Beyond the visible spectrum – applying 3D multispectral full-body imaging to the VirtoScan system

In postmortem forensic examinations, digital photography is most commonly utilized to capture the visible (VIS) part of the electromagnetic spectrum. As a result, the findings are documented in the same way they were perceived by the human eye at the time of the examination. Therefore, it is not surprising that textures used for three-dimensional (3D) surface documentation are usually also captured within the VIS spectrum [1‐24]. However, the literature shows a variety of possible applications of forensic photography on either side of the VIS part of the electromagnetic spectrum and with the help of narrowband light sources.

The VIS part of the electromagnetic spectrum (i.e. visible light or visible radiation) lies between a lower limit of approximately 360 and 400 nm (nm) and an upper limit of approximately 760 and 830 nm [25]. Ultraviolet (UV) radiation is characterized by wavelengths shorter than those of VIS light, ranging from 100 to 400 nm [25]. In contrast, near-infrared (NIR) radiation (also referred to as IR-A) is characterized by wavelengths longer than those of VIS light. NIR radiation ranges from approximately 780 nm to 1400 nm [25]. When electromagnetic radiation within the range from UV to NIR hits matter, it is reflected or refracted at the surface. The refracted electromagnetic radiation is scattered and re-emitted or absorbed. When UV radiation is absorbed by matter and causes excitation of a molecule, the stored energy is re-emitted as electromagnetic radiation with a longer wavelength as soon as the molecule relaxes. The difference between the band maxima of the absorption and emission spectra is known as the Stokes shift [26‐28]. When only emission occurs, as long as the UV-emitting light source is switched on, the emission is referred to as fluorescence. This behavior is used for UV-induced fluorescence photography.

Within the field of forensic medicine and pathology, one of the applications most commonly associated with multispectral photography is the detection and visualization of latent bruises and injuries [29‐43]. Some articles have reported the usefulness of multispectral photography for the detection and documentation of occult bruises in children [30, 35, 37, 42, 43] and adults [32, 35, 37, 41]. In addition, some studies have specifically referred to the use of multispectral photography to visualize and analyze bite marks [31, 33] and bruises in connection with strangulation [34]. In addition to its application in the investigation of bite marks, multispectral photography has been used in various areas in forensic odontology. For example, multispectral photography has been used to detect and visualize dental restorations [44‐46] and to investigate the age-dependent properties of dental fluorescence [47]. Another topic linked to multispectral photography is the detection and visualization of bodily fluids. Some studies have investigated the potential of different wavelengths to allow bodily fluids to be distinguished from other substances, such as liquids, gels and ointments [48‐50]. Furthermore, studies and case reports have described the usefulness of different wavelengths to visualize latent bodily fluids on textiles [48, 49, 51] and human skin [48, 50, 52‐54]. UV fluorescence has been applied to detect cryptic skin particles on various materials [55]. NIR photography has the potential to detect and visualize tattoo ink on human skin after advanced decomposition [31, 41, 56‐61]. This application has been shown to assist in the successful identification of the deceased [58, 59, 61]. Furthermore, multispectral photography has been used to investigate tattoo modifications and to determine whether tattoos were used to cover older tattoo designs [62, 63]. Additionally, NIR imaging has been shown to improve the visualization of vein patterns in the human body [64‐69]. For example, images showing palm vein and palm dorsum vein patterns have been used for biometric verification and human identification [65, 66, 69, 70].

In summary, the main goal of multispectral imaging in a forensic context is to detect, enhance, visualize and document latent evidence that is barely perceptible or invisible to the human eye. The greatest challenge for multispectral imaging is locating the evidence, since it can easily be overlooked. The search can be time consuming, especially when it involves large and complicated surfaces such as those of an entire body. Moreover, the need to use a range of spectra can prolong the procedure. Since time is a critical factor in any forensic investigation, the use of fast 3D multispectral imaging could be of help, as it would require the use of the body only for the duration of multispectral 3D documentation. Immediately thereafter, the body would be available for other examinations while the search for latent evidence is conducted digitally. A digital 3D model allows interaction with and navigation through the data, which can facilitate locating latent evidence and contribute to a better understanding of the dataset and its spatial relationships [71]. In addition, 3D data can be used to acquire measurements on the body [14, 18, 19, 22]. Finally, 3D data can be used for 3D reconstructions of crime and accident scenes [6, 7, 9, 24] to perform matching between an injury and an injury-causing object [1‐5, 71].

However, it seems that the benefits of 3D multispectral imaging are not yet well known, as this technique has not been widely used in forensic investigations. To the best of our knowledge, there is only one publication to date reporting the potential use of 3D multispectral photogrammetry for forensic investigations at the crime scene. In that publication, Edelman and Aalders [72] describe a method for close-range, single-camera, thermal, multispectral and hyperspectral photogrammetry for crime scene documentation. Studies regarding the use of 3D multispectral imaging for forensic-medical full-body examinations seem to be absent in the scientific literature.

To address this absence, we aimed to develop an automated, fast and cost-effective multispectral 3D imaging system for postmortem examinations. The objective of this study was to investigate the feasibility of performing semiautomatic 3D multispectral full-body documentation using photogrammetry. Furthermore, we aimed to investigate whether 3D surface documentation beyond the VIS spectrum could provide information beyond that acquired by standard postmortem 3D surface documentation within the VIS spectrum. We used NIR illumination for imaging solely in the NIR range and UV illumination for imaging in the VIS to NIR range (referred to as UV-induced UV-I imaging in this study).

An imaging protocol for 3D multispectral full-body imaging was used to document four exemplary forensic cases. For each case, five photogrammetric datasets were recorded. Altogether, 20 photogrammetric datasets were included in this study. On average, image acquisition for the entire body took approximately 5 min for the UV-I image series and approximately 3 min for each of the VIS or NIR image series.

In this study, a method for fast 3D multispectral full-body imaging was developed. Photogrammetric datasets were acquired semi automatically in conjunction with the use of a medical CT scanner. Furthermore, a workflow to produce textured 3D models based on multispectral image data using a popular type of photogrammetry software was presented. The data quality of 3D reconstructions based on four example cases was analyzed. Additionally, features on the body surface that showed apparent disparities among the VIS, UV-I and NIR datasets were evaluated.

All of the acquired datasets were reconstructed successfully with the help of Agisoft Metashape Professional. The results showed that the 3D reconstructions varied in quality and level of detail depending on the spectral range of the image data. The 3D reconstructions of the UV-I and VIS datasets seemed to perform comparably well. Based on visual comparison, the 3D mesh representations exhibited a similar level of detail. In contrast, the 3D reconstructions of the NIR datasets generally showed a lower level of detail. The corresponding 3D models showed noisy 3D mesh representations featuring rough surfaces. This observation was most likely due to the characteristics of NIR radiation and its representation in the NIR images. The NIR images in this study mainly displayed body hair, vein patterns and injuries. In addition, the bodies in the NIR images had a largely homogenous texture. Such a texture is impractical for photogrammetric reconstructions that require non-uniform surfaces with sufficient texture information. Hence, 3D reconstructions based on NIR images exhibited noisy surfaces that contributed to a generally lower level of detail.

Generally, Agisoft Metashape Professional offers functionalities for datasets and image stacks based on multiple wavelengths [72]. However, the setup used in this study could not guarantee that the camera positions and angles remained unchanged throughout the imaging procedure. It is possible that positions and angles were modified slightly during the manual replacement of the filters and the light sources. For this reason, the 3D reconstructions were calculated separately for each dataset rather than mapping different textures onto one selected 3D reconstruction.

In addition to the analyses of the 3D reconstructions, comparisons between the NIR and UV-I datasets and the VIS datasets were performed to identify features specific to the former. These features attracted attention during the first inspection of the multispectral datasets and were used as exemplary findings to illustrate the potential benefits of multispectral 3D imaging. The NIR datasets showed an enhanced visibility of vein patterns. Furthermore, injuries and bruises that presumably were located deeper in the tissue showed noticeable contrast in the NIR datasets. In contrast, signs of subtle bruising on the skin could not be detected in the NIR datasets. The UV-I datasets showed enhanced visibility of foreign substances on the skin. These substances appeared to be antiseptic cleansing agents, adhesives and bodily fluids. Overall, these findings seem consistent with the scientific literature. However, debate about the validity of UV, NIR, and narrowband light sources, especially for diagnosing latent and subtle bruising, appears ongoing [36, 38‐40]. To gain a deeper understanding of the validity of different light sources, further analysis is necessary. Such analysis is beyond the scope of the present study. The demonstration of potential benefits of multispectral imaging in this study was based solely on visual comparisons among 3D models of multispectral datasets. These findings were not investigated in detail.

This study demonstrated the possibility of using multispectral photogrammetry for postmortem full-body documentation. Furthermore, it highlighted some of the benefits of 3D UV-I and NIR imaging compared to standard postmortem 3D surface documentation. The imaging setup used in this study was designed based on our experience in our previous projects [13, 15, 20]. In this study, the total number of cameras was reduced to a minimum to introduce an affordable and low-cost approach for 3D multispectral full-body imaging. The setup and the imaging workflow were employed in this study in conjunction with the use of a medical CT scanner. This approach allows the 3D data to be aligned and merged with the corresponding CT data [6, 7, 10, 16, 24]. However, the system is not limited to use in combination with CT scanners. The multicamera rig is movable and can be used to capture photogrammetric datasets in combination with autopsy tables, lifting carts, examination couches and potentially even hospital beds to document postmortem and antemortem cases. The multicamera approach not only facilitates and automates the imaging procedure but also contributes to reproducibility. Furthermore, it allows the implementation of multispectral photogrammetry with similar camera angles and camera positions throughout the entire spectral range. These features enable the user to compare and analyze multispectral data in both 3D and raw form (i.e., 2D photographs). Overall, finding and documenting evidence is key for any forensic investigation. With the help of fast 3D multispectral full-body imaging, the detection of latent evidence can be achieved digitally to reduce the examination time of the body. Furthermore, 3D multispectral full-body imaging allows the storage and preservation of forensically relevant information on the entire body.

The presented setup is a prototype and has not yet been used in routine investigations. Currently, the manual replacement of light sources and lens filters demands manual adjustments and requires the training of personnel to use the system. Furthermore, an improved workflow for multispectral white balancing would help improve the data. In addition to addressing the technical aspects of the imaging setup, future studies should endeavor to include a larger and more diverse set of example cases. Moreover, to further investigate the potential of NIR and UV-I imaging, future projects should include additional methods to analyze the findings.

In this study, a multicamera setup based on four modified DSLR cameras was designed that can be used in conjunction with a medical CT scanner to semi automatically perform full-body photogrammetry. The use of NIR and UV light sources in combination with appropriate lens filters can allow multispectral photogrammetry to be performed for forensic investigations. The obtained 3D multispectral full-body data can facilitate the detection of latent evidence that is invisible to the naked eye and allow visualization, documentation and analysis of evidence beyond that in the VIS spectrum.