Laboratory Analysis (Halal Forensic) PDF

Summary

This presentation covers various aspects of Halal forensic analysis, including the prohibition of pork in Islam, issues related to food processing and production, such as adulteration, and genetically modified organisms (GMOs). It also examines safety concerns, particularly in the South Korean context.

Full Transcript

LABORATORY ANALYSIS
(HALAL FORENSIC)

Assoc. Prof. ChM, Dr Mohd Sukri Hassan
THE PROHIBITION OF SWINE IN ISLAM
“He has only forbidden you dead meat, and blood,
and the flesh of swine and that on which any other
name hath been invoked besides that of Allah. But if
one is forced by necessity, without willful
disobedience, nor transgressing due limits, - then is
he guiltless. For Allah is oft-forgiving, most
merciful.”

Al-Quran Surah 2: Verse 173
THE PROHIBITION OF SWINE IN ISLAM

And eat of what Allah has provided for you [which is] lawful
and good. And fear Allah , in whom you are believers.

Al-Quran Surah 5: Verse 88
 Processing

Customers’ Genetically
Confidence Modified

Halal
Present
Issues
Product
Ingredients
Safety & & Additives
Quality

Detection
Method
 ▪ Raw materials – animal or plant origin
▪ Slaughtering and stunning – according to Shariah or not
▪ Processing operations/equipment contamination
▪ Packaging/Storage/Transportation (containers and vessels)
▪ Food ingredients and additives
Pig and its by-products (e.g., pork, lard, gelatin)
ISSUES IN
▪
▪ Enzymes (e.g.. rennet)
HALAL FOOD ▪ Emulsifiers (e.g.. E471 or mono- & diglycerides)
PRODUCTION ▪ Alcohol (ethanol)
▪ Biotechnology and GMOs (genetically modified organisms)
▪ Safety and quality aspects (aspect of ‘Thoyyiba’)
ADULTERATION

Adulteration is a legal term for a food product which fails to
meet certain standards.

Adulterants may be intentionally added to more expensive
substances to increase visible quantities, reduce manufacturing
costs and other deceptive or malicious purpose.

Adulterants may also be accidentally or unknowingly
introduced into the substances.
Halal Food Issues from Islamic and Modern Science Perspectives. Nurrul hidayah A.Fadzlillah et al.,
2011
ADULTERATION WITH
PORCINE-BASED PRODUCT
In some countries, food manufacturers choose to
blend vegetable fats with lard to reduce production cost

Lard could be effectively blended with other vegetable
oils to produce shortening, margarines and other
specialty food oils

In other instances, adulteration with porcine products
could be unintentional
Gelatin
SAFETY ISSUES (SOUTH KOREA)
Humidifier sterilizer sold by UK firm killed or
injured hundreds.
Some 178 killed or injured by lung problems
cause by product.
South Korea says 530 people had registered
claims since 2011 of lung ailments from
using humidifier sterilizers marketed by Oxy
Reckitt Benckiser, and similar products
marketed by other firms.
Reckitt Benckiser's global brands include
Dettol antiseptic wash, Nurofen and Durex
condoms.

http://www.dailymail.co.uk/news/article-3569143/Reckitt-Benckiser-exec-
slapped-S-Korea-apologising-deadly-sterilizers.html
SAFETY ISSUES (SOUTH KOREA)

Confrontation: Nearly 180 South Koreans have died or suffered injuries as a result of
lung injuries caused by a humidifier sterilizer sold by Reckitt Benckiser

http://www.dailymail.co.uk/news/article-3569143/Reckitt-Benckiser-exec-slapped-S-Korea-apologising-deadly-
sterilizers.html
GENETICALLY MODIFIED ORGANISM (GMO)?

GMOs or Genetically Modified Organisms are living organisms
whose genetic material has been artificially manipulated in a
laboratory through Genetic Engineering (GE). This relatively new
science creates unstable combinations of plant, animal, bacteria
and viral genes that do not occur in nature or through traditional
crossbreeding methods.
http://www.nongmoproject.org/learn-more/what-is-gmo/
PROS AND CONS OF GMO FOODS

PROS CONS

Insect resistance Allergic
Weather resistance Unknown long term
Disease resistance health effect
Prolonged shelf life Unnatural taste
Increase production
WHERE IS BLOOD PLASMA COME FROM?

BOVINE
PORCINE

FISH
CHICKEN
WHY BLOOD PLASMA ?
Binder

Natural
Bioactive
colour
compounds
enhancer

BLOOD
Protein and
PLASMA
Iron Emulsifier
supplement

Egg replacer Fat replacer
Ofori, J.A. and Hsieh, Y.P.
The Use of Blood and Derived Products as Food Additives.
www.intechopen.com
WHAT IS BLOOD PLASMA?
Liquid portion of blood remaining after
the blood cells [white blood cells
(WBCs), red blood cells (RBCs), and
platelets] have been removed.

The largest user of blood proteins in
food is the meat industry

By 2001, it was estimated that the
food industry was utilizing 30% of
the blood produced in
slaughterhouses
Ofori, J.A. and Hsieh, Y.P. The Use of Blood and Derived Products as Food Additives.
www.intechopen.com
WHERE IS STEM CELL COME
FROM?
WHAT IS STEM CELL?

A stem cell is an immature cell that has the
potential to become specialized into different
types of cells throughout the body

Stem cell procedures currently provide life-saving
treatments for patients with leukemia, lymphoma,
other blood disorders, and some solid tumor
Recycled Used Cooking Oil
RECENT DETECTION ADVANCEMENT

The task of halal authentication cannot rely only
on expertise from shariah alone, but also require
other related technical fields such as food science
and technology, chemistry and veterinary science.

Halal autentication cannot rely solely on physical
inspection and documentation anymore, but also
using the latest high technology analytical
instrumentation.
 Various approaches to detect and quantify
level of adulterants in food products:
Determine the ratios between some
chemical constituent and assuming that
these ratios are constant in particular
food products.
Searching specific markers in food
RECENT
products, either chemical constituent or
morphological components which proves
DETECTION the presence of adulterant in food
products.
ADVANCEMENT Analytical methods derived from physical
analysis by taking account the whole
samples to show the adulteration effects
on physic-chemical properties.
 Fourier Transform Infrared (FTIR) spectroscopy
Differential Scanning Calorimetry (DSC)
Electronic Nose (E-nose) technology
Others
AUTHENTICATION
TECHNIQUES
FOOD AUTHENTICITY
INSTRUMENTS

FTIR GC-MS

DIFFERENTIAL SCANNING CALORIMETRY PCR
FTIR
Food samples (chocolate, cake, biscuits) were
analyzed to identify the differences in FTIR spectra
profiles

FTIR technique combined with chemometric
analysis able to detect and quantify the level of
lard adulterated in food samples.

Offers rapid (results in 2 min), simple, accurate,
reliable, and environmental friendly tool
RECENT DETECTION RESEARCH
FTIR
FTIR
FTIR
 Thermoanalytical technique for monitoring
DIFFERENTIAL changes in physical or chemical properties of
SCANNING
material by detecting the heat changes
CALORIMETRY

Thermogram profile show the presence of lard
in food sample

Relatively simple, accurate and minimum
amount of sample needed
DIFFERENTIAL SCANNING CALORIMETRY
DIFFERENTIAL SCANNING CALORIMETRY
DIFFERENTIAL SCANNING CALORIMETRY
DIFFERENTIAL SCANNING CALORIMETRY
DIFFERENTIAL SCANNING CALORIMETRY
 GAS

37 FAMEs standard
Fatty Acids identification
CHROMATOGRAPHY

4
6
8
10
12
14
16
18
20
22
pA

9.387 - C4:0
9.994 - C6:0
10

11.123 - C8:0

13.084 - C10:0

14.430 - C11:0
15

16.000 - C12:0

17.740 - C13:0

19.586 - C14:0
20

21.020 - C14:1
21.476 - C15:0

22.928 - C15:1
FID1 A, Front Signal (SUZIE2014\160115- 2ND2015-01-16 11-17-25\002B0101.D)

23.362 - C16:0

24.558 - C16:1
25

25.209 - C17:0

26.388 - C17:1
27.001 - C18:0
27.672 - C18:1n9t
28.013 - C18:1n9c
28.745 - C18:2n6t
29.516 - C18:2n6c
30

30.605 - C18:3n6 30.416 - C20:0
31.266 - C18:3n3
31.412 - C20:1
32.098 - C21:0
32.943 - C20:2
33.786 - C22:0
34.076 - C20:3n6
34.739
34.947 C20:3n3
34.825 - C22:1n9
-- C20:4n6
35

35.489 - C23:0
36.440 - C22:2
36.928 - C20:5n3
37.277 - C24:0

38.466 - C24:1
40

42.295 - C22:6n3
min
 0
50
pA

100
150
200
250
300
350
400

9.548 - C4:0

10
15
15.965 - C12:0
16.230
16.888
17.427 - C13:0

19.535 - C14:0

20
21.911 - C15:0

23.363 - C16:0
FID1 A, Front Signal (SUZIE2014\160115 - AISHAH 2015-01-19 09-10-13\037B3701.D)

24.325
24.506 - C16:1
Spiked lard of palm oil

25
25.143 - C17:0

26.254 - C17:1
26.959 - C18:0
27.655 - C18:1n9t
28.044 - C18:1n9c

29.104
29.248 - C18:2n6t 29.487 - C18:2n6c
30

30.319 - C20:0
30.608 - C18:3n6
31.214 C20:1
31.328 -- C18:3n3

32.870 - C20:2
33.659 - C22:0

34.883 - C22:1n9
35

37.118 - C24:0

39.786
40
min
 Scores (training set)
 Loadings (training set)
 PCA application on collected samples at pasar
malam.

Projection of test lard samples (validate PCA
model from training set).

Projection of collected samples (unknown).
 Scores plot of test lard samples
 Scores plot of collected samples
 PCA plot the 5 % spiked lard in palm olein has
significant differs from the control and was use
as database for calibration set (training set)
into PCA projection technique.

The collected night market samples were then
projected into PCA model and found that it
distributed far away from calibration samples
(training set).
Heated Edible Fats , are they similar?
Raw FTIR of Mutton fat (M) and tallow (B) samples show high intensity between 3100 and 3340 cm-1.
Raw FTIR of chicken fat (C) shows high noisy at 3359 – 3390, 2240 – 2250 and 1230 – 1900 cm-1.
Observation at 2800 – 3200 cm-1 shows a similarity between chicken and lard by two identical
peaks.

Both mutton and tallow fats display split spectral peaks at these frequencies which are required
pre-processing data before applying chemometrics
FTIR spectra of all edibles fats after pre-processing using the Savitzky–Golay second derivatives

The spectral ranges at 715 cm-1 and above were selected because the other regions (650 – 714 cm-1) have
no spectral information because of the unvarying spectrum.
Principal components analysis (PCA),
k-mean cluster analysis (k-mean CA) and linear
discriminant analysis (LDA)
PCA of Fourier Transform Infrared Spectroscopy
Linear Discriminant Analysis (LDA) of edibles fats after heat treatments

Lard and chicken lying close to zero for a class are associated with the class.
80.5% of fats were correctly classified
 Principal Component Regression (PCR),
Orthogonal Partial Least Square Regression
(OPLSR) and
Linear Support Vector Machine Regression (SVMR)
PCR
OPLS
 COMPARISON of REAL-TIME PCR and FTIR WITH
CHEMOMETRICS TECHNIQUE in ANALYSING HALAL
SUPPLEMENT CAPSULE
Materials and Method – Comparison Real-Time
and FTIR
FTIR,
DNA Isolation BioDrop Real – Time PCR
Chemometrics

The gelatins Measureme The amplification The analysis was
was extracted nt was was repeated at made on the
according to performed the 35 cycle, due frequency 4000-
Agilent Porcine at to the analysis with 650 cm-1. The
Detection Kits 260 nm – the standard DNA data were
280 nm. (17-33 cycle for analyzed with
bovine and 19-34 PCA techniques
cycle for porcine). using The
Unscrambler X
10.3 software.
 -0.100
0.000
0.100
0.200
0.400
0.500
0.600
0.700
0.800

0.300
586
679
772
864
957
1049
1142
1234
1327
1420
1512
1605
1697
1790
1883
1975
2068
2160
2253
2345
2438
2531
2623
2716
2808
2901
2994
FTIR Spectra in Gelatin Capsule of Supplement Product

3086
3179
3271
3364
3456
3549
3642
3734
3827
3919
4012
S1
S2
S4
S5
S9
S6
S11
S12
S13
S14
S17
S18
 The PCA Score and Loadings Table

⚫ Normalization and smoothing of the FT-IR spectrum of gelatin capsule was shown in the figure
above.
⚫ PCA manipulates the data of variables (peak height of amino acids) in the way that these
variables can be displayed on an x, y coordinate system. PCA did this by calculating principal
components (PC1) which are linear combination of original variables.
 The figure showed the enlarged FTIR spectra at fingerprint regions. The
different peaks in terms of peak intensity were used for selecting the spectral
regions for the quantification and classification of gelatins capsule in
supplement product.
PC1 vs. PC2. PCA was pre-treatment with Savitsky-golay and peak
normalization where PC1 described 89% variation of data, while PC2 and PC3
account for 7% and 3% variations, respectively. Therefore, more than 90% of
variation can be described only by three PCs (The Scores Plot).
The PCA loading plot described the projection of variables in the same plane
as the score plot. From the figure, it was known that 694 and 3271 cm-1 were
the variables giving the most contribution toward PC1, while 1558 and 1635
cm-1 were more influencing on PC2.
 RESULT OF REAL-TIME PCR IN GELATIN CAPSULE OF SUPPLEMENT PRODUCT

Sample Concentration Ct Value Remarks
(ng/µl) Porcine Bovine
Mean ± SD Mean ± SD Mean ± SD
S1 4.85 ± 0.21 26.97 ± 0.38 20.54 ± 1.28 Mixture
S2 3.23 ± 0.34 - 26.20 ± 0.46 Bovine
S4 3.90 ± 0.02 26.41 ± 0.83 23.07 ± 0.76 Mixture
S5 5.08 ± 0.06 27.20 ± 0.74 - Porcine
S6 6.14 ± 0.82 26.57 ± 0.55 - Porcine
S9 2.50 ± 0.17 27.69 ± 0.81 20.52 ± 1.02 Mixture
S11 5.01 ± 0.14 27.73 ± 0.53 21.34 ± 0.68 Mixture
S12 4.72 ± 0.16 26.89 ± 0.47 16.67 ± 0.53 Mixture
S13 4.43 ± 0.01 - 24.23 ± 0.53 Bovine
S14 4.67 ± 0.01 - 31.49 ± 0.75 Bovine
S17 1.94 ± 0.07 - 31.38 ± 1.35 Bovine
S18 3.78 ± 0.54 27.8 ± 0.28 27.81 ± 0.29 Mixture
-CT 1.00 - - -
 Different concentrations of gelatin capsules were detected based on the
threshold cycle (Ct) of each sample which is the cycle number where the
samples fluorescent curve jumps sharply upward and corresponds to the
initial concentration of DNA.
12 retail products, 6 samples were found to contain porcine-bovine gelatin, 2
samples were found to contain only porcine gelatin, with the remaining 4
samples being bovine gelatin.
 Real-time PCR were validated based upon repetitive elements of the porcine
and bovine DNA and they allowed sensitive detection of porcine and bovine
DNA at concentrations 10-5 ng/ul.
The use of FTIR and PCA was investigated to compare the result of real-time
PCR. From this method, wavenumber profiles can classify capsule shells made
from bovine and porcine gelatin but was not successful for classification of
adulteration gelatin in capsule shells.
AUTHENTICATION METHODS FOR HALAL FOOD
ASSESSMENT
Examples of haram ingredients that can be analysed by laboratory analysis methods. (Spigel et al., 2012)
Haram ingredient Identification Examples of laboratory analysis methods References

Animal species Pork meat or DNA hybridization, DNA sequencing, PCR (Aida, Man, Raha, & Son, 2007; Aida, Man,
pork Wong, Raha, & Son, 2005; Che Man, Aida,
derivates, or Raha, & Son, 2007; Farouk et al., 2006; Farrokhi
meat & Jafari Joozani, 2011; Kesmen, Sahin, & Yetim, 2007;
from other Laube et al., 2007; Tanabe et al., 2007)
animal
species

Animal fat Fat composition: FTIR, NIRS, DSC, NMR, HPLC, LC-MS(/MS), (Che Man, Gan, NorAini, Nazimah, & Tan, 2005;
vegetable or GC, PTR-MS, electronic nose technology Fauzi & Mas’ud, 2009; Jee, 2002; Marikkar, Ghazali,
animal fat Long, & Lai, 2003; Marikkar, Lai, Ghazali, & Che Man, 2001;
Nurjuliana, Man, Mat Hashim, & Mohamed, 2011; Rohman &
Che Man, 2010; Syahariza, Man, Selamat, & Bakar, 2005;
Van Ruth, Rozijn, et al., 2010; Van Ruth, Villegas, et al., 2010)
Proteins, peptides Protein SDS-PAGE, CE, FTIR, colorimetry, chromatography (Hashim et al., 2010; HSC, 2009; Venien & Levieux, 2005;
or amino acids composition: (e.g. HPLC), immunoassays and immunoblotting (e.g. Westermeier & Naven, 2002)
from pork origin collagen or ELISA),
gelatine biosensors, NIRS, MS, 2D-PAGE coupled to mass
from pork or spectrometric
other techniques (MALDI-TOF)
animals
Animal origin of Natural or SNIF-NMR, IRMS & SNIF-NMR, (Ebeler, 2007; Fauzi & Mas’ud, 2009)
ingredients synthetic Isotope ratio-based finger prints, chiral GC analysis,
origin, chemical C/N-ratio by CHN-analyser
or
microbial
conversion,
bone or wooden
origin
Alcohol Alcohol GC, electronic nose technology, (Anis Najiha, Tajul, Norziah, & Wan Nadiah, 2010; Boscaini,
PTR-MS Mikoviny, Wisthaler, Von Hartungen, & M€ark, 2004; Fauzi &
Mas’ud, 2009)
AUTHENTICATION METHODS FOR HALAL FOOD
ASSESSMENT

Halal authenticity issues in meat and meat products. Khadijah Nakyinsige et al., 2012
DETECTION RESEARCH
RESEARCH
RESEARCH
Leather and
Bristle Products
Pig Skin

Slanting shape for each hole clearly seen.
FTIR Analysis on
Pig Skin and Standard kulit khinzir, T-Dome

%T
90

Polymers Poly(N-methyl acrylamide)
Match:64.09

%T
50 Molecular Formula:
Sample Prep: film/MTL/KRS-5
CAS Number: 0-00-0
Cocoamidopropyl hydroxys ultaine
Match:62.82

%T
50 Trade Name: Scher Chemicals Inc. Schercotaine SCAB

Poly(g-benzyl-L-glutamate)
Match:62.71

%T
50 Molecular Formula:
Sample Prep: film/CLF/CsI
CAS Number: 0-00-0

NYLON
Match:61.14
%T 50 Trade Name:
Supplier: BADISCHE (BASF)
Fiber Number: A0162

Poly(5-methylcaprolac tam)
Match:60.48
%T

50 Molecular Formula:
Sample Prep: film//CsI
CAS Number: 0-00-0

3500 3000 2500 2000 1500 1000
Wavenumbers (cm-1)
Pig Hair

Pig hair shows two or three branches.
FTIR on Pig Hair and Polymers
 Adulteration and contamination of
non‐halal components are major
concern in food processing and
production.
CONCLUSION Development on methods of
detection adulteration are urgently
needed for halal food verification
and certification.
 These analytical methods have potential to be
utilised by halal food authorities responsible
for authentication of halal food such as JAKIM.
New analytical methods of analysis developed
by our research group is simple, rapid and
CONCLUSION reliable for detection of pork and lard in food
and other consumer products.
THANK YOU