinfection.  A previous study by Best, Sattar, Springthorpe, and 
Kennedy (1990) indicated that phenol (5%) inactivated MTB, and ethanol 
(70%) was only effective against MTB in suspension. According to Kappel, 
76 
 
Reinartz, Schmid, Holter, and Azar (1996) the antibacterial action of alcohol 
is increased when alcohol is added to formalin. 
 
A study done by Fukunaga, Murakami, Gondo, Sugi, and Ishihara (2002) 
found that treatment with 10% formalin lowered the sensitivity of bacilli in 
ZN staining.  Gerston et al. (2004) attempted to test the viability of MTB in 
formalin fixed lungs.  The lungs were removed during autopsy and placed in 2 
- 3 L of 10% buffered formalin for a minimum of 2 weeks.  Twelve of the 138 
cases still had viable MTB; 8 of the 12 viable cases were fixed in formalin 
from 20 - 49 days.  Gerston et al. (2004) concluded that MTB can survive in 
lungs fixed in 10% formalin. 
 
4.2.2 Risk of transmission of Mycobacterium tuberculosis 
 
The transmission of MTB during embalming is due to the inhalation of 
infectious aerosols that may escape through the mouth of the cadaver.  This 
risk may be reduced by a proper ventilation system in the mortuary (or 
embalming room) or placing a cloth over the cadaver’s mouth (Morgan 2004).  
Other measures, such as wearing a mask, can also be taken to reduce the risk 
of infection.  Only high filtration masks are capable of preventing the 
77 
 
inhalation of the bacilli in the infectious aerosol.  Ultraviolet germicidal 
irradiation (UVGI) can also be used as this highly effective method uses 
ultraviolet light to kill or inactivate the MTB in the air (Riley 1994). 
 
According to Healing, Hoffman and Young (1995), TB is classified as a 
medium risk to healthy people and stated that, “The embalming of people who 
have died of tuberculosis is unlikely to be hazardous because there is little 
aerosol formation but, because air may be expelled from the lungs of a body 
when it is lifted, it is recommended that the face of the corpse is covered 
temporarily with a disposable cloth.”  From the results obtained in this study it 
is clear that MTB can remain viable after death for up to 36 days and 
precautions should be taken during embalming.  The high pressure used to 
disperse the embalming fluid through the arteries is responsible for the aerosol 
formation expelled through the mouth of the cadaver.   
 
This study also fulfilled its initial aim: “To investigate if MTB is still viable in 
human cadaver lung tissue and especially in granulomatous tissue after 
embalming has taken place”.  The results clearly demonstrated that the 
embalming fluid used at the department of Basic Medical Sciences renders the 
MTB not viable.  Has the following objective been achieved: “The aim was to 
78 
 
test the efficacy of the embalming fluid used at the department of Basic 
Medical Sciences (University of the Free State) on eliminating 
Mycobacterium tuberculosis in human cadaver lung tissue.”  The study 
concluded that the embalming fluid is very efficient concerning eliminating 
MTB.   
  
79 
 
5. CONCLUSIONS 
 
5.1 LIMITATIONS 
 
A possible limitation of the study is the sample size that consisted of 20 
cadavers.  The small sample size was due to financial restraints.  The 
laboratory tests done were very expensive amounting to the amount of R35 
000.  The results were consistent and no growth was detected 3 weeks after 
embalming in any of the apical or hilar samples of the 20 cadavers tested, the 
small sample size may be acceptable for the purpose of this study.   
 
Another limitation could possibly be that 13 samples were obtained from the 
left lung and only seven samples from the right lung.  As describe in Chapter 
2, this was because the accessibility of the sample from the apex was restricted 
if the head was either flexed to the left or to the right side.  According to 
Leung (1999), the right lung is affected more often.  A further study might be 
necessary to confirm this finding. 
 
 
 
80 
 
5.2 VALUE OF STUDY 
 
The results indicate that the embalming fluid used at the department of Basic 
Medical Sciences (UFS) is therefore effective in rendering the cadaver sterile 
and non-infectious as far as MTB is concerned.  The results clearly 
demonstrated no growth was detected 3 weeks after embalming.  The 
composition of the ingredients of the embalming fluid needs no modification 
as it renders the bacilli non-infectious.   
 
The results obtained will be used to ensure that the correct procedures and 
safety precautions are taken by the personnel of the department to prevent 
transmission of MTB to the embalmer and the students.  The findings will thus 
be used to launch a standard operating procedure to ensure that the embalmer 
will be at a minimum risk of contracting MTB from a cadaver during the 
embalming process. 
 
The results also indicate that minimum safety precautions need to be taken by 
embalmers and students 3 weeks after embalming as far as MTB is concerned.  
The six-month period, which is currently the time between embalmment and 
81 
 
dissection by students, also do not need to be changed, as none of the cadavers 
had viable MTB bacilli after 3 weeks. 
82 
 
5.3 FURTHER RECOMMENDATIONS 
 
These findings however, did not test for the viability of other organisms such 
as HIV after embalming has taken place on the cadaver.  Although the results 
obtained indicate that the embalming fluid is an effective bactericide 
concerning MTB, the question arises whether it is an effective virucide.  A 
further study could therefore be conducted to investigate the efficacy of 
embalming fluid as a virucide. 
 
  
 
 
 
 
 
 
 
 
 
 
83 
 
6. SUMMARY 
 
THE EFFECT OF THE EMBALMING FLUID, USED BY THE 
DEPARTMENT OF BASIC MEDICAL SCIENCES (UFS), ON THE 
VIABILITY OF MYCOBACTERIUM TB IN HUMAN CADAVER LUNG 
TISSUE.   
 
Embalming fluid contains substances such as formalin, ethanol, phenol, and 
other solvents to prevent decomposition temporarily.  These agents disinfect, 
preserve, and/or sanitize.  The risk of contracting a disease such as 
tuberculosis (TB) among persons, who are in close contact with recently 
deceased people, is high and the risk varies according to occupation.  Workers 
at Anatomy Departments and embalmers are some of those people who are at 
a greater risk of contracting tuberculosis carried by cadavers.   
 
The question thus arises whether the penetration of formalin and other 
embalming agents into the tissue infected with Mycobacterium tuberculosis 
(MTB) is sufficient to render the bacilli non-infectious.  The aim is to test the 
efficacy of the embalming fluid used at the department of Basic Medical 
84 
 
Sciences (UFS) on eliminating Mycobacterium tuberculosis in human cadaver 
lung tissue.  
 
The cadavers were accompanied by their death certificates indicating the 
cause of death.  Only cadavers whose death certificate indicated that the cause 
of death was TB, was selected to be included in the study.  Closed needle 
biopsies were performed on 20 cadavers to obtain lung tissue from the apical 
and hilar areas.  With the use of a pro-cut biopsy needle, a sample of lung 
tissue was obtained by inserting the needle through the 3rd intercostal (hilar 
sample) and the supraclavicular space (apical sample).  The first sample was 
taken before embalming.  The second sample 3 weeks after embalming.  
Tissue was then retrieved and deposited into a sterile specimen container, with 
saline as transport medium, and transported to Pathcare Laboratory (Drs 
Dietrich, Voigt, Mia, and partners) in Bloemfontein.  The following diagnostic 
tools were used by Pathcare:  direct microscopy from aspirates (lungs in the 
case of Pulmonary TB or from granulomatous lesions), MGIT culture, 
identification using PCR techniques, if positive. 
 
Before embalming 50% of the apical samples tested positive for MTB and 3 
weeks after embalming none tested positive for MTB.  Before embalming 
85 
 
40% of the samples taken from the area close to the hilus (perihilar), tested 
positive for MTB, 3 weeks after embalming none tested positive.  The results 
show that 3 weeks after embalming none of the tested lung samples contained 
viable MTB.  Thirteen of the 20 cadavers tested did have a viable strain of 
MTB before embalming occurred.  It is of special interest to mention that one 
cadaver still had viable MTB 36 days after death.  According to previous 
studies, after death, MTB can remain infectious for about 8 days in 
unembalmed lung tissue and up to 14 days if stored between 2 - 4oC.  From 
this result, it is clear that MTB can survive in dead bodies with significant 
post-mortem intervals. 
  
It is evident from the results that the embalming fluid used at the department 
of Basic Medical Sciences (UFS) renders the bacilli non-infectious, because 
no growth was indicated 3 weeks after embalming 
 
Keywords: Embalming fluid, viability, Mycobacterium tuberculosis, cadaver, 
tuberculosis, UFS, formalin, lungs. 
 
 
 
86 
 
OPSOMMING 
 
DIE EFFEK VAN DIE BALSEMVLOEISTOF, GEBRUIK DEUR DIE 
DEPARTEMENT VAN BASIESE MEDIESE WETENSKAPPE (UV), 
OP DIE LEWENSVATBAARHEID VAN MYCOBACTERIUM TB IN 
MENSLIKE KADAWER LONGWEEFSEL. 
 
Die balsemvloeistof bevat stowwe soos formalien, etanol, fenol en ander 
oplosmiddels om ontbinding tydelik te voorkom.  Hierdie agente ontsmet, 
bewaar en/of reinig.  Die risiko van die opdoen van 'n siekte soos tuberkulose 
(TB) is hoër onder persone wat in noue kontak met lyke is en die risiko wissel 
ook volgens beroep.  Werkers by Anatomie Departemente is van die persone 
wat 'n groter risiko beloop om tuberkulose vanaf kadawers te kry. 
 
Die vraag ontstaan dus of die penetrasie van formalien en ander balseming 
agente in weefsel wat met Mycobacterium tuberculosis (MTB) besmet is, 
voldoende is om die basille nie-aansteeklik te maak.  Die doel is om die 
doeltreffendheid van die balsemvloeistof wat gebruik word by die 
Departement van Basiese Mediese Wetenskappe (UV) met betrekking tot 
Mycobacterium tuberculosis te toets. 
87 
 
Die kadawers is vergesel deur hulle doodsertifikate wat die oorsaak van dood 
aangedui het.  Slegs kadawers wie se doodsertifikaat aangedui het dat die 
oorsaak van dood TB was, is gekies om ingesluit te word in die studie.  
Geslote naald biopsies is uitgevoer op 20 kadawers om longweefsel te verkry 
van die apikale en hilus areas.  Met die behulp van 'n “pro-cut” biopsie naald 
is longweefsel deur die 3de interkostale (hilus) en die supraklavikulêre spasie 
(apikale) verkry.  Die eerste monster is geneem voor balseming.  Die tweede 
monster is geneem 3 weke na die balsem proses. Weefsel is onttrek en in 'n 
steriele monster houer gedeponeer, met soutoplossing as vervoer middel, en 
vervoer na Pathcare laboratorium (Drs Dietrich, Voigt, Mia, en vennote) in 
Bloemfontein.  Die volgende diagnostiese instrumente is gebruik deur 
Pathcare: direkte mikroskopie aspirates (longe in die geval van pulmonêre TB 
of van granulomateuse letsels), MGIT kultuur metode, identifiseer met PKR 
tegnieke, indien die uitslag positief is. 
 
Voor balseming het 50% van die apikale monsters positief getoets vir MTB en 
3 weke na die balseming het geen monster positief getoets vir MTB met die 
MGIT kultuur metode nie.  Voor balseming het 40% van die monsters wat 
geneem is uit die area naby die hilus, positief getoets vir MTB en 3 weke na 
die balseming het geen positief getoets.  Die resultate toon dat 3 weke na 
88 
 
balseming geeneen van die long monsters lewensvatbare MTB bevat het nie.  
Dertien van die 20 kadawers wat getoets is, het 'n lewensvatbare stam van 
MTB bevat voor balseming.  Dit is van besondere belang om te noem dat een 
kadawer nog lewensvatbare MTB 36 dae na dood gehad het.  Volgens vorige 
studies, na dood, kan MTB aansteeklik bly vir ongeveer 8 dae in longweefsel 
wat nie gebalsem is en tot 14 dae indien gestoor tussen 2 - 4°C. Vanuit hierdie 
resultate is dit duidelik dat MTB kan oorleef in lyke met beduidende post-
mortem-intervalle. 
 
Dit is duidelik uit die resultate dat die balsemvloeistof wat gebruik word by 
die Departement van Basiese Mediese Wetenskappe (UV) die basille 
onaansteeklik maak, as gevolg van  die feit dat daar geen groei 3 weke na 
balseming is nie. 
 
 
 
 
 
 
  
89 
 
7. REFERENCES 
 
Ajmani, M.L.  1998.  Embalming: Principles and Legal Aspects.  Jaypee 
Brothers Publishers: 112-117. 
Author unknown.  2006.  Cross section through the thorax at vertebra T5.  
[Online image]  <http://www.oocities.org/afgalaly/Respiratory.html>   
[Accessed 25 June 2012] 
Best, M., Sattar, S.A., Springthorpe, V.S., and Kennedy, M.E.  1990.  
Efficacies of selected disinfectants against Mycobacterium tuberculosis.  
Journal of Clinical Microbiology, 28(10):2234-2239.  
Bloom, B.R. and Murray, C.J.L.  1992.  Tuberculosis: Commentary on a 
Reemergent Killer.  Science, 257(5073):1055-1064.  
Blumberg, L.  1995.  Developments in Tuberculosis.  The South African 
Journal of Epidemiology and Infection, 10(4):118-122. 
Brink, A.J. and de Kock, M.A.  1973.  Hart en Longsiektes.  Kaapstad: Nasou 
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APPENDIX A