Abstract
Bone taphonomy is a widely investigated topic; however, few data are available concerning marine bone taphonomy, especially on remains recovered from great depths and with short post-mortem intervals. To date, few studies have evaluated the bony changes which occur in seawater compared to samples with different post-mortem histories, and none through a comparative analysis of different approaches. To this purpose, this pilot study aims to examine the influence of seawater on bone preservation compared to other depositional contexts by multiple perspectives. Forty-nine human bone samples (femurs or tibiae) recovered from different environments (sea water, fresh water, outdoor, burial in coffin) were compared by macroscopic, microscopic and bone densitometric approaches. In order to investigate organic and inorganic components, undecalcified and decalcified histology of thin sections was performed. The analyses revealed a well-preserved bone tissue both macroscopically (92%) and microscopically (97% and 95% for undecalcified and decalcified sections). No significant differences were detected from radiological densitometric investigations (BMD = 1.6 g/cm2 ± 0.1), except between old and young individuals (p value < 0.001). Differences were observed for body decomposition and few scavenged samples (3/15). However, even if slight variations were observed, no relation was recorded with the depositional contexts. We found a similar bone preservation in the four environments at the time of recovery, both macroscopically and microscopically, but also with radiological densitometric investigations. Our observations enriched the literature on bone taphonomy, providing data on bone tissue preservation in the early post-mortem period from a multidisciplinary perspective, paving the way for further studies on the topic.
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Introduction
Bone taphonomy has always fascinated forensic scientists for many reasons, some more valid perhaps than others: at times it seems to have strong correlations, but not always, with postmortem interval (PMI), in other cases it seems to relate to the burial or deposition site of the body, and sometimes macroscopic taphonomy may be envisaged as reflecting the potential the bone has for providing microscopic, biomolecular, chemical information. Many times, however, research has proven that these correlations may not be so [see, for example, 1–5].
Since the nineteenth century, several studies have been carried out to better understand the diagenetic processes which affected human remains coming from different environments [e.g. 6–16]. Over the years, several mechanisms responsible for bone deterioration have been described, including biological and chemical degradation of the collagen fraction and dissolution and recrystallization phases of the mineral component [9, 12, 13, 16, 17]. A mutual protection was proposed as responsible for bone stability during the post-mortem period between these two fractions (the collagen and the mineral fractions), and its breaking would result in a rapid degradation of bone tissue [18]. Among the different mechanisms, the microbial degradation of bone has been one of the most investigated topics. In 1981, Hackett was the first to describe and characterise the forms of foci and tunnels [8], with several scientists after him proceeding with the study of bone tissue microstructure with a special focus on microbial activity in bones coming from different environments. The possible patterns of microbial activity that can be found in different contexts have been described, especially those related to outdoor and water environments, reporting the time at which the first signs were visible within bone tissue [see, for example, 15, 19–23]. However, despite the considerable number of studies, little is still known about marine bone taphonomy, especially for samples coming from deep sea and with a short PMI.
Considering the difficulties in setting experimental investigations in marine environments, information generally comes from forensic cases [24–27], which are focused on body preservation and macroscopic appearance of the recovered skeletal remains. Studies on bioerosion were also carried out, but analyses were limited to experimental substrates (e.g. limestone and PVC plates) [28,29,30,31]. Other bioerosion studies were carried out on pigs, but without analysing bone tissue when skeletonization was reached [32,33,34]. Considering bone histological investigations, data were recorded especially from archaeological material (tenth to sixteenth centuries) [20, 23, 35, 36], and only in few cases from recent human skeletal remains [19].
In the last years, methods other than microscopy were used in taphonomical research, such as chemical and radiological analyses. Among these, the analysis of bone mineral density (BMD) has been included in many studies. In particular, previous investigations focused on the changes in bone mineral content at several portions on human bones by different techniques (single photon absorptiometry, peripheral quantitative computed tomography (pQCT), and dual energy X-ray densitometry) [37–39], suggesting a possible relation between the density of bone elements or portions and their degree of environmental preservation [38, 39]. However, no studies have investigated BMD on skeletal remains coming from marine environments, nor have they evaluated whether variations in mineral content exist between different environments. In addition, no comparisons were carried out so far among bones recovered from different depositional scenarios with a multidisciplinary approach (medico-legal, anthropological and radiological).
Collecting more data on bone tissue preservation of contemporary samples would provide important insights on the diagenetic trajectory which affected skeletal remains, as well as regarding the mechanisms involved in the preservation/degradation of the bone components (collagen and mineral phase). This is even more important from environments for which little information is available, such as the sea [27, 40]. This information would have also important implications in laboratory analyses that involve the study of the bone tissue and its molecular components, such as age estimation, pathological diagnosis and genetic studies. In addition, comparisons with other samples with a different post-mortem history would allow identification of the peculiar traits which can differentiate the different burials and environmental changes acting as a fingerprinting of the diagenetic events.
The present pilot study aims to compare the state of preservation of bones recovered in seawater with bones coming from different environments (outdoor and fresh water environments and buried in coffin) from a macroscopic, microscopic and bone densitometric perspectives. This is the first type of comparative study in this sense to our knowledge.
Materials and methods
Samples
The study was conducted overall on 49 samples coming from four different contexts.
Fifteen samples (samples SW 1–15) were selected from remains recovered in a boat which had sunk in the Mediterranean Sea 100 km north of the Libyan coast and 200 km south of the Italian island of Lampedusa at a depth of about 400 m. The bodies, who laid both outside the boat (in the sea bottom) and inside cargo and deck, were recovered in different periods after the disaster (from 4 to 14 months).
Fourteen samples were selected from forensic cases, accordingly to the availability of skeletons with PMI comparable to those of the marine group. Among these, three samples were collected from individuals recovered in fresh water environments (FW 1–3), while the remaining were all recovered in outdoor environments (i.e. on the ground surface) (OE 1–10), with the exception of one individual, who was buried in soil at a depth of 1 m (OE 11). All the environments were located in the North of Italy, in Piedmont, Lombardy and Emilia Romagna Region, and the remains were recovered in a time lapse between 2000 and 2019. In this area the mean annual temperature ranges between 12 and 15 °C (13.2 °C ± 1.2 °C), with mean cumulative rainfall of 939 mm (± 343.8 mm) and mean humidity of 76% (± 5.4%) (mean data from 2000 to 2019 [41]).
Ten samples (samples CM 1–10), with a much longer PMI and buried in soil, were selected from the contemporary Milan skeletal collection, “Collezione Antropologica LABANOF” (CAL, LABANOF Anthropological Collection) [42]. The bodies came from unclaimed remains of persons who died between 1990 and the 1992, buried inside coffin and placed under the soil for 15 years at the Cimitero Maggiore in Milan (Italy), until complete skeletonization.
In addition, in order to evaluate the presence of BMD age-related changes in the samples buried in coffins (cemeterial cases), bone densitometric analyses were performed on ten complete femurs selected from ten younger individuals of the same skeletal collection (5 males and 5 females, burial in coffin, PMI: 20 years), with known ages that were comparable to the outdoor sample (age range: 20–45 years old). To this purpose, CM samples were called CM_old and CM_young, respectively.
The remains of these individuals can be used for scientific studies, in accordance with the Police Mortuary Rules (DPR 09.10.1990 n° 285, art. 43) and the Regio Decreto (08.31.1933 n° 1592, art. 32).
Femurs or tibiae were chosen for the analyses, since these bone elements were available for each case. Information on the biological profiles was acquired through demographic sources and/or anthropological analyses [43].
Details concerning each sample are reported in Table 1.
Anthropological analyses
Body preservation
The state of decomposition of the body was evaluated as described in [25, 44]) for samples from water and outdoor/buried samples, respectively. Nine (from 1 to 9) and ten (from A to D, with additional sub-stages) categories describe the decomposition of a body from the “fresh cadaver” appearance to an early and then advanced decomposition, until the partial/complete bone exposure and final disarticulation.
To this purpose, pictures acquired during body examinations were analysed, with a special focus on the portion of the lower limbs from which samples were collected (thigh or leg).
To compare results, the scoring system defined by De Donno et al. [25] was uniformed to the four categories identified by Megyesi et al. [44] as reported in Table 2.
Macroscopic analysis of the bone tissue
Since environments have a different influence on the macroscopic appearance of bones, the state of preservation of bone surface was evaluated using specific methods for each samples group.
Samples collected from buried remains or remains decomposed in an outdoor environment were analysed applying bone weathering stages proposed by Behrensmeyer [45]. Six stages were identified (from 0 to 5), corresponding to an increasing amount of bone alterations, such as cracking, flaking, rough area and weathered compact bone, which becomes more consistent over time. Stage 0 was associated to bone showing greasiness, no cracks or flakes and soft tissue still present, while the last phase (stage 5) corresponded to very fragile bones, easily prone to breaking.
Samples coming from the aquatic environment were evaluated according to the description reported by Pokines et al. [26]. Since no scoring system was suggested, bone appearance was described checking for the taphonomic characteristics identified by the authors in marine remains. Generally, score 0 was associated to bone showing organic sheen, fat leaching, adipocere and soft tissue still present.
Microscopic analysis
Two semi-circular sections were cut transversely with a hacksaw at the middle diaphysis of each bone sample (or in its proximity when it was lacking) and submitted to processing protocols for undecalcified and decalcified bone sections.
The first sections were levelled on a side using a Struers Dap-7 grinding wheel, with abrasive discs of grain size between 180 and 4000, to obtain flat and polished fragments. After the mounting of the smooth side on a glass slide with Pertex resin (Histolab Products AB), samples were grounded on the other side to get thin sections suitable for microscopic analysis.
The second sections were fixed in formalin (v/v, pH 7–7.6), ratio formalin/sample 20:1, and decalcified at room temperature with Histo-Decal, containing 14% hydrochloric acid (Histo-Line Laboratories, Milan), rinsing 1h in tap water after each step. After dehydration using an increasing alcohol series, samples were included in paraffin, cut in 5 μm sections and stained with Hematoxylin-Eosin.
Sample slides were analysed using the polarizing optical microscope Zeiss Axio Scope.A1, and images were acquired with the camera system True Chrome Hd II and the software ISCapture version 3.6.7. Bone tissue appearance was evaluated and classified according to the score system (Oxford Histological Index, OHI) described by Hedges et al. [46], as already applied by Cappella et al. and Caruso et al. [47, 48]. Six stages were identified (from 5 to 0), evaluating the amount of unaltered bone and the possibility to recognise bone structures such as osteons, lamellae and osteocyte lacunae. Bone sections with well-preserved tissue, highly similar to fresh bone were scored as “5”, while sections with less than 5% of the tissue preserved and no recognisable features were classified as “0”.
Radiological analyses
Bone mineral density (BMD) was assessed with dual energy X-ray absorptiometry (DXA), using a Hologic QDR-Discovery W densitometer (Hologic Inc., Bedford, MA, USA). BMD areal values were expressed as g/cm2, which represents the bone mineral content (g) per area (cm2). Bone samples were scanned in 140 × 25 mm regions covering all the bone shaft available. As not all the bone specimens were complete, comparison between samples was performed on the region which resulted most common among the majority of them. In particular, since the fifteen samples from sea water environment only had a fragment sampled during autopsy examination from the middle diaphysis, this region was selected for the analysis. Only six samples lacked this part, SW 5, OE 3, OE 7, OE 10, OE 11 and CM_old 9, and were not included in the analysis.
Statistical analysis
Interobserver variability
Anthropological analyses were carried out in a blind test by two anthropologists (with 5 and 10 years of experience on macro- and microscopic taphonomy) following the scoring system described in the previous paragraphs (see the Anthropological Analyses section). Interobserver agreement was calculated using the Cohen’s kappa statistic [49]. The interpretation of Cohen’s kappa was carried out as reported by Landis and Koch [50], defining values < 0 as no agreement, 0–0.20 as slight, 0.21–0.40 as fair, 0.41–0.60 as moderate, 0.61–0.80 as substantial and 0.81–1 as almost perfect agreement.
Mineral content variation among groups
In order to determine if the depositional environment could influence bone mineral content, statistical analyses were carried out to evaluate differences on BMD among the different groups. However, since few samples were available for the fresh water environment (3 samples) and the sample size was not comparable to the other groups, this group was not included in the statistical evaluation. Normality and homoscedasticity were verified by the Shapiro and Bartlett tests, and the comparison among group means was performed using the one-way analysis of variance (ANOVA). Post-hoc tests were made by Tukey HSD tests. Statistical significance was assessed when the p value was lower than 0.05.
Statistical analyses were carried out using the R Studio Software (version 1.2.1335) (RStudio Team (2015). RStudio: Integrated Development for R. RStudio, Inc., Boston, http://www.rstudio.com/).
Results
Anthropological analyses
Statistical analysis highlighted a high agreement between the two operators. Kappa values ranged between 0.70 and 0.95 (p value < 0.001), suggesting low interobserver variability (Table 3).
Evaluation of the state of preservation of the cadavers (Table 4, section “Body decomposition”) revealed a greater skeletonization of the bodies (61% of the entire sample) and a minor early/advanced stage of decomposition in the entire sample (13% and 26%, respectively). Comparing the four environments, inter-group variability was observed. Skeletonization of the samples was recorded in all the buried cases (CM_old 1–10) and, with a low percentage, in the sea water context (67%), where other stages were still present even if in a minor amount (13% and 20% in B and C, respectively). Differently, samples coming from fresh water and outdoor environments were spread in the central (B and C) and in the last three categories (B, C, D) respectively, the latter showing the majority of bodies in the advanced stage of decomposition and skeletonization classes (46% and 36%, respectively).
When bone tissue was examined, comparable results were obtained from both macroscopic and microscopic analyses (Table 4, sections “Bone preservation”, “Undecalcified thin sections” and “Decalcified thin sections”). Most of the samples were characterised by good preservation of the cortical bone tissue (92%, scores 0–1), which appeared still greasy in samples with the shortest PMI (< 36 months), and by well-preserved bone microstructure (within up to 85–95% of the tissue) in both undecalcified and decalcified thin sections (97% and 95%, respectively, scores 4–5) (Fig. 1).
No tunnels and destructive foci were detected in the samples collected from the two aquatic contexts and the outdoor environments, which showed also a similar macroscopic appearance. Cortical bone erosion related to marine organism activity was observed both macroscopically and microscopically in three samples recovered in the sea bottom 7–9 months after death (SW 9, SW 10 and SW 14). In spite of the loss of bone tissue in the external layer, the bone structure proved well-preserved inside: the medullary cavity still full of preserved bone marrow and the absence of weathering signs as well as destructive foci in the entire section represent the main findings (Fig. 1d–f). Differently, even if in a small fraction of samples (from 10 to 30%), the buried cases (CM_old cases) displayed bone weathering on the surface, mainly consisting in flaking (CM_old 6, CM_old 7 and CM_old 8), and destructive foci caused by microbial activity corresponding to circa 30% of the bone section (CM_old 1 and CM_old 4, Fig. 1q–r), while in the remaining cases the bone tissue was well-preserved (Fig. 1m– o).
When attention was focused on bone tissue alterations, other than tunnels and destructive foci, blackish/darkened areas of unknown origin were identified in undecalcified thin sections of both seawater and fresh water samples. In particular, these regions were in correspondence of both external circumferential lamellae and osteons in the seawater samples SW12 and SW13 (Fig. 2a–c), and they were observed also in the middle section in fresh water samples (Fig. 2d–f). After decalcification, in the latter the same osteons appeared detached from the surrounding tissue with an appearance similar to that of insufficiently demineralised tissue (Fig. 1h–i).
Comparing body and bone preservation, no relation was observed. In particular, complete skeletonized samples showed in the majority of the cases macroscopic and microscopic features similar to those collected from recent and early decomposed bodies (Fig. 3). In addition, the localization of most of the samples within the area characterised by well-preserved bones (Fig. 3, 0-1 and 5-4 coordinates) pointed that no relevant macroscopic and microscopic differences existed among the three different contexts.
Radiological analyses
The BMD values obtained by the bone densitometric analyses are reported in Table 5. Since an outlier was identified in the old cemeterial group (highlighted in bold in the table), the value was excluded from the statistical analysis.
BMD analysis showed comparable results between the sea water and the outdoor samples (Table 5). In both cases, BMD values ranged from 1.332 to 1.772 g/cm2, with a mean ± standard deviation (SD) of 1.6 ± 0.1 g/cm2. Similar findings were also detected on the samples from fresh water environments. Even if few samples were available in this case and statistics could not be considered, the three samples showed values comparable to the previous groups.
Differently, lower values were observed in the CM_old sample, whose bone mineral density ranged from 0.876 to 1.402 g/cm2, with a mean ± SD of 1.166 ± 0.176 g/cm2. In contrast to the old cemeterial group, femur samples from younger individuals coming from the same burial context (burial in coffin and a PMI of 20 years) showed a bone density similar to the first two groups (SW and OE groups) (mean, 1.598 g/cm2; SD, 0.116 g/cm2; min, 1.456 g/cm2; max, 1.785 g/cm2), highlighting again differences with the older subjects of the entire sample (Table 5).
These observations were corroborated by statistical analyses. ANOVA test showed a significant difference among the four major groups (p value < 0.001), and specifically significant differences were observed between the old cemeterial group with the sea water, outdoor and young cemeterial samples (p values < 0.001 in all cases by pairwise comparisons carried out using the Tukey HSD test).
Considering the samples depending on the sex of the individual and the bone selected for the analysis (femur or tibia), additional information was pointed out. Figure 4 reports BMD values for each group of samples, distinguishing among males and females, as well as the bone sample (femur and tibia) and environments.
Female samples were generally characterised by lower BMD values compared to the males of the same group. A similar trend was observed between bone samples especially in the CM_old sample, where femurs showed greater values than tibiae.
Looking at BMD values distribution, the trend described before was more evident. Specifically, the majority of BMD values were in the range between 1.4 and 1.8 g/cm2 for both the aquatic and outdoor environments and the CM_young samples, while values lower than 1.4 g/cm2 were recorded in the CM_old sample (between 0.8 and 1.4 g/cm2). A similar scenario was outlined when comparisons were performed among the only male groups, even if the CM_young and the outdoor samples showed values only greater than 1.6 g/cm2. To this purpose, a deep analysis of the sea water group highlighted that BMD values between 1.4 and 1.6 g/cm2 were observed especially in the A and slightly in the C groups (i.e. the samples recovered in the sea bottom and cargo, respectively), whereas greater values were recorded in the B samples (i.e. samples recovered in the deck of the ship).
Discussions
The present pilot study provided a preliminary insight on the state of preservation of bodies and bone samples from a marine environment, and specifically from great depths (400 m) and with short PMI (4–14 months). This was done from several points of view (macroscopic, microscopic and densitometric), by comparing data of similar samples collected from individuals which were buried in coffins, as well as recovered in outdoor or fresh water environments.
Macroscopic and microscopic methods were selected as they are the reference methods in bone taphonomy research and the most used to describe bone tissue preservation [see 8, 21, 26, 45–48]. However, to collect data mainly on the mineral component, dual energy X-ray absorptiometry was selected as non-destructive method able to measure the mineral content and to provide additional data before carrying out any further destructive analyses.
In literature, the few studies focusing on marine taphonomy are limited to body decomposition [24–27] and to experimental investigations on pigs or bioerosion [28–34]. However, not many analyses were carried out on the skeletal tissue in order to evaluate the cellular and molecular changes which occur in marine contexts in contemporary samples.
Our results showed an overall good preservation of bone tissue of the sea water samples from both the macroscopic and microscopic point of view, regardless of the state of decomposition of the body. Only three samples displayed cortical bone erosion possibly due to fauna activity in agreement with the observations performed by Pokines et al. [26] and the experiments carried out using pig carcasses by Anderson and Bell [32,33,34]. Despite bone loss, the samples were characterised by well-preserved tissue, and no microorganism invasion in the form of tunnels such as those described in several studies [8, 19, 20, 23, 35] was detected. The absence of such microbial activity could be explained with an insufficient time since death to allow microorganisms’ invasion and growth. The observations performed by Yoshino and colleagues [19] supported this theory. In fact, they observed microscopically the first signs of microorganism activity in recent human remains recovered from the marine context 4–5 years after death. Similarly, even if using a different substrate (limestone) and focusing on macrobioerosion, Färber and colleagues [31] (experimental condition: close to Greek cliff, water depths between 3 and 17 m) observed no activity within the first year of exposure, thus identifying an increasing diversity and intensity of bioerosion agents over time. However, time could not be the only variable. In fact, since some archaeological samples (tenth to sixteenth centuries) showed bone matrix characteristics similar to those observed in fresh bones [20, 35, 36], environmental conditions have to be also included among the factors influencing bone tissue preservation. Several studies highlighted the effects of environmental parameters such as temperature, light, depth, dissolved oxygen on faunal compositions and diversity related to body preservation [24, 25, 28–34]. Generally, a decrease in life and diversity has been observed with increasing depths and differences were recorded in different seasons, with the lowest activity and diversity documented in winter at the deepest depth considered (250 m) [30]. In their study Arnaud and colleagues [35] explained the good preservation of the observed bone matrix as the result of a wet salting procedure of the sample during the post-mortem period. In such a case, the salt contained in the sea water acts similarly to the salt-fish conservation, as it penetrates into the tissue with a better bone structure preservation.
In order to verify the presence of differences among bones coming from different environments, seawater samples were compared with other cases coming from outdoor and fresh water environments and cases buried in a coffin. Previous studies in literature compared samples from different post depositional contexts [15, 19, 21, 23], but none of them investigated taphonomic parameters such as the general body preservation, the macroscopic and microscopic tissue appearance and the bone mineral content.
When comparing samples from the various analysed contexts (sea water, fresh water, outdoor and burial in coffin), no differences were observed in terms of bone macroscopic and microscopic preservation. Specifically, the microscopic aspect proved similar high OHI scores in both undecalcified and decalcified thin sections, suggesting a good preservation of both organic and inorganic components. Only few samples from individuals buried in coffins showed limited microorganism invasion (10–30%). Regardless the bone element analysed, the present results are in agreement with those reported in literature: limited microorganism invasions were found at mid-diaphysis in femurs and tibiae of buried individuals by Caruso et al. [48], and the appearance of first signs of microbial activity within the bone tissue was found near the surgical neck of humeri after 15 years of decomposition on the ground by Yoshino et al. [19]. The similar preservation observed suggested that regardless the region of sampling, bone diaphysis shows a comparable bone tissue preservation. Differences were instead highlighted on the state of preservation of the body. In fact, an advanced decomposition was found mainly in fresh water and outdoor samples, while a greater amount of seawater and buried cases were partially or completely skeletonised. The complete skeletonization of samples from buried corpses could be ascribable mainly to the longer time since death (PMI: 20 years); for this reason, a higher number of samples coming from a similar environment and with a shorter PMI (1 year) are needed to perform additional comparisons. On the contrary, samples recovered from the sea showed results at times slightly opposite to what has been reported in literature: Ellingham et al. [27] discoursed about a decomposition process slower than that occurring on ground for corpses decomposing in seawater contexts because of the lower temperatures, the absence of insects and the salinity which decreases bacterial activities. However, as highlighted by Anderson and Bell [34], at depths of 100–300 m remains are mainly scavenged than decomposed, and this data might justify why the majority of bodies proved partially or completely skeletonised in our sample. In this regard, faunal composition and necrophagous communities are the main factors influencing the speed of skeletonization of a body [24]. Examples of skeletonised and disarticulated bodies with a short PMI (few months) have been described in literature [24, 32].
Even if slight differences were highlighted among the groups, body preservation seemed not to influence the macroscopic and microscopic appearance of each sample. In fact, even in case of complete skeletonization of the body, macroscopic and microscopic bone appearance was similar in all the contexts. Similarly, no relation exists between macroscopic and microscopic preservation, as highlighted within the small fraction of samples showing bone weathering on the surface, but a well-preserved bone tissue microscopically. In addition, the features analysed in our study seem not to be predictive of the depositional context, both when samples with comparable and different PMIs were considered. The only exception seems to be the peculiar pattern identified in the sea and fresh water samples (blackish/darkened areas). However, such a pattern is difficult to interpret and the origin and causes are still unknown. To this purpose, additional investigations are needed by high-resolution technologies, such as backscattered electron imaging in a scanning electron microscope (BSE-SEM), already used in taphonomic studies of bone tissue [10, 15, 21, 23, 51].
Densitometric radiological investigation provided interesting data to taphonomic research. To date, studies focused especially on bone portion “survival” without checking whether differences exist between environments. Therefore, this is the first study in which different depositional contexts are compared and where data on sea water samples are reported.
Differently to anthropological analyses, densitometric radiological investigation highlighted a significant difference between sea water and outdoor samples with old cemeterial cases. The lower values observed in the latter can depend on several variables, among which the environment, age at death, pathology or the bony part we analysed. In fact, the old cemeterial group was the sample mostly represented by tibiae (50% of the sample compared to the 18–27% of the other groups) where the BMD values found were clearly lower than those observed on femurs. Because it was difficult to verify all the variables and especially considering the decrease of the mineral content in the old population already proved in literature [52–54], we decided to select ten individuals from the same environment (burial in coffin) whose age at death and kind of bone were comparable with the outdoor and sea water samples (age range: 20–43 years old, bone: femur). The obtained BMD values at the middle diaphysis ranged between 1.456 and 1.785 g/cm2 (mean: 1.598 g/cm2, SD: 0.116 g/cm2), and no differences were observed when comparing these values to those obtained from sea water samples and outdoor cases, excluding any difference among these environments. When fresh water samples were also considered, even if in a small number, similarities were observed with the majority of the samples, highlighting once more the difference with the old group.
Since the sea water samples were all collected from male individuals and considering the well-known differences in bone mineral density existing between males and females [37, 52], comparisons were also carried out limiting the analyses to the only male fraction. Also for this sub-analysis we found similar conclusions, even if cemeterial (young individual), and outdoor samples showed values slightly greater than sea water bones. These variations may be related to the reduced number of samples and/or the position of bodies within the ship. In support to the second hypothesis, BMD values recorded suggested a decrease of bone mineral density in samples collected from individuals recovered in the sea bottom and cargo, while greater values were observed in samples recovered from the deck. However, sample size has to be increased in order to check this variation and to identify the variables involved.
The present study has some limitations. Some samples, especially those buried in coffins, had a PMI longer than the other cases, and no data were available 1 year after death. However, since a well-preserved bone tissue has been macroscopically and microscopically observed in the majority of the cases, we could assume a bone tissue preservation comparable to the other samples even in the early post-mortem period. Concerning bone densitometric investigation, no information was available about BMD at the time of death, preventing to carry out a longitudinal analysis for this parameter assessing its possible changes over the time in each environment. Therefore, we focused mainly on the data after the recovery in the several depositional contexts in order to verify if any difference exists and if BMD can be considered a relevant predictive marker of the depositional environment in forensic cases. An additional limitation lies in the unequal number of samples from each post depositional contexts and especially the small size of the fresh water sample. This requires in the future further analyses on larger sample groups in order to verify the observations reported. Nevertheless, even if no additional data are available, the present study would provide an initial overview of the state of preservation of the bone tissue comparing samples with different post-mortem histories and by adding radiological densitometric methods to the common anthropological investigations used in bone taphonomy research.
Conclusion
The present pilot study represents a first taphonomic attempt to compare samples of contemporary human remains recovered from different environments and PMIs by several perspectives, enriching literature on body and bone preservation, from a macro-, microscopic and radiological point of view. In particular, since no studies are available concerning contemporary human remains recovered from the sea at greater depths such as 400 m and especially in the Mediterranean Sea, these observations, even if on a small sample, provided further data on marine bone taphonomy. The analyses performed highlighted a similar preservation of the bone tissue in the four environments, both macroscopically and microscopically, despite the state of preservation of the body. Similar conclusions were outlined by radiological densitometric investigations, showing no differences among the contexts. Further analyses need to be performed using higher resolution technologies, larger sample sizes, human remains with different PMIs and recovered from various environmental contexts, in order to possibly highlight changes and differences for longer period of times and to obtain a more complete taphonomic picture.
In the meantime, the results obtained in this study suggest that no differences exist among the four contexts at the time of recovery and that neither the bone preservation nor the mineral content/density can be considered predictive of the depositional environment, especially for cases with PMI shorter than 14 months.
Data availability
All data analysed during this study are included in this published article
Code availability
Not applicable
References
Haynes S, Searle JB, Bretman A, Dobney KM (2002) Bone preservation and ancient DNA: the application of screening methods for predicting DNA survival. Journal of Archaeological Science 29(6):585–592. https://doi.org/10.1006/jasc.2001.0731
Jans MME, Kars H, Nielsen–Marsh CM, Smith CI, Nord AG, Arthur P, Earl N, (2002) In situ preservation of archaeological bone: a histological study within a multidisciplinary approach. Archaeometry 44(3):343–352. https://doi.org/10.1111/1475-4754.t01-1-00067
Misner LM, Halvorson AC, Dreier JL, Ubelaker DH, Foran DR (2009) The correlation between skeletal weathering and DNA quality and quantity. J Forensic Sci 54(4):822–828. https://doi.org/10.1111/j.1556-4029.2009.01043.x
Cockle DL, Bell LS (2015) Human decomposition and the reliability of a “universal” model for post mortem interval estimations. Forensic Sci Int 253:136.e1–9. https://doi.org/10.1016/j.forsciint.2015.05.018
Buekenhout I, Cravo L, Vieira DN, Cunha E, Ferreira MT (2018) Applying standardized decomposition stages when estimating the PMI of buried remains: reality or fiction? Australian Journal of Forensic Sciences 50(1):68–81. https://doi.org/10.1080/00450618.2016.1212268
Wedl C (1864) Über einen im Zahnbein und Knochen keimenden Pilz. Sitzungsber. Akad Wiss Wien 50:171–192
Marchiafava V, Bonucci E, Ascenzi A (1974) Fungal osteoclasia: a model of dead bone resorption. Calcif Tissue Res 14(3):195–210. https://doi.org/10.1007/bf02060295
Hackett CJ (1981) Microscopical focal destruction (tunnels) in exhumed human bones. Med Sci Law 21(4):243–265. https://doi.org/10.1177/002580248102100403
Collins MJ, Riley MS, Child AM, Turner-Walker G (1995) A basic mathematical simulation of the chemical degradation of ancient collagen. J Archaeol Sci 22(2):175–183. https://doi.org/10.1006/jasc.1995.0019
Bell LS, Skinner MF, Jones SJ (1996) The speed of post mortem change to the human skeleton and its taphonomic significance. Forensic Sci Int 82(2):129–140. https://doi.org/10.1016/0379-0738(96)01984-6
Nielsen-Marsh CM, Hedges REM (2000) Patterns of diagenesis in bone I: the effects of site environments. J Archaeol Sci 27(12):1139–1150. https://doi.org/10.1006/jasc.1999.0537
Collins MJ, Nielsen–Marsh CM, Hiller J, Smith CI, Roberts JP, Prigodich RV, Wess TJ, Csapò J, Millard AR, Turner-Walker G, (2002) The survival of organic matter in bone: a review. Archaeometry 44(3):383–394. https://doi.org/10.1111/1475-4754.t01-1-00071
Hedges RE (2002) Bone diagenesis: an overview of processes. Archaeometry 44(3):319–328. https://doi.org/10.1111/1475-4754.00064
Reiche I, Favre-Quattropani L, Vignaud C, Bocherens H, Charlet L, Menu M (2003) A multi-analytical study of bone diagenesis: the Neolithic site of Bercy (Paris, France). Meas Sci Technol 14:1608–1619. https://doi.org/10.1088/0957-0233/14/9/312
Turner-Walker G (2012) Early bioerosion in skeletal tissues: persistence through deep time. N Jb Geol Paläont Abh 265(2):165–183. https://doi.org/10.1127/0077-7749/2012/0253
Kendall C, Eriksen AMH, Kontopoulos I, Collins MJ, Turner-Walker G (2018) Diagenesis of archaeological bone and tooth. Palaeogeogr, Palaeoclimatol, Palaeoecol 491:21–37. https://doi.org/10.1016/j.palaeo.2017.11.041
Smith CI, Nielsen-Marsh CM, Jans MME, Collins MJ (2007) Bone diagenesis in the European Holocene I: patterns and mechanisms. J Archaeol Sci 34(9):1485–1493. https://doi.org/10.1016/j.jas.2006.11.006
Trueman CN, Martin DM (2002) The long-term survival of bone: the role of bioerosion. Archaeometry 44(3):371–382. https://doi.org/10.1111/1475-4754.t01-1-00070
Yoshino M, Kimijima T, Miyasaka S, Sato H, Seta S (1991) Microscopical study on estimation of time since death in skeletal remains. Forensic Sci Int 49(2):143–58. https://doi.org/10.1016/0379-0738(91)90074-s
Bell LS, Elkerton A (2008) Unique marine taphonomy in human skeletal material recovered from the medieval warship Mary Rose. Int J Osteoarchaeol 18(5):523–535. https://doi.org/10.1002/oa.952
Fernández-Jalvo Y, Andrews P, Pesquero D, Smith C, Marín-Monfort D, Sánchez B, Geigl EM, Alonso A (2010) Early bone diagenesis in temperate environments: Part I: surface features and histology. Palaeogeogr, Palaeoclimatol, Palaeoecol 288(1–4):62–81. https://doi.org/10.1016/j.palaeo.2009.12.016
Pesquero MD, Ascaso C, Alcalá L, Fernández-Jalvo Y (2010) A new taphonomic bioerosion in a Miocene lakeshore environment. Palaeogeogr, Palaeoclimatol, Palaeoecol 295(1–2):192–198. https://doi.org/10.1016/j.palaeo.2010.05.037
Pesquero MD, Bell LS, Fernández-Jalvo Y (2018) Skeletal modification by microorganisms and their environments. Historical Biology 30(6):882–893. https://doi.org/10.1080/08912963.2017.1371713
Dumser TK, Türkay M (2008) Postmortem changes of human bodies on the bathyal sea floor–two cases of aircraft accidents above the open sea. J Forensic Sci 53(5):1049–1052. https://doi.org/10.1111/j.1556-4029.2008.00816.x
De Donno A, Campobasso CP, Santoro V, Leonardi S, Tafuri S, Introna F (2014) Bodies in sequestered and non-sequestered aquatic environments: a comparative taphonomic study using decompositional scoring system. Sci Justice 54(6):439–446. https://doi.org/10.1016/j.scijus.2014.10.003
Pokines JT, Higgs N (2015) Macroscopic taphonomic alterations to human bone recovered from marine environments. J Forensic Identif 65(6):953–984
Ellingham STD, Perich P, Tidball-Binz M (2017) The fate of human remains in a maritime context and feasibility for forensic humanitarian action to assist in their recovery and identification. Forensic Sci Int 279:229–234. https://doi.org/10.1016/j.forsciint.2017.07.039
Poulicek M, Goffinet G, Jeuniaux C, Simon A, Voss-Foucart MF (1988) Early diagenesis of skeletal remains in marine sediments: a 10 years study. Bull Soc R Liège 57(4–5):313–330
Wisshak M, Gektidis M, Freiwald A, Lundälv T (2005) Bioerosion along a bathymetric gradient in a cold-temperate setting (Kosterfjord, SW Sweden): an experimental study. Facies 51(1–4):93–117. https://doi.org/10.1007/s10347-005-0009-1
Färber C, Wisshak M, Pyko I, Bellou N, Freiwald A (2015) Effects of water depth, seasonal exposure, and substrate orientation on microbial bioerosion in the Ionian Sea (Eastern Mediterranean). PloS one 10(4):e0126495. https://doi.org/10.1371/journal.pone.0126495
Färber C, Titschack J, Schönberg C, Ehrig K, Boos K, Baum D, Illerhaus B, Asgaard U, Bromley RG, Freiwald A, Wisshak M (2016) Long-term macrobioerosion in the Mediterranean Sea assessed by micro-computed tomography. Biogeosciences 13:3461–3474. https://doi.org/10.5194/bg-13-3461-2016
Anderson GS, Bell LS (2014) Deep coastal marine taphonomy: investigation into carcass decomposition in the Saanich Inlet, British Columbia using a baited camera. PLoS One 9(10):e110710. https://doi.org/10.1371/journal.pone.0110710
Anderson GS, Bell LS (2016) Impact of marine submergence and season on faunal colonization and decomposition of pig carcasses in the Salish sea. PLoS One 11(3):e0149107. https://doi.org/10.1371/journal.pone.0149107
Anderson GS, Bell LS (2017) Comparison of faunal scavenging of submerged carrion in two seasons at a depth of 170 m, in the strait of Georgia. British Columbia. Insects 8(1):33. https://doi.org/10.3390/insects8010033
Arnaud G, Arnaud S, Ascenzi A, Bonucci E, Graziani G (1978) On the problem of the preservation of human bone in sea-water. J Hum Evol 7(5):409–420. https://doi.org/10.1016/S0047-2484(78)80091-8
Ascenzi A, Silvestrini G (1984) Bone-boring marine micro-organisms: an experimental investigation. J Hum Evol 13(6):531–536. https://doi.org/10.1016/S0047-2484(84)80006-8
Galloway A, Willey P, Snyder L (1997) Human bone mineral densities and survival of bone elements: a contemporary sample. In: Haglund WD, Sorg MH (eds) Forensic Taphonomy. CRC Press, The postmortem fate of human remains, pp 295–318
Willey P, Galloway A, Snyder L (1997) Bone mineral density and survival of elements and element portions in the bones of the Crow Creek massacre victims. Am J Phys Anthropol 104(4):513–528. https://doi.org/10.1002/(SICI)1096-8644(199712)104:4%3c513::AID-AJPA6%3e3.0.CO;2-S
Suby JA, Guichón RA, Cointry G, Ferretti JL (2009) Volumetric BMD values of archaeological human bone remains with pQCT and DEXA. Journal of Taphonomy 7(1):29–45
Gilbert F, Oxenham M (2020) Estimation of the TSD in an aquatic environment. In: Hayman J, Oxenham M (eds) Estimation of the time since death: current research and future trends. Academic Press, pp 165–189
SCIA. Sistema nazionale per l’elaborazione e diffusione di dati climatici. www.scia.isprambiente.it. Accessed 12 April 2021
Cattaneo C, Mazzarelli D, Cappella A, Castoldi E, Mattia M, Poppa P, De Angelis D, Vitello A, Biehler-Gomez L (2018) A modern documented Italian identified skeletal collection of 2127 skeletons: the CAL Milano cemetery skeletal collection. Forensic Sci Int 287:219.e1-219.e5. https://doi.org/10.1016/j.forsciint.2018.03.041
Christensen AM, Passalacqua NV, Bartelink EJ (2014) Forensic anthropology: current methods and practice. Academic Press, San Diego, CA
Megyesi MS, Nawrocki SP, Haskell NH (2005) Using accumulated degree-days to estimate the postmortem interval from decomposed human remains. J Forensic Sci 50(3):1–9. https://doi.org/10.1520/JFS2004017
Behrensmeyer AK (1978) Taphonomic and ecologic information from bone weathering. Paleobiology 4(2):150–162. https://doi.org/10.1017/S0094837300005820
Hedges RE, Millard AR, Pike AWG (1995) Measurements and relationships of diagenetic alteration of bone from three archaeological sites. J Archaeol Sci 22(2):201–209. https://doi.org/10.1006/jasc.1995.0022
Cappella A, Gibelli D, Muccino E, Scarpulla V, Cerutti E, Caruso V, Sguazza E, Mazzarelli D, Cattaneo C (2015) The comparative performance of PMI estimation in skeletal remains by three methods (C-14, luminol test and OHI): analysis of 20 cases. Int J Legal Med 132(4):1215–1224. https://doi.org/10.1007/s00414-015-1152-z
Caruso V, Cummaudo M, Maderna E, Cappella A, Caudullo G, Scarpulla V, Cattaneo C (2018) A comparative analysis of microscopic alterations in modern and ancient undecalcified and decalcified dry bones. Am J Phys Anthropol 165(2):363–369. https://doi.org/10.1002/ajpa.23348
Cohen J (1960) A coefficient of agreement for nominal scales. Educ Psychol Measur 20(1):37–46. https://doi.org/10.1177/001316446002000104
Landis JR, Koch GG (1977) The measurement of observer agreement for categorical data. Biometric 33(1):159–174. https://doi.org/10.2307/2529310
Bell LS (2012) Identifying postmortem microstructural change to skeletal and dental tissues using backscattered electron imaging. Methods Mol Biol 915:173–190. https://doi.org/10.1007/978-1-61779-977-8_11
Runolfsdottir HL, Sigurdsson G, Franzson L, Indridason OS (2015) Gender comparison of factors associated with age-related differences in bone mineral density. Arch Osteoporos 10(1):23. https://doi.org/10.1007/s11657-015-0214-7
Messina C, Sconfienza LM, Bandirali M, Guglielmi G, Ulivieri FM (2016) Adult dual-energy x-ray absorptiometry in clinical practice: How I Report it. Semin Musculoskelet Radiol 20(03):246–253. https://doi.org/10.1055/s-0036-1592370
Kanis JA, Cooper C, Rizzoli R, Reginster JY, Scientific Advisory Board of the European Society for Clinical and Economic Aspects of Osteoporosis (ESCEO), the Committees of Scientific Advisors and National Societies of the International Osteoporosis Foundation (IOF) (2019) European guidance for the diagnosis and management of osteoporosis in postmenopausal women [published correction appears in Osteoporos Int. 2020 Jan;31(1):209] [published correction appears in Osteoporos Int. Apr;31(4):801]. Osteoporos Int 30(1):3–44. https://doi.org/10.1007/s00198-018-4704-5
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The authors wish to thank Prof. Giorgio Marrubini (University of Pavia) and Dr. Camillo Melzi (MetAnalisi) for their suggestions and help provided on R Studio software.
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Bertoglio, B., Messina, C., Cappella, A. et al. Bone tissue preservation in seawater environment: a preliminary comparative analysis of bones with different post-mortem histories through anthropological and radiological perspectives. Int J Legal Med 135, 2581–2594 (2021). https://doi.org/10.1007/s00414-021-02636-6
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DOI: https://doi.org/10.1007/s00414-021-02636-6