Edda Guareschi

Microplastics (MP) are ubiquitous in the environment, and have been detected in the tissues of several species. Limited studies quantify the presence of MP in food producing species, including sheep. Here, MP were screened in tissue samples from Australian sheep using low-cost methodologies, with the aim of enabling their subsequent chemical characterization and quantification. Samples of several organs from six sheep were prepared using (i) a standard digestion and filtration protocol, and (ii) a novel impression smear method. Both methods involved staining with Nile Red (10µg/ml) and observation by fluorescence microscopy. Suspected MP were detected in 32.3% (10/31) of digestion samples, 51.6% (16/31) of smear samples and 50.0% (8/16) of controls. Such results will direct further research aimed at contributing to food safety and public health policies focused on animal and human health.

Bone taphonomy and diagenesis contribute to anthropological analysis in forensic investigations by attempting to reconstruct the relationship between human cadaveric remains and their postmortem depositional environment. The rare aquatic taphonomic experiments have been delivering conflicting results on the influence of time and the environment on the decay of bone and teeth, especially considering that the main diagenetic processes can lead to fragmentation, progressive dissolution or fossilization. The aim of this experimental, quantitative, randomized and controlled 2-year study was to analyse the taphonomy and diagenesis of submerged terrestrial mammalian bones to achieve a more accurate estimation of both the post-mortem interval (PMI) and the post-mortem submersion interval (PMSI) in the short term. Three parameters of bone diagenesis, the Oxford Histological Index (OHI), the total porosity and the collagen content of cortical bone were analysed by MicroCT Scan, bright-field Light Microscopy (Picrosirius Red stain), Scanning Electron Microscopy (SEM) and Laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) on 75 sheep femurs and tibias placed in four distinct types of environment (natural saltwater, natural freshwater, an artificial seawater solution and exposed to the air) vs. non-exposed controls. LA-ICP-MS was soon discontinued because no measurable changes of the elemental profiles could be detected. Multivariate statistical analysis was applied to the collected data. The macroscopical preservation was consistently excellent (OHI=5). The total porosity and the degradation of collagen were greater underwater than in subaerial exposure, whereas demineralization zones and bioerosion tunnelling appeared after 12 months in the air-exposed samples only. Underwater, the continuous movement, the correlated abrasion by sand and sediment and the constant alkaline pH (≥ 8) can explain the progressive removal of the mineral component and the subsequent exposure of collagen to bioeroders and chemical hydrolysis. On land, the same process occurs at a slower rate on account of the seasonality of the water flow, however, the action of the more abundant and diversified species of bioeroding microorganisms appears more efficient. Despite some limitations, this study indicates that three parameters of bone diagenesis can predict the depositional environment of terrestrial mammalian bone characterized by a PMI and/or PMSI of at least 12 months.

The understanding of the victim's decomposition process is crucial in forensic science for establishing accurate time since death, and the overall timelines of criminal investigations. Global research, which primarily relies on non-human animal proxies, highlights a scarcity of facilities using human bodies and a lack of baseline data for some regions and remote locations. In cases such as the Andaman and Nicobar (A&N) Islands (India), forensic practitioners turn to literature-derived patterns developed at the closest locations (mostly mainland India). This study examines 51 human decomposition cases investigated in A&N in comparison with the existing literature, emphasizing distinctions and similarities in their decomposition relative to the current Indian literature. This study advocates for further research and potentially calls for the establishment of the first anthropology research facility in the Indo-Pacific region, encouraging the development of tailored methodologies for more accurate estimations in diverse environments.

In March 2022, human remains were discovered submerged 15 metres underwater, near Cubagua Island, Venezuela. The remains were intricately entangled and secured to the seafloor. The investigation was conducted by the Servicio Nacional de Medicina y Ciencias Forenses (SENAMECF) of Venezuela, and it involved an underwater recovery operation, followed by a comprehensive examination. The medicolegal, anthropological, odontological, and taphonomical analyses alongside diatom test were conducted to ascertain the identity of the remains, determine the cause of death, and estimate the post-mortem interval (PMI)/post-mortem submersion interval (PMSI). Collaborative efforts with international experts on adipocere and barnacle analyses allowed for the refinement of the enhanced the precision of information provided in plea announcements, which facilitated the identification of the subject. Forensic analyses on incomplete and highly decomposed human remains present inherent complexities, which are exacerbated in underwater environments. Compounded by the limited experience and expertise in aquatic forensics among law enforcement agencies worldwide, the present case exemplifies a successful professional collaboration that surmounted a diverse array of challenges. This case underscores the critical importance of knowledge-sharing within the continuously evolving field of forensic science, serves as an illustrative example, and provides guidelines for the investigation of similar cases in the future.

The taphonomy and diagenesis of bone and teeth recovered from any environments provide crucial information for forensic sciences and investigations. This leads to the estimation of the postmortem interval (PMI) and the postmortem submersion interval (PMSI) of the organism/s. Aquatic taxa can induce macroscopic and microscopic alterations in biomineralized tissues (e.g., grooves) or can colonize them by attachment (e.g., Bryozoa). Bryozoa are tiny invertebrates that form colonies in freshwater and saltwater. They can survive for years as suspension feeders in all climates. Most marine Bryozoa species have a biomineralized exoskeleton that can be preserved after their death. This research analyzes eight fragments of archeological elephant ivory with a known PMSI of 314 years, which were inhabited by three distinct bryozoan colonies. The variations in the preservation of the bryozoan exoskeletons and the overgrowth of different marine taxa reveal that one colony (lichenoporid cyclostomatid) was alive at the time of the ivory collection from the submerged archeological site while the two other colonies (cheilostomatid) had previously died at different times. The primary objective of this observation is to contribute to the understanding of the taphonomy of terrestrial mammalian biomineralized tissues recovered in marine environments. Additionally, the study discusses the potential forensic implications of this association, such as the evidence of marine submersion and the PMSI. A secondary objective is to present the Bryozoa colonies within a distinctive depositional context, considering that many bryozoan species of the Western Australian coast remain undescribed. The complexity of the Bryozoa ecobiology is also highlighted, with the need of further research (e.g., minimum time for colonization). Finally, this study highlights the urgency of multidisciplinary collaboration to advance aquatic forensic capabilities.

The estimation of the post-mortem submersion interval (PMSI) of skeletal remains can provide critical information to forensic investigations, contributing to various aspects such as identification. A fundamental aspect of the PMSI estimation in bone is the degradation of collagen, the most abundant organic component. This degradation can be assessed using various analytical techniques, including the digital analysis of images taken from histological slides. Two open-source software for image digital analysis, ImageJ® and Orbit®, provide novice-friendly and accessible technology to a broad audience of forensic practitioners. However, the absence of established procedures can challenge the consistency of the interpretation of the results, especially between observers. The principal aim of this study was to compare the efficacy of ImageJ® and Orbit® in quantifying the degradation of collagen in images taken from histological slides of mammalian non-human bones submerged for 4 months to 2 years. Despite the inconsistency in the outcomes of intraobserver vs. interobserver testing, this research has demonstrated the promising potential of digital histology. It has also identified the need for further investigation, particularly focusing on the usability of ImageJ® and the refinement of the Orbit® workflow.

Since the 1940s, when maritime archaeology was established, the systematic excavation of submerged wrecks began to be refined. Systematic excavations led to the recovery of a vast array of organic and inorganic artefacts, including human and non-human bones and teeth. In order to preserve the materials recovered from the sea, the discipline of maritime conservation rapidly expanded and dealt with unique issues, including, but not limited to, marine salts' encrustation of archaeological artefacts. Bone and teeth are organic artefacts which provide crucial information about natural and social environments of the past. When recovered from marine settings, they are often friable and require conservation processes and consolidation treatments, e.g., to prevent shrinkage during drying. However, conservation processes and consolidants can interfere with pathological, traumatic and taphonomical evidence associated with bone and teeth, and can bias sample preparation and analysis through mechanical action and chemical composition. The aim of this paper, in which a few examples of interference are listed, is to highlight the need of accurately documenting any type of conservation process and/or consolidation treatment that has been performed on bone and teeth stored in archaeological collections. This becomes essential when samples are selected for study, especially if this includes destructive analysis, and will assist in clarifying any conflicting results, leading to reliable interpretations.

Archaeoentomology is the study of insects and other arthropods recovered from an archaeological site; they can be found in association with ancient human and animal remains, food, artefacts or they can be related to the environment and its changes throughout the time. Within archaeoentomology, the branch of "funerary archeoentomology" considers insects and other arthropods especially in association with human remains in funerary and burial contexts. The presence and the location of certain insect species closely associated with or nearby the remains, can be valuable in gathering information about the ecological situation at the time of burial and the changes that occurred in the environment up until the discovery of the body. Funerary archaeoentomology investigations have been carried out globally, primarily in countries like Italy, Peru, the United Kingdom and France. Similarly to forensic entomology contexts, the abundance and diversity of insects are affected by the type of burial, the macro and micro-environment of and surrounding the burial, the items associated with the cadaver, the post-mortem practices, and the time that has elapsed from the body deposition to the discovery and the excavation. While funerary archaeoentomology and forensic entomology remain two well-distinguished disciplines, the sampling practice, the insect identification process, and the analyses of the burial ecology in funerary archaeoentomology studies follow the best practices and the general guidelines of forensic entomology. In both disciplines, the correct identification of the insects is key to providing correct information. Various methods have proven effective for insect identification, i.e., morphological, molecular and chemical analysis. This review aims to collect the current knowledge in funerary archaeoentomology, discuss the strengths and weaknesses of insect identification methods in an archaeological context, and describe the groups of the most relevant insects and other arthropods found in association with ancient human remains worldwide. Furthermore, recommendations will be provided to advance the practices of archaeoentomology examinations.

Bone and teeth, specialised bio-mineralized connective tissues, are left after the typical decomposition process of any vertebrate organism. Their analysis can reveal insights into an organism's life and retrace the history of the remains after death (also known as taphonomy), which ultimately evolves to destruction or fossilization. Studies on the taphonomy of terrestrial mammalian bio-mineralized tissues have mostly focussed on terrestrial depositional environments. Here, samples submerged in the marine environment are investigated.

Five archaeological bones of terrestrial mammalian species (pig and oxen) with historically known post-mortem submersion interval (PMSI) (69–316 years) and recovery sites, were analysed macroscopically, microscopically and by microCT. The aim was to characterize for the first time the alterations produced by marine bioeroding sponges, and to discuss their potential interdisciplinary application, with special focus on forensic investigations.

The pig samples showed microanatomical preservation (Oxford Histological Index = 3–5), increased total porosity, the presence of old tissue flakes with sponge spicules and traces of bioerosion, such as papillary holes, canals and chambers with microsculptured walls. The presence of such tissue flakes suggested that, at the time of recovery, they may have been free of sediment and inhabited by live sponges. The shape of one internal chamber was identified as the ichnospecies Entobia convoluta as typically produced by shallow, warm-water Cliothosa spp. Surface analyses for further biological evidence remained inconclusive.

The taphonomy of skeletal remains has always been relevant in anthropological, natural and forensic studies. In forensics, the role of taphonomy is to contribute to personal identification, cause of death and post-mortem interval (PMI). This study detected the past colonization of terrestrial mammalian bone by marine bioeroding sponges, and aimed to link the taphonomic findings to natural processes and environments. Bioeroding sponges are for the first time confirmed to colonize terrestrial mammalian bone submerged in marine environments, and to promote diagenesis through bioerosion.

Tadalafil is an inhibitor of the human enzyme cyclic guanosine monophosphate–specific phosphodiesterase, type 5 (PDE-5). As a mild vasodilator, it is primarily used for the treatment of erectile dysfunction, an increasingly common condition in men. It is also used for treatment of benign prostatic hyperplasia and pulmonary arterial hypertension. Adverse events of this drug are rare. Absolute contraindications include serious cardiac disease. Despite the widespread use of tadalafil, very little is known about its toxicology in forensic pathology and its association with post-mortem redistribution. This study presents a forensic case with possible contribution of tadalafil. The administration of tadalafil might act as a concurrent cause or contributing factor for lethal cardiogenic shock in people with cardiac disease.