June 28, 2011

Saliva Can Reveal Person's Age

Geneticists of University of California, Los Angeles, have developed a new saliva test which can accurately predict a person's age. 


A newly patented test based on the research, for example, could offer crime-scene investigators a new forensic tool for pinpointing a suspect's age.

"Our approach supplies one answer to the enduring quest for reliable markers of aging," said principal investigator Dr. Eric Vilain, a professor of human genetics, pediatrics and urology at the David Geffen School of Medicine at UCLA.

"With just a saliva sample, we can accurately predict a person's age without knowing anything else about them," he added.

Vilain and his colleagues looked at a process called methylation - a chemical modification of one of the four building blocks that make up our DNA.

"While genes partly shape how our body ages, environmental influences also can change our DNA as we age," explained Vilain.

"Methylation patterns shift as we grow older and contribute to aging-related disease," he added.

"Methylation's relationship with age is so strong that we can identify how old someone is by examining just two of the 3 billion building blocks that make up our genome," said first author Sven Bocklandt, a former UCLA geneticist now at Bioline.

The study has been published in the online edition of the Public Library of Science (PLoS) ONE


Source-ANI

June 17, 2011

Forensic Human identification

People can be identified by their fingerprints. This assertion is supported by the philosophy of friction ridge identification, which states that "Friction ridge identification is established through the agreement of friction ridge formations, in sequence, having sufficient uniqueness to individualize".

Friction ridge identification is also governed by four premises or statements of fact:

   1. Friction ridges develop on the fetus in their definitive form prior to birth.
   2. Friction ridges are persistent throughout life except for permanent scarring, disease or decomposition after death.
   3. Friction ridge paths and the details in small areas of friction ridges are unique and never repeated.
   4. Overall, friction ridge patterns vary within limits which allow for classification.

People can also be identified from traces of their DNA by DNA fingerprinting, from their teeth or bite by forensic odontology, from a photograph or a video recording by facial recognition systems, from the video recording of their walk by gait analysis, from an audio recording by voice analysis, from their handwriting by handwriting analysis, from the content of their writings by their writing style (e.g. typical phrases, factual bias, and/or misspellings of words), or from other traces using other biometric techniques.

Body identification is a subfield of forensics concerned with identify someone from their remains.


Body identification is a subfield of forensic science wherein investigators need to identify a body. Forensic (literally, "for the courts") purposes are served by rigorous scientific forensic identification techniques, but these are generally preceded by simply asking bystanders or other persons for the victim's name.

If a body is not badly decomposed or damaged, two persons (or one) who knew the deceased well should visually confirm the identity.

Authorities will also compare supportive documents such as driver's license, passport, or other authoritative photo ID before accepting a personal identification with which to further their investigative and/or forensic purposes.

Of course, any formal investigation should "reality check" additional forensic and scientific evidence to reinforce or question the supposed identity of the victim. Reliable identification becomes increasingly difficult as time passes.

 SOURCE : WIKIPEDIA

 IMPORTANT LINKS:

Forensic Human Identification Course



June 11, 2011

Forensic geology- By Raymond C. Murray

The use of geological materials as trace evidence in criminal cases has existed for approximately one hundred years.  Murray (2004) provides an overview and reminds us that it began, as with so many of the other types of evidence, with the writings of Sir Arthur Conan Doyle.  Doyle wrote the Sherlock Holmes series between 1887 and 1927.  He was a physician who apparently had two motives: writing salable literature and using his scientific expertise to encourage the use of science as evidence (Murray and Tedrow 1992).  In 1893 Hans Gross wrote his book Handbook for Examining Magistrates in which he suggested that perhaps one could tell more about where someone had last been from the dirt on their shoes than from toilsome inquiries.  A German chemist, Georg Popp, in 1908 examined the evidence in the Margarethe Filbert case.  In this homicide a suspect had been identified by many of his neighbours and friends because he was known to be a poacher.  The suspect's wife testified that she had dutifully cleaned his dress shoes the day before the crime.  Those shoes had three layers of soil adhering to the leather in front of the heel.  Popp, using the methods available at that time, said that the uppermost layer, thus the oldest, contained goose droppings and other earth materials that compared with samples in the walk outside the suspect's home.  The second layer contained red sandstone fragments and other particles that compared with samples from the scene where the body had been found.  The lowest layer, thus the youngest, contained brick, coal dust, cement and a whole series of other materials that compared with samples from a location outside a castle where the suspect's gun and clothing had been found.  The suspect said that he had walked only in his fields on the day of the crime. Those fields were underlain by porphyry with milky quartz.  Popp found no such material on the shoe although the soil had been wet on that day.  In this case, Popp had developed most of the elements involved in present day forensic soil examination.  He had compared two sets of samples and identified them with two of the scenes associated with the crime.  He had confirmed a sequence of events consistent with the theory of the crime and he had found no evidence supporting the alibi.    

           

Rocks, minerals, soils and related materials have evidential value.  The value lies in the almost unlimited number of kinds of materials and the large number of measurements and observations that we can make on these materials.  For example, the number of sizes and size distributions of grains combined with colors, shapes and mineralogy is almost unlimited.  There are an almost unlimited number of kinds of minerals, rocks, and fossils.  These are identifiable, recognizable, and can be characterized.  It is this diversity in earth materials, combined with the ability to measure and observe the different kinds, which provides the forensic discriminating power.
There have been many contributions to the discipline over the last 100 years.  Many have been made by the Laboratory of the Federal Bureau of Investigation, in Washington D C., McCrone Associates in Chicago, The Centre for Forensic Sciences in Toronto, Microtrace in Elgin, Illinois, the former Central Research Establishment at Aldermaston,  Kenneth Pye Associates Ltd in Great Britain, The Japanese National Research Institute of Police Science, The Netherlands Forensic Institute, as well as other government, private and academic researchers.
Because much of the evidential value of earth materials lies in the diversity and the differences in the minerals and particles, microscopic examination at all levels of instrumentation is the most powerful tool.  In addition, such examination provides an opportunity to search for man-made artifact grains and other kinds of physical evidence.
Individualization, that is, uniquely associating samples, from the crime scene with those of the suspect to the exclusion of all other samples is not possible in most cases. In this sense earth material evidence is not similar to DNA, fingerprints and some forms of firearms and tool mark evidence.  However, in a South Dakota homicide case, soil from the scene where the body was found and from the suspect’s vehicle both contained similar material including grains of the zinc spinel gahnite. This mineral had never before been reported from South Dakota.  Such evidence provides a very high level of confidence and reliability.
One of the most interesting types of studies is the aid to an investigation.  There are many examples of cases where a valuable cargo in transit is removed and rocks or bags of sand of the same weight are substituted.  If the original source of the rocks or sand can be determined, then the investigation can be focused at that place.  In a high visibility case, DEA agent Enrique Camarena was murdered in Mexico (McPhee 1997).  His body was exhumed as part of a cover-up staged by members of the Mexican Federal Judicial Police.  When the body was found later, it contained rock fragments that were different from the country rock at that place and represented the rocks from the original burial site.  With the combination of petrographic examination of those rocks and a detailed literature search of Mexican volcanic rock descriptions, the original burial location was found and the cover-up exposed.
Most examinations involve comparison.  Comparison aims to establish a high probability that two samples have a common source, or conversely that they do not have similar properties and thus are unlikely to have come from the same source.  In comparison studies of soils, it is difficult to overestimate the value of findings artifacts in the soil or some other unusual type of evidence.  In an Upper Michigan rape case, three flowerpots had been tipped over and spilled on the floor during the struggle.  It was shown that potting soil on the suspect's shoe had a high degree of similarity with a sample collected from the floor and represented soil from one of the pots.  In addition, small clippings of blue thread existed both in that flowerpot sample and on the shoe of the suspect.  The thread provided additional trace evidence which supplemented the soil evidence.
In a New Jersey rape case, the suspect had soil samples in the turn-ups of his trousers.  In addition to glacial sands grains that showed similarity with those in soil samples collected from the crime scene, the soil contained fragments of clean Pennsylvania anthracite. Such coal fragments are not uncommon in the soils of most of the older cities in eastern North America. However, in this sample there was too much coal when compared with samples collected in the surrounding area.  Further investigation showed that some 60 years earlier the crime scene had been the location of a coal pile for a coal burning laundry.  Again, the combining of soil-evidence with an investigation of an artifact and local industrial history increased the evidential value.
A new and evolving type of study is one done for the purpose of intelligence gathering. An example might involve identifying mineral material on an individual who had claimed to have recently been to a particular location.  In such a case the question would be asked whether the mineral material supports the claim and could have come from that location.  Identification of the mineral material alone can be useful in the case of mine fraud, gem fraud and art fraud by providing information that demonstrates the fraud.
The alertness of those who collect samples, and the quality of collection, is critical to the success of any examination.  If appropriate samples are not collected during the initial evidence gathering, they will never be studied and never provide assistance to the court.  There is the case in which an alert police officer happened to look at an individual arrested for a minor crime.  He observed, "that is the worst case of dandruff I have ever seen."  It was not dandruff but diatomaceous earth, which was essentially identical with the insulating material of a safe that had been broken into the previous day.
The future of Forensic Geology holds much promise.  However that future will see many changes and new opportunities. New methods are being developed that take advantage of the discriminating power inherent in earth materials.  Quantitative x-ray diffraction could possibly revolutionize forensic soil examination. When developed to the point that this or similar methods become routine laboratory techniques, it will be possible to do a quantitative mineralogical analysis that is easily reproducible. However, the microscope will remain an important tool in the search for the unusual grain or artifact.  Sampling methods, plus the thorough and complete training those people who collect samples for forensic purposes, will be improved.   Soils are extremely sensitive to change over short distances, both horizontally and vertically.  Soil sampling in many cases is the search for a sample that matches.  The collection of all the other samples serves only the purpose of demonstrating the range of local differences.  In collecting soil samples for comparison, we are searching for one that would have the possibility of matching.  Screening techniques applied during sampling that eliminate samples that are totally different are often appropriate.  For example, a surface sample offers little possibility of matching with material collected at a depth of four feet in a grave.
Studies that demonstrate the diversity of soils are important. One approach is to take an area that one would normally assume was fairly homogenous in its soil character and collect a hundred samples on a grid.  Each pair of samples would then be compared with each other until all the pairs are shown to be different.  Starting with colour and moving on to size distribution and mineralogy, different methods are used to eliminate all of these pairs as appearing similar. Junger (1996) performed several such studies and suggested methods for soil examination.
The qualifications and competence of examiners are a very major problem.  How do you learn to do forensic soil examinations?  This requires a thorough knowledge of mineralogy and the ability to effectively use a microscope and the other techniques used in earth material examina­tion. It is also important that examiners be familiar with the other kinds of trace evidence plus the law and practice of forensic examination.

 REFERENCES

Junger, E. P.  1996.  Assessing the Unique Characteristics of Close-Proximity Soil Samples: Just How Useful is Soil Evidence?  Journal of Forensic Sciences,  41  27-34.
 McPhee, J.  1997.  Irons in the Fire. Farrar, Straus and Giroux, New York.
 Murray, R.C. and Tedrow, J.  1992.  Forensic Geology. Prentice Hall, Englewood Cliffs, N.J.               
Murray, R. C. 2004, Evidence from the Earth, Mountain Press, Missoula, MT
Presented at the International Conference on forensic Geology, London, 2003

June 9, 2011

FORENSIC PALYNOLOGY

Pollen analysis begins in 1916 in Sweden with the concept that was first outlined by Lennart von Post

The key pollen evidence  from the Shroud focuses on four main types, all four are insect-pollinated:

Zygophyllum dunosum, Gundelia tournefortii, Cistus creticus and Capparis aegyptia

Pollen and spore production and dispersion are important considerations in the study of forensic palynology. First, if one knows what the expected production and dispersal patterns of spores and pollen (called the pollen rain) are for the plants in a given region, then one will know what type of "pollen fingerprint" to expect in samples that come from that area (Bryant, 1989). Therefore, the first task of the forensic palynologist is to try to find a match between the pollen in a known geographical region with the pollen in a forensic sample. Knowledge of pollen dispersal and productivity often plays a major role in solving such problems.
There are a number of different methods by which plants disperse their pollen or spores. Many aquatic angiosperms live completely submerged and release their pollen underwater, relying on water currents to transport the pollen from the male anther to the female stigma of a neighboring flower. This method of transport, like the wind, is a hit- and -miss method of pollination. For this reason these plants produce pollen types that consist only of a single-layered cellulose wall, the pollen is almost never preserved in sediments and generally oxidizes rapidly if removed from water. Because of these limitations, these types of pollen are of little potential value for forensic work.



Current Status of Forensic Pollen Use

The United Kingdom is currently the world leader in using forensic pollen routinely in a wide variety of criminal and terrorist investigations, training not offered at any university

It is now routine in most areas of the UK for a forensic palynologist (FP) to be the FIRST person to visit a crime scene & collect essential samples for study  Last year the leading Forensic Palynologist team in the UK
worked on over 60 criminal cases of all types  New Zealand is a co-leader in Forensic pollen studies, it has
been used routinely in criminal since the mid 1980s

 Australia, Canada, Europe, and even a few Asian countries are now using forensic palynology in criminal cases However, the skills and competency of forensic pollen ID & use in some regions of the world are questionable

A Rarely used Technique in the India
 
 Forensic pollen studies are very rarely attempted in the India.
Current problem in the India is that there are very few people who are trained to do forensic pollen studies
 Currently there is little demand for this service, this is why very few forensic labs currently use it
There are currently no jobs for those who might want to train as forensic palynologists.
Because of no jobs, there are very few training programs currently available for students interested in becoming forensic palynologists




June 2, 2011

Forensic seismology

Forensic seismology originated during the Cold War as a means of monitoring the enemy's underground nuclear tests. But it is a field whose uses are as broad as the imagination. 



FOR EXAMPLE:

Forensic Seismology Provides Clues To Kursk Disaster

ScienceDaily (Jan. 23, 2001) — WASHINGTON - The explosions that sank the Russian submarine Kursk on August 12, 2000, triggered shock waves that were recorded by a network of seismic stations in the Baltic region and beyond. Now, forensic seismologists have used these data to reconstruct the disaster. Writing in the January 23 issue of Eos, the weekly newspaper of the American Geophysical Union, Keith D. Koper and Terry C. Wallace of the University of Arizona and Steven R. Taylor and Hans E. Hartse of the Los Alamos National Laboratory report that, based on their analysis of seismograms, explosions, not impact, caused the Kursk to sink with the loss of all crew members.

The authors note that underwater explosions are highly efficient producers of seismic signals, and these have been long studied, including those generated by the sinking of a Soviet submarine in 1989. The Kursk seismic data possess features unique to underwater explosions, a strong indication that the Kursk did not sink because of a collision or other impact, they say.
Seismic stations recorded two explosions that correspond to the Kursk disaster in time and place. The first explosion was 250 times smaller than the second one, which occurred 135 seconds later. The earlier explosion was clearly recorded only at a few nearby stations, while the second one released energy equivalent to around five tons of TNT and was recorded up to 5,000 kilometers [3,100 miles] away. 

Koper and his colleagues note that this area of the Barents Sea rarely experiences any seismic activity, so it was highly unlikely that the seismic signals were caused by an earthquake. One point of careful analysis, they say, concerned whether the second event consisted of one massive explosion or several simultaneous smaller ones and perhaps also impact of the Kursk on the seafloor. 

The most compelling seismic evidence that the main Kursk event was dominated by an explosion was the observation of a "bubble pulse." This pulse results from oscillations of a bubble of hot gases unleashed by an explosion as it rises toward the surface. The spectral pattern produced by an underwater explosion and recorded by seismic stations provides strong evidence that the second explosion was one massive event, not several smaller ones. 

In another study, Wallace and Koper collaborated to use seismic data from Norway, Sweden, Finland, and Spitsbergen to reconstruct the sinking of the Russian submarine Kursk on 12 August 2000. 

When the sub sank, the Scandinavian seismometers showed two events a little more than two minutes apart. Underwater explosions produce bubbles of hot gases, which oscillate as they rise. 

The frequency of these oscillations depends on the size of the explosion and the depth at which it occurs. This allowed the scientists to determine that the Kursk was sunk by an explosion, not a collision, and that it had occurred when the sub was at a depth of 83 m. 

The first blast carried power equivalent to 250 kg of TNT; the second was several times larger. Wallace and Koper therefore suspected that the first was a torpedo misfire during live-fire exercises, which the Kursk was known to be undertaking at the time. The second, larger explosion, they believed, probably occurred when fire from the initial accident detonated additional warheads.
Shortly after the sinking, the seismograms revealed many other small seismic events, with magnitudes between 1.25 and 1.86. These appear to have been depth charges dropped by the Russians to discourage other nations from sending scuba divers to spy out the secrets of the stricken submarine. The seismic readings were so precise that Wallace and Koper could even track the speed and course of the naval vessel used to lay down the underwater barrage.


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