The Effect of Different Washing Treatment against Protein Quantity
and Agglutination Level in Bloodstain for Forensic Identification
Ardyan Pradana Putra
1
, Hartono Kahar
2
and Ahmad Yudianto
1,3
1
Master of Forensic Science School Postgraduate School, Universitas Airlangga, Surabaya, Indonesia
2
Department Clinical Pathology Faculty of Medicine Universitas Airlangga Surabaya
3
Department Forensic Medicine and Medicolegal, Faculty of Medicine, Universitas Airlangga, Surabaya, Indonesia
Keywords: Agglutination level, Bloodstain, Forensic Identification, Protein Quantity, Washing
Abstract: Forensic examination of bloodstain provides important information to uncover inquired offense because
blood is easily scattered in almost all forms of violence, and its biological state has specific properties in
each person. In reality, perpetrators often attempt to conceal blood stained evidences to block revelation
during investigation by disposing, burying, burning & washing. A number of stained evidences account but
worn clothes during the incident are usually treated in either of the form, and when washed, chemicals such
as detergents and bleach solution (NaClO) are used. The purpose of this study was to investigate the effect
of washing on protein quantity and agglutination level on bloodstain in clothes for forensic identification.
This is a laboratory experimental study, in which 32 samples of bloodstained clothes were given different
treatments: tap water only, detergents and bleach solution with a control without washing. From the total of
32 samples, 16 samples were measured for protein quantity using UV spectrophotometer and 16 samples for
agglutination level. The results were then analyzed using statistical parametric One Way Anova with
significance level of 0.05. The result of statistical test obtained (p value <0.05) showing that there was a
difference between the mean of protein quantity and agglutination level on bloodstain sample in each
treatment. This research concluded that there is an effect on blood protein quantity and agglutination level
due to washing type used (tap water, detergent, and bleach solution) by its decreasing trend supported by
leaching and protein denaturation behavior.
1 INTRODUCTION
Along with the development of science and
technology in the field of molecular biology, in
efforts to solve case, especially the criminal, the law
enforcers i.e., the police, prosecutors, judges and
legal counsel would require assistance from the
experts. In accordance with their respective fields,
the experts will examine the evidence (corpus
delicti) scientifically so that the tragedy can illustrate
the case, and at the end, to determine a bright spot
about a crime act (Darmayani, 2011).
According to the data from Badan Pusat Statistik
(2016), crime rates in Indonesia fluctuate during the
period of 2013-2015. Of the many cases of crime,
murder case tops the list, followed by crime against
physical (violence). As per report of the Bureau of
Development and Operations of the National
‘MABES POLRI’, the total number of crime
incidents in 2013 was 342,084 cases which
increased to 352,936 cases in 2015. Meanwhile, the
risk of crime rate per 100,000 population is
estimated to be 140 people by 2015.
In cases of murder or violence, it is very
common to find evidence related to a crime both left
at a crime scene and attached to the body of the
perpetrator or victim. Physical evidence of body
material can be bloodstain, sperm, tissue, hair etc.
(Puspitaati et al, 2016). Forensic examination of
bloodstain provides important information to
uncover inquired offense because blood is easily
scattered in almost all forms of violence, and its
biological state has specific properties in each
person (Idries, 2013). Serological examination of
bloodstain can be done quickly and inexpensively
with a variety of methods using preference of
Absorption Elution Technique (Hoediyanto, 2012).
In reality, perpetrators often attempt to conceal
blood stained evidences to block revelation during
investigation by disposing, burying, burning &
446
Putra, A., Kahar, H. and Yudianto, A.
The Effect of Different Washing Treatment against Protein Quantity and Agglutination Level in Bloodstain for Forensic Identification.
DOI: 10.5220/0007544704460452
In Proceedings of the 2nd International Conference Postgraduate School (ICPS 2018), pages 446-452
ISBN: 978-989-758-348-3
Copyright
c
2018 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
washing. A number of stained evidences account but
worn clothes during the incident are usually treated
in either of the form, and when washed, chemicals
such as detergents and bleach solution (NaClO) are
used (Yudianto, 2013). Detergent & sodium
hypochlorite are some chemical examples and
household cleaning agents used as cleanser because
they contain surfactants, which is capable to clean
stains of dirt and blood spots, so they can dissolve in
water (Marcelisa, 2015). Based on the problem,
phenomena, and gap described above, it is important
to know the effect of different washing treatment
towards protein quantity and agglutination level on
bloodstained clothes for forensic identification.
2 METHODOLOGY
2.1 Research Design
This was a laboratory experimental study, posttest
only control group design. In which 32 samples of
bloodstain on cloth were given different treatments
which are without washing (control), washing using
tap water, detergents and bleach solution. From the
total of 32 samples, 16 samples were measured for
protein quantity using UV spectrophotometer and 16
samples for agglutination level. The result of protein
quantity measurement was then analyzed using
parametric One Way Anova with the requirement of
normal and homogeneous data, while the
agglutination level data was analyzed using
nonparametric Kruskal Wallis statistic test. This
research was conducted at Human Genetic
Laboratory, Institute of Tropical Disease,
Universitas Airlangga, Surabaya.
2.2 Materials and Method
2.2.1 Materials
Blood with blood group A (Rh+), cloth (cotton),
Detergent (active ingredient 19% Anionic
Surfactant), stain/bleach cleaner (5.25% NaCIO), tap
water & washing machine.
2.2.2 Reagent
Ether Alcohol, Anti A, tap water, 2% Red Blood
Cell Suspension, distilled water, Guanidine HCL,
Trizole reagent, Chloroform, Ethanol, Isopropanol,
1% SDS and 0.9% NaCl.
2.3 Research Procedures
2.3.1 Collection of Sample
Blood samples were obtained from a volunteer who
had blood type A (Rh+) and stored in an EDTA
vacutainer tube. Then, blood spots were made on
cotton clothes by way of blood drops as much as
300μ in each spotting. The number of blood spots on
each shirt was 2 spots of blood, 1 spot of blood for
the examination of protein level and the other one
for the measurement of level of agglutination. The
total number of blood spots formed was 32 spots.
2.3.2 Washing of Stains
The clothes were washed using a washing machine
(LG Inventer ®). The washing process was done
separately based on the shirt label. A stained labeled
shirt was not washed, for control. B labeled shirt that
has blood spots washed in a 10 liters of tap water
without detergent, C labeled clothes soaked in 10
liters washing machine that has been added 30
grams of powder detergent, while D labeled clothes
were soaked in a 10 liters of tap water which has
added 60 ml stain cleaning solution (5.25% NaCIO)
then washed with the washing machine with
automatic setting. Once the washing process is
completed, it was rinsed with tap water for 1 time.
Then all clothes were allowed to dry by hanging at
room temperature.
2.3.3 Sample Preparation
Each shirt labeled A, B, C & D that has dried after
washing process is cut into small pieces on the area
where the blood stains are marked. They were then
inserted into the test tube based on the label to read
protein content and the level of agglutination.
2.3.4 Examination of Protein Quality
The estimate of protein quantity in blood spots were
measured using a Spectrophotometer with a
wavelength of 280 nm, using an absorbance ratio of
280/260 to determine the correction factor present in
a table. The level of protein was determined by the
following formula: protein content (mg / ml) = A280
x correction factor x dilution. Finally, the protein
was isolated using Trizole reagent, Chloroform,
Ethanol, Isopropanol, SDS 1% & Guanidine HCL.
The Effect of Different Washing Treatment against Protein Quantity and Agglutination Level in Bloodstain for Forensic Identification
447
2.3.5 Examination of Agglutination Level
Agglutination level examination was done by
soaking the pieces of cloth contained blood spots
into the reaction tube containing reagent anti A.
Then incubated at 4oC for at least 16 hours. After
the immersion, the anti-A reagent in the test tube
was removed and replaced with 0.9% NaCl.
Washing was performed with NaCl 0.9% 5 times
and centrifuged at 1000 rpm for 1 minute to remove
the rest of the reagent. After the last centrifuge,
0.9% NaCl was added and warmed for 15 minutes at
a temperature of 56oC. After the warming, 2% of
blood suspense was added and incubated at 4oC for
2 hours then shaken strongly. After the procedure,
the level of agglutination was recorded.
3 RESULT AND DISCUSSION
3.1 Bloodstain Protein Quantity Under
Varied Washing Treatment
32 formed bloodstains samples on 16 pieces of
cotton clothes spotted with blood drops of 300μ each
and washed under treatments without washing,
washing using only tap water, detergents, and bleach
solution gave results on protein quantity and
agglutination level as follows;
Protein content measurement using
spectrophotometer at UV 280 nm wavelength by
absorbance ratio of 280/260 determined the
correction factor that exist in a table. These levels of
protein were determined by the following formula:
protein content (mg/ml) = A280 x correction factor x
dilution.
Figure 1. Graph of protein content in blood spots with
different treatment
Blood protein levels shown in Figure 1 showed a
decrease in the mean difference of protein levels in
various groups, i.e. in the untreated group and the
tap water washed group. The decrease of protein
content was at 0.6 mg / ml. The group without
treatment and the detergent washed clothes was at
1.42 mg / ml; and the group without treatment with
bleach (NaClO) washed group was at 1.88 mg / ml.
Statistically; detergent leaching effect on protein
content, Anova parametric analysis responded
normally. According to the test, all data obtained
results at p value> 0.05, ie p value for protein
content based on the difference of treatment of
(0.150-0.95), this stated a normal distribution of
studied data. P value obtained, measured > 0.05.
This study variance assume homogeneous data. The
data in this study have qualified because of normal
distribution and homogeny, then statistical analysis
parametric Anova (One Way Anova) followed.
Table 1: One Way Anova parametric analysis of washing
effect on protein content
The result of statistical analysis of parametric
One Way Anova in Table 1 obtained the value of p
(sig.) = 0.001 because the p value (sig.) <0.05. Then
by this test, H0 is rejected and H1 is accepted which
means to effect of washing type on protein content at
spotting blood with UV spectrophotometer method.
Bloodstained samples under different treatments
as resulted in findings portray significant
information on the effect of washing as concealment
of evidence in forensic inquiries. Referring to blood
protein quantity shown in Figure 1, a decreased in
the mean of protein levels is observed in various
groups. The summary is given by: the group without
washing, the average protein content of 2.17 mg / ml
is presented, tap water at 1.57 mg / ml, washing
group detergent at 0.75 mg / ml, and washing group
using bleach (NaClO) at 0.29 mg / ml.
Interpretation of the findings of this study
showed that washing using bleach (NaClO) was
more likely to decrease protein levels compared to
detergents and tap water. The observed differences
ICPS 2018 - 2nd International Conference Postgraduate School
448
of protein group without treatment with washing
group using bleach (NaClO) were 1.88 mg / ml. The
group without treatment, washing group using
detergent of 1.42 mg / ml, the group without
treatment, and washing group using tap water of 0.6
mg / ml.
Decreased protein levels from the total blood
spots occurred due to washing and occurrence of
protein denaturation is due to exposure to detergent
chemicals and stain cleaning fluid. Denaturation of
proteins is the loss of higher structural properties by
disruption of hydrogen bonds and other secondary
forces required by the molecule. Factors that can
cause protein denaturation include temperature, pH,
physical factor (mechanical), and addition of
chemicals. Changes in temperature and pH can
disrupt the structure of the protein and cause loss of
function. The pH of the detergent alone > 10 also
certainly cause protein denaturation (Silverthorn,
2014).
Washing the sticking blood stains on clothes
requires three types of energy. The three energies
are: chemical energy supplied by detergent, thermal
energy provided by warm or hot water, and
mechanical energy derived from washing machine
or hand. The role of mechanical energy derived from
the movement of the washing machine causes
erasion of all blood spots sticking to the fabric. All
of these three energies must work in synergy so that
the washing process can be effective (Ophardt,
2013).
If leaching uses only water, the quantity of
protein content remaining is more than washing
using detergent because the detergent contains
chemical composition as one of its ingredients is
responsible for protein structural destruction. Similar
to Sopiah Nida (2015), the function of surfactant in
detergent is also to reduce surface tension so as to
increase the wetting power of the water, which in
return wet and erode the bloodstain, loosen and
remove the dirt and suspend the loose dirt (Sopida
Nida, 2015). Biological detergents contain enzymes
designed to hydrolyze protein molecules, and
therefore, are potential to further lower blood stains
and protein levels (Oldfield, 2017).
Tap water will not be able to remove blood spots
that have spread into the fabric fibers. In such cases,
detergent is used to remove stains spotted blood.
Structurally, protein remain active at 30oC-48oC,
above it to 50oC the biological structure will be
subjected to destruction hence denaturation process
occurs (Silverthorn, 2014). The water temperature
detergent added will usually increase. Therefore,
high temperature washing can remove traces of
blood to a greater extent than cold or lowered
temperatures (Oldfield, 2017).
Similar to previous experiments conducted by C.
Oldfield et. al. (2017), the interpretation of the
research findings showed that detergent and NaClO
are able to remove some blood traces. This finding
may be useful for investigations of offenses that
suspect the use of detergent and NaClO in
concealing the bloodstain evidence by washing
method, making it potentially useful to test
suspected items and/or perform additional analysis
on evident suspected material.
Research conducted by K.A. Harris in 2006
support this study by deriving that all of the cleaning
agents, bleach has the most damaging effect on the
quality of DNA profile obtained in blood spots.
Therefore, from the citation above; it is learnt that
the quantity measure of DNA in biological
substances treated with bleach decreases over time
due to degradation – congruent to the quality above.
This condition is not visible on the substrate being
cleaned with soap, detergent, and / or non-chlorine
disinfectant.
3.2 Bloodstain Agglutination at Varied
Washing Treatment
The result of measurement of blood group
agglutination level by using Absorption Elution
method of bloodstain on cloth in group without
treatment, washing group using tap water, washing
group using detergent and washing group using
bleach (NaClO) can be seen in table 2 below:
Table 2: Agglutination Rate Data on Blood Spot on Cloth
The Effect of Different Washing Treatment against Protein Quantity and Agglutination Level in Bloodstain for Forensic Identification
449
Based on the result of blood group agglutination
level by using Absorption Elution method on the
blood spots in cloth, the change of agglutination
level (tend to decrease) in the group without
treatment, washing using tap water, washing with
detergent, and washing with bleach (NaClO). In the
washing with detergent and washing with bleach
(NaClO) group, there were 4 samples with negative
agglutination results.
However, to test whether there is a detergent
leaching effect on agglutination rates or not, a
nonparametric statistical analysis by Kruskal Wallis
was performed. The test resulted Kruskal Wallis’
nonparametric statistical analysis, which is portrayed
in Table 3.
Table 3. Kruskal Wallis Test for bloodstain agglutination
level
Agglutination Level
Chi-Square 13.551
Df 3
As
y
m
p
. Si
g
. .004
a. Kruskal Wallis Test
b. Grouping Variable: Treatments
In Table 3, p value (Asymp Sig.) = 0.004, since p
value <0.05, then H0 is rejected, and H1 is accepted.
It means that there is a detergent leaching effect on
the agglutination level in ABO blood group
determination on blood spots with absorption elution
method.
The data on blood group agglutination level in
the sample group without treatment were obtained
+4 by 100%. The group of water-washed samples
obtained +3 by 25% and +2 by 75%. The group
using detergent obtained +1 by 50% and negative by
50%. The group using bleach (NaClO) obtained +1
by 50% and negative by 50%.
Agglutination rate data in the Table 2 tended to
decrease in the trend of untreated group, wash using
tap water group, wash using detergent group, and
wash using bleach (NaClO) group. Thus, the protein
content of a bloodstain is directly proportional to the
level of agglutination. If the protein level decreases,
the agglutination rate also decreases.
As studded in the protein quantity above, the
tending effect was also contributed by the impacting
energy that directly or indirectly affects molecular
structure of protein. The force energy: chemical
energy, thermal energy, and mechanical energy are
counted several inclusive factors (Ophardt, 2013).
The other agglutinating factors (antibody-antigen
reaction), apart from those generated by friction due
to washing, are as discussed by Whitlock (2010).
they are antigen-antibody specificity complex
pairing, noncovalent bond, lock and key physical
mechanism, antigens and antibodies concentration
under prozone phenomenon, temperature, time, pH
(7.2-7.4) plus the surface net negative charge - zeta
potential surrounding red blood cells
.
3.3 Blood Protein Quantity and
Agglutination Level Effect
From the 16 bloodstain pairs (300μ each) made on
16 cotton pieces of cloth, one pair was assessed for
agglutination and the other pair for protein content.
The 32 blood drops (16 pairs) in total treated under
similar treatment gave corresponded reaction
according to the category of assessment. The
findings were obtained from the two factors
analyzed which was built on the potential impact.
Discussing the factors in aggregation, it conveys a
meaningful attribute of combined factors in
ascertaining the extent.
Referring to the 4 different types of treatment
used for both agglutination or protein content:
without washing (which referred as control), average
protein content was measured at 2.17 mg / ml with
+4 agglutination level at 100%. The control reaction
(without the use of treatment) portrays a set
benchmark of a 100% positive reaction to
agglutination with maximum protein content.
Washing using only tap water (treatment) present a
decreased amount of protein content to 1.57 mg / ml
with agglutination level of +3 by 25% and +2 by
75%. Detergent washing treatment resulted into a
continued lowering effect of protein content to 0.57
mg/ml when referred to control content. The
corresponding drops agglutinatinated a level of +1
and negative by 50%/50%. Washing by bleach
solution gave a protein content of 0.29 mg / ml at
agglutination level of +1 by 50% and negatively too.
In this study, the differences in washing blood
spots proved to affect protein content and
agglutination levels. There was a significant
decrease in the average level of protein in blood
spots washed using tap water, detergent and bleach.
Either washed using detergent and washed with
bleach, both give equal chance of either obtaining
agglutination at +1 or not obtaining at all (negative
agglutination reaction). The probability to
agglutination is counted and vice versa with the
content of protein (Refer Figure 1 and Table 2).
Likewise, various factors that affect the level of
protein in bloodstain will also affect the results of
agglutination examination level in bloodstain.
ICPS 2018 - 2nd International Conference Postgraduate School
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Thereby, the aggregation of findings analyzed
from protein concentration and blood agglutination
showed a paralleling and complementing
dependency resulted by washing treatment.
This study is based in blood tissue cellular
content. Conceptually, protein content and
agglutination level determine the behavior and state
of the blood cellular composition. Focusing on red
blood cell (erythrocytes), the contained protein
integrates with the cell wall, which is antigenic. The
composition of the red blood cell membrane is 49%
protein, 43% lipids and 8% carbohydrates. This
variation in protein in erythrocytes, which results in
blood, is divided into several groups called blood
groups (Silverthorn, 2014).
Thus, each blood group has its own antigen on
the surface of the red blood cell membrane. Blood
type antigens consist of carbohydrates and proteins.
They together form glycoproteins and all are
attached to various components in the red blood cell
membrane. Protein is one of the macromolecules
that make up more than half of the cell (Silverthorn,
2014). Hence, the amount of protein contained
directly affect agglutinin reaction. Thus, the more
damaging and destruction to cellular protein, the
more it responds to weakened agglutination in order
to complicate in ascertaining and determination of
the forensic inquiry.
4 CONCLUSIONS
Forensic examination of bloodstain provides
important information to uncover inquired offenses
because blood is easily scattered in almost all forms
of violence. In this study, the difference of washing
treatment on bloodstain proved to affect protein
content and agglutination levels. There was a
gradual significant decrease in the average of protein
content and level of agglutination in blood spots
washed using tap water only, detergent, and bleach.
The decrease in the average of protein content and
the level of agglutination in this study was caused by
various factors, including mechanical factors derived
from washing machines, chemical factors provided
by detergents and bleach liquids, and thermal factors
provided by water with a detergent mixture. In
addition, the temperature factor, time, pH, and
antigens-antibodies concentration also affect the
decrease in the average protein content and the level
of agglutination in blood spots. In general, a
decreased protein content and agglutination level is
by protein denaturation and destruction due to
washing treatment and exposure to detergent
chemicals and stain cleaning fluids.
Hence, amount of protein contained is directly
affected by agglutinin reaction. Thus, the more
damaging and destruction to cellular protein, the
more it responds to weakened agglutination in order
to complicate in ascertaining and determination of
the forensic inquiry. The study opens up a new
approach to blood identification even after washed
with detergent, which could prove useful in solving
important forensic criminal cases
ACKNOWLEDGEMENTS
The authors would like to thank the technicians of
the Human Genetic of Tropical Diseases (ITD)
Laboratory of Airlangga University and all those
who have assisted in the completion of this research.
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