Forensic facial reconstruction explained

Forensic facial reconstruction (or forensic facial approximation) is the process of recreating the face of an individual (whose identity is often not known) from their skeletal remains through an amalgamation of artistry, anthropology, osteology, and anatomy. It is easily the most subjective—as well as one of the most controversial—techniques in the field of forensic anthropology. Despite this controversy, facial reconstruction has proved successful frequently enough that research and methodological developments continue to be advanced.

In addition to identification of unidentified decedents, facial reconstructions are created for remains believed to be of historical value and for remains of prehistoric hominids and humans.

Types of identification

There are two forms pertaining to identification in forensic anthropology: circumstantial and positive.[1]

Facial reconstruction presents investigators and family members involved in criminal cases concerning unidentified remains with a unique alternative when all other identification techniques have failed. Facial approximations often provide the stimuli that eventually lead to the positive identification of remains.

Legal admissibility

In the U.S., the Daubert Standard is a legal precedent set in 1993 by the Supreme Court regarding the admissibility of expert witness testimony during legal proceedings, set in place to ensure that expert testimony is based on sufficient facts or data, derived from proper application of reliable principles and methods.[3] When multiple forensic artists produce approximations for the same set of skeletal remains, no two reconstructions are ever the same and the data from which approximations are created are largely incomplete.[4] Because of this, forensic facial reconstruction does not uphold the Daubert Standard, is not considered a legally recognized technique for positive identification, and is not admissible as expert testimony. Currently, reconstructions are only produced to aid the process of positive identification in conjunction with verified methods.

Types of reconstructions

Two-dimensional reconstructions

Two-dimensional facial reconstructions are based on ante mortem photographs, and the skull. Occasionally skull radiographs are used but this is not ideal since many cranial structures are not visible or at the correct scale. This method usually requires the collaboration of an artist and a forensic anthropologist. A commonly used method of 2D facial reconstruction was pioneered by Karen T. Taylor of Austin, Texas during the 1980s.[5] Taylor's method involves adhering tissue depth markers on an unidentified skull at various anthropological landmarks, then photographing the skull. Life-size or one-to-one frontal and lateral photographic prints are then used as a foundation for facial drawings done on transparent vellum. Recently developed, the F.A.C.E. and C.A.R.E.S. computer software programs quickly produce two-dimensional facial approximations that can be edited and manipulated with relative ease. These programs may help speed the reconstruction process and allow subtle variations to be applied to the drawing, though they may produce more generic images than hand-drawn artwork.[6]

Three-dimensional reconstructions

Three-dimensional facial reconstructions are either: 1) sculptures (made from casts of cranial remains) created with modeling clay and other materials or 2) high-resolution, three-dimensional computer images. Like two-dimensional reconstructions, three-dimensional reconstructions usually require both an artist and a forensic anthropologist. Computer programs create three-dimensional reconstructions by manipulating scanned photographs of the unidentified cranial remains, stock photographs of facial features, and other available reconstructions. These computer approximations are usually most effective in victim identification because they do not appear too artificial. This method has been adopted by the National Center for Missing & Exploited Children, which uses this method often to show approximations of an unidentified decedent to release to the public in hopes to identify the subject.[7]

Superimposition

Superimposition is a technique that is sometimes included among the methods of forensic facial reconstruction. It is not always included as a technique because investigators must already have some kind of knowledge about the identity of the skeletal remains with which they are dealing (as opposed to 2D and 3D reconstructions, when the identity of the skeletal remains are generally completely unknown). Forensic superimpositions are created by superimposing a photograph of an individual suspected of belonging to the unidentified skeletal remains over an X-ray of the unidentified skull. If the skull and the photograph are of the same individual, then the anatomical features of the face should align accurately.[8]

Methods of Reconstruction

Different versions of Craniofacial Reconstruction have been used in multiple disciplines over the span of its discovery. Today, as stated, it is a technique used widely across the globe, that has proven to aid in forensic investigations by identifying victims of different crimes. Forensic experts will use their in depth knowledge of facial musculature and tissue attachments on the skull, in order to recreate the identity of the victim.[9] In order to do such, it is important to consider the appearance of the skull, its soft tissues attached as well as its corresponding scans (X-Ray, CT Scans, ultrasound).[10] As stated above, Craniofacial Reconstruction was performed manually, using clay in 2D and 3D aspects. However, today, technology is able to assist in this reconstruction, with the help of 3 similar but different techniques; the Russian Method, the American Method and the Manchester Method.

The Russian Method is a method of craniofacial reconstruction that uses the musculature of the skull. This method uses a clay-like substance to recreate the musculature of the victim’s skull and focuses on the insertion of the muscles to the skull. The American Method is a second method of reconstruction however, this technique focuses on the overlying tissue of the skull. This method requires the facial tissue depth data recorded from previous remains or from live patients, using tissue puncture markers and/or ultrasounds. This technique can display the differences between the reconstruction of remains, based on factors such as race, sex and age. The Manchester Method is a combination of the Russian Method and the American Method. It uses the musculature of the skull as well as tissue depth markers and landmarks, in order to execute the reconstruction, and it is found to be the technique that is most commonly used today.

History

Hermann Welcker in 1883 and Wilhelm His, Sr. in 1895, were the first to reproduce three-dimensional facial approximations from cranial remains.[11] Most sources, however, acknowledge His as the forerunner in advancing the technique. His also produced the first data on average facial tissue thickness followed by Kollmann and Buchly who later collected additional data and compiled tables that are still referenced in most laboratories working on facial reproductions today.[12]

Facial reconstruction originated in two of the four major subfields of anthropology. In biological anthropology, they were used to approximate the appearance of early hominid forms, while in archaeology they were used to validate the remains of historic figures. In 1936, Rose Koller from the Natural History Museum in Vienna led a team of sculptors at the Smithsonian Institution's Anthropological Department in recreating likenesses of "ancient Austrians" from their skulls.[13] In 1964, Mikhail Gerasimov used paleo-anthropological facial reconstruction to estimate the appearance of ancient peoples[14]

Although students of Gerasimov later used his techniques to aid in criminal investigations, it was Wilton M. Krogman who popularized facial reconstruction's application to the forensic field. Krogman presented his method for facial reconstruction in his 1962 book, detailing his method for approximation.[14] Others who helped popularize three-dimensional facial reconstruction include Cherry (1977), Angel (1977), Gatliff (1984), Snow (1979), and Iscan (1986).

In 2004 it was for Dr. Andrew Nelson of the University of Western Ontario, Department of Anthropology that noted Canadian artist Christian Corbet created the first forensic facial reconstruction of an approximately 2,200-year-old mummy based on CT and laser scans. This reconstruction is known as the Sulman Mummy project.

Technique for creating a three-dimensional clay reconstruction

Because a standard method for creating three-dimensional forensic facial reconstructions has not been widely agreed upon, multiple methods and techniques are used. The process detailed below reflects the method presented by Taylor and Angel from their chapter in Craniofacial Identification in Forensic Medicine, pgs 177–185.[15] This method assumes that the sex, age, and race of the remains to undergo facial reconstruction have already been determined through traditional forensic anthropological techniques.

The skull is the basis of facial reconstruction; however, other physical remains that are sometimes available often prove to be valuable. Occasionally, remnants of soft tissue are found on a set of remains. Through close inspection, the forensic artist can easily approximate the thickness of the soft tissue over the remaining areas of the skull based on the presence of these tissues. This eliminates one of the most difficult aspects of reconstruction, the estimation of tissue thickness. Additionally, any other bodily or physical evidence found in association with remains (e.g. jewelry, hair, glasses, etc.) are vital to the final stages of reconstruction because they directly reflect the appearance of the individual in question.

Most commonly, however, only the bony skull and minimal or no other soft tissues are present on the remains presented to forensic artists. In this case, a thorough examination of the skull is completed. This examination focuses on, but is not limited to, the identification of any bony pathologies or unusual landmarks, ruggedness of muscle attachments, profile of the mandible, symmetry of the nasal bones, dentition, and wear of the occlusal surfaces. All of these features have an effect on the appearance of an individual's face.

Once the examination is complete, the skull is cleaned and any damaged or fragmented areas are repaired with wax. The mandible is then reattached, again with wax, according to the alignment of teeth, or, if no teeth are present, by averaging the vertical dimensions between the mandible and maxilla. Undercuts (like the nasal openings) are filled in with modeling clay and prosthetic eyes are inserted into the orbits centered between the superior and inferior orbital rims. At this point, a plaster cast of the skull is prepared. Extensive detail of the preparation of such a cast is presented in the article from which these methods are presented.

After the cast is set, colored plastics or the colored ends of safety matches are attached at twenty-one specific "landmark" areas that correspond to the reference data. These sites represent the average facial tissue thickness for persons of the same sex, race, and age as that of the remains. From this point on, all features are added using modeling clay.

First, the facial muscles are layered onto the cast in the following order: temporalis, masseter, buccinator and occipito-frontals, and finally the soft tissues of the neck. Next, the nose and lips are reconstructed before any of the other muscles are formed. The lips are approximately as wide as the interpupillary distance. However, this distance varies significantly with age, sex, race, and occlusion. The nose is one of the most difficult facial features to reconstruct because the underlying bone is limited and the possibility of variation is expansive. The nasal profile is constructed by first measuring the width of the nasal aperture and the nasal spine. Using a calculation of three times the length of the spine plus the depth of tissue marker number five will yield the approximate nose length. Next, the pitch of the nose is determined by examining the direction of the nasal spine – down, flat, or up. A block of clay that is the proper length is then placed on the nasal spine and the remaining nasal tissue is filled in using tissue markers two and three as a guide for the bridge of the nose. The alae are created by first marking a point five millimeters below the bottom of the nasal aperture. After the main part of the nose is constructed, the alae are created as small egg-shaped balls of clay, that are five millimeters in diameter at the widest point, these are positioned on the sides of the nose corresponding with the mark made previously. The alae are then blended to the nose and the overall structure of the nose is rounded out and shaped appropriately.

The muscles of facial expression and the soft tissue around the eyes are added next. Additional measurements are made according to race (especially for those with eye folds characteristic of Asian descent) during this stage. Next, tissues are built up to within one millimeter of the tissue thickness markers and the ears (noted as being extremely complicated to reproduce) are added. Finally, the face is "fleshed," meaning clay is added until the tissue thickness markers are covered, and any specific characterization is added (for example, hair, wrinkles in the skin, noted racial traits, glasses, etc.). The skull of Mozart was the basis of his facial reconstruction from anthropological data. The bust was unveiled at the "Salon du Son", Paris, in 1991.[16]

Problems with facial reconstruction

There are multiple outstanding problems associated with forensic facial reconstruction.[17]

Insufficient tissue thickness data

The most pressing issue relates to the data used to average facial tissue thickness. The data available to forensic artists are still very limited in ranges of ages, sexes, and body builds. This disparity greatly affects the accuracy of reconstructions. Until this data is expanded, the likelihood of producing the most accurate reconstruction possible is largely limited.[18]

Lack of methodological standardization

A second problem is the lack of a methodological standardization in approximating facial features. A single, official method for reconstructing the face has yet to be recognized. This also presents major setback in facial approximation because facial features like the eyes and nose and individuating characteristics like hairstyle – the features most likely to be recalled by witnesses – lack a standard way of being reconstructed. Recent research on computer-assisted methods, which take advantage of digital image processing, pattern recognition, promises to overcome current limitations in facial reconstruction and linkage.[19]

Subjectivity

Reconstructions only reveal the type of face a person may have exhibited because of artistic subjectivity. Soft tissue reconstruction is an approximation based on osteological measurements; therefore, distinguishing characteristics used in identification could be missed.[20] The position and general shape of the main facial features are mostly accurate because they are greatly determined by the skull.[21]

Neolithic dog's head forensic reconstruction

An image of the forensic model of a Neolithic dog skull found at Cuween Hill Chambered Cairn, Orkney, Scotland was published by Sci-News.com on April 22, 2019.

Forensic artist Amy Thornton made a model of the dog's head using a 3D print, based on a CT scan made at the Royal (Dick) School of Veterinary Studies of one of the 24 canine skulls found at the site.

According to Dr. Alison Sheridan, Principal Archaeological Research Curator in the Department of Scottish History and Archaeology at National Museums Scotland, "The size of a large collie, and with features reminiscent of that of a European grey wolf, the Cuween dog has much to tell us ... While reconstructions have previously been made of people from the Neolithic era, we do not know of any previous attempt to forensically reconstruct an animal from this time."[22]

In popular culture

In recent years, the presence of forensic facial reconstructions in the entertainment industry and the media has increased. The way the fictional criminal investigators and forensic anthropologists utilize forensics and facial reconstructions are, however, often misrepresented[23] (an influence known as the "CSI effect"). For example, the fictional forensic investigators will often call for the creation of a facial reconstruction as soon as a set of skeletal remains is discovered. In many instances, facial reconstructions have been used as a last resort to stimulate the possibility of identifying an individual.[24]

Facial reconstruction has been featured as part of an array of forensic science methods in fictional TV shows like and NCIS and their respective spinoffs in the CSI and NCIS franchises.

In Bones, a long-running TV series centered around forensic analysis of decomposed and skeletal human remains, facial reconstruction is featured in the majority of episodes, used much like a police artist sketch in police procedurals. Regular cast character Angela Montenegro, the Bones team's facial reconstruction specialist, employs 3D software and holographic projection to "give victims back their faces" (as noted in the episode, "A Boy in a Bush").

In the MacGyver episode "The Secret of Parker House", MacGyver reconstructs the skull of Penny's aunt Betty while investigating her house.

The facial reconstruction of Egypt's Tutankhamun, popularly known as King Tut, made the June 2005 cover of National Geographic.

A variety of facial reconstruction kit toys are available, with "crime scene" versions, also, reconstructions of famous historical figures, like Tutankhamen and the dinosaur Tyrannosaurus rex.

Recently, facial reconstruction has been part of the process used by researchers attempting to identify human remains of two Canadian Army soldiers lost in World War I. One soldier sculpted by Christian Corbet was identified through DNA analysis in 2007, but due to DNA deterioration, identifying the second using the same techniques failed. In 2011, the second of the soldiers' remains discovered at Avion, France were identified through a combination of 3-D printing software, reconstructive sculpture and use of isotopic analysis of bone.[25] [26]

Further reading

External links

Notes and References

  1. Burns. Forensic Anthropology Training Manual.
  2. Reichs and Craig. Facial Approximation: Procedures and Pitfalls.
  3. Steadman
  4. Helmer et al. Assessment of the Reliability of Facial Reconstruction.
  5. Dowling, Paul. "Saving Face." Forensic Files. Prod. Paul Bourdett and Vince Sherry. Dir. Michael Jordan. 28 Nov. 2007. Television.
  6. Reichs and Craig
  7. Web site: Unidentified murder victim a 'total nightmare' case for detectives. 9 July 2015. Adam. Rodewald. 5 August 2013. dead. https://web.archive.org/web/20150714184728/http://www.fdlreporter.com/article/20130804/FON019804/308040064/Unidentified-murder-victim-total-nightmare-case-detectives. 14 July 2015.
  8. Lundy. Physical Anthropology In Forensic Medicine
  9. Deng . Qingqiong . Zhou . Mingquan . Shui . Wuyang . Wu . Zhongke . Ji . Yuan . Bai . Ruyi . 2011-05-20 . A novel skull registration based on global and local deformations for craniofacial reconstruction . Forensic Science International . en . 208 . 1 . 95–102 . 10.1016/j.forsciint.2010.11.011 . 21185136 . 0379-0738.
  10. Shrimpton . Sarah . Daniels . Katleen . de Greef . Sven . Tilotta . Francoise . Willems . Guy . Vandermeulen . Dirk . Suetens . Paul . Claes . Peter . 2014-01-01 . A spatially-dense regression study of facial form and tissue depth: Towards an interactive tool for craniofacial reconstruction . Forensic Science International . en . 234 . 103–110 . 10.1016/j.forsciint.2013.10.021 . 24378309 . 0379-0738.
  11. Forensic Facial Reconstruction: The Final Frontier
  12. Rhine. Facial Reproductions In Court.
  13. News: Thone . Frank . Ancestral Portraits . 24 March 2024 . Science News Letter . 797 . Society for Science & the Public . July 18, 1936.
  14. Iscan, M.Y. (Mehmet Yasar). Craniofacial Image Analysis and Reconstruction.
  15. Taylor and Angel. Facial Reconstruction and Approximation.
  16. Forensic scientists uncovering Mozart . 1293314 . 2061918 . 84 . 6 . 1991 . J R Soc Med . 387 . Puech PF . 10.1177/014107689108400646.
  17. Lebedinskaya et al. Principles of Facial Reconstruction.
  18. Rathbun. Personal Identification: Facial Reproductions.
  19. Web site: 2016-10-17 . Evolution is *NOT* Progressive . 2022-02-28 . NotPoliticallyCorrect . en.
  20. Wilkinson . Caroline . Facial reconstruction – anatomical art or artistic anatomy? . Journal of Anatomy . 2010 . 216 . 2 . 235–250 . 10.1111/j.1469-7580.2009.01182.x . 0021-8782 . 2815945 . 20447245.
  21. Helmer et al.
  22. http://www.sci-news.com/archaeology/neolithic-dog-07115.html Scientists Reconstruct Face of Neolithic Dog | Archaeology | Sci-News.com
  23. Web site: Croom. Nicole. 2014-04-17. The CSI Effect: Science 'As Seen on TV'. 2022-02-02. synapse.ucsf.edu. en.
  24. Studies in Crime: An Introduction to Forensic Archaeology p. 129
  25. News: Where science meets art. Baird. Moira. June 4, 2011. The Telegram. Transcontinental Media. 23 June 2012.
  26. Web site: 3D Printing Technology Helped Identify Canadian WW1 Soldier. Quiring. Tami. March 22, 2011. Village Gamer. 23 June 2012. Aldergrove, British Columbia.