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Associative Evidence

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Associative Evidence

Associative evidence originates from contact between

  • people,
  • objects,
  • people and objects.

Associative evidence can be used to provide links between evidence and individuals involved in a crime. In some cases, the associative evidence (e.g., fingerprints or DNA) may be sufficient to prove the contact. In other cases, the associative evidence may be less definitive and provide corroboration of other evidence.

Examples of Associative Evidence

From top to bottom: broken glass, hair, fingerprint
From top to bottom: broken glass, hair, fingerprint
National Institute of Justice (NIJ) (see reuse policy).

Examples of associative evidence include

  • latent fingerprints left on an object,
  • fibers left from contact of clothing with objects,
  • blood from physical injury,
  • semen from sexual assault,
  • saliva from spitting, cigarettes, or envelopes,
  • hair shed at a scene,
  • paint transferred during a burglary or automobile accident,
  • glass transferred during a burglary or from a bottle used as a weapon,
  • soil from a scene,
  • impressions from tools, footwear, or tire.

Value of Associative Evidence

The value of associative evidence depends on four factors:

  • The specificity or degree of identity of the evidence
  • The frequency of occurrence
  • The persistence of the transferred material
  • The likelihood of alternate explanations

Specificity

Unique DNA sequence. The side-by-side arrangement of bases along the DNA strand (e.g., ATTCCGGA).
Unique DNA sequence. The side-by-side arrangement of bases along the DNA strand (e.g., ATTCCGGA).
Image courtesy of the U.S. Department of Energy Human Genome Program http://www.ornl.gov/hgmis (see reuse policy).

The value of associative evidence in regard to specificity or identity can be illustrated with a comparison of blood versus glass evidence.

Blood can be identified using DNA analysis. The typical DNA testing procedure results in the identification of the chemical composition at each of thirteen different locations on a DNA molecule. Every DNA molecule in the body of an individual will have the same composition at these sites. A reported DNA profile is therefore a specific description of a persons DNA.

In contrast, there are minute differences in the physical and trace chemical properties of a sheet of glass. Testing fragments from the glass sheet will reflect the variations in these properties; these variations will be greater in fragments originating in different locations across the same sheet of glass. The differences are small, but they do result in some uncertainty as to the absolute identity of the material tested and therefore the true value of the associative evidence.

Frequency of Occurrence

The significance of associative evidence also depends on the frequency of occurrence of the measured attribute in the environment.

For example, the frequency in various human populations (Caucasian, Negroid, Mongoloid, etc.) of the DNA composition at each of the thirteen locations (known as the thirteen core loci) has been measured. The frequency of the full profile in the population as a whole can therefore be calculated. The accepted process for doing this and deriving a numerical description of the rarity of the DNA profile is complex, but, in essence, a DNA profile from the thirteen core loci is unique (other than for identical twins).

In contrast to the biological diversity between individuals, the tight quality control of the manufacturing of glass would lead us to expect a high degree of similarity in the physical and chemical properties of glass produced in a single batch. However, batch-to-batch variation and the small within-batch differences referred to previously mean that it has not been possible to establish population databases for glass that are as useful as those for DNA.

Most Common Allele Frequencies in the FBI Caucasian Database
STR
Marker
# of
Alleles
Random Match Probability
(FBI Caucasian)
CSF1PO 11 0.112
FGA 19 0.039
TH01 7 0.081
TPOX 7 0.195
VWA 10 0.062
D3S1358 10 0.075
D5S818 10 0.158
D7S820 11 0.065
D8S1179 10 0.067
D13S317 8 0.085
D16S539 8 0.089
D18S51 15 0.028
D21S11 20 0.039
  Product 0.000000000000001683
  One in 594,059,679,247,540
    1 in 594 trillion

Persistence

Some associative evidence, such as latent prints and biological fluids, can be detected for a considerable time after deposition. Other types of evidence, such as hairs, glass, and fibers, are transferred to the receiving object and are shed over a relatively short period of time. The main issue to bear in mind is that no conclusion can be drawn from the absence of detected associative evidence targets.

Alternate Explanations

The question may be posed as Could it be that my DNA matches the target profile by chance? and the known population frequencies can be used to provide the answer.

Other alternate explanation scenarios are more difficult to deal with, for example:

  • Semen resulting from intercourse by consent, in contrast to rape
  • Blood transferred in the course of giving assistance to an injured person
  • A fingerprint deposited innocently at the location some time prior to the crime

 

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