As defined, forensic science, or forensics, is the application of science to establish how historical events occurred and thereby provide impartial evidence that can be used in a court of law. This may be observed as the use of the scientific methods and processes in crime-solving, within the criminal justice system. Forensic sciences include medicine, biology, dermatoscopy, chemistry, traseology, and computer science. Forensic science can be used to identify decedents or suspects, establish a connection to a crime or crime scene, or prove elements of a crime [7, 22, 50]. The first mention of the use of medicine and biology to solve the crime appeared in the 13th century [46]. Using science to investigate crimes and identify criminals began in the mid to late 1800s. People who had a significant impact on the development of forensic sciences include Ambroise Paré, Fortunato Fidelis, Edmond Locard, Francis Galton, Carl Wilhelm Scheele, Henry Goddard, Hans Gross, Francis Galton, James Watson, Alphonse Bertillon, Sir William Herschel, Sir Alec Jeffreys, Frances Glessner Lee, and many others. They had an impact on the development of forensic medicine, toxicology, chemistry, ballistics, anthropometry, crime scene photography, biology, fingerprinting as well as DNA analyses Now, in the 21st century, forensic scientists have started using modern technologies in crime-solving (e.g. laser scanners, drones, photogrammetry). Thanks to the usage of new testing methods and modern techniques, many cases from many years ago have been solved [10, 19, 36, 41, 49, 50].
We still have to remember that forensic science is derived from biological, engineering, and social sciences, which often deal with issues distant from the world of crime but have been adapted for criminal investigations. There are many forensic sciences and each of them deals with researching a different segment of reality for the criminal trial.
Forensic science connects many sciences from different areas [18, 50]. One of the newer areas of forensic science is microbiology [9, 13, 30, 33, 48]. During an investigation, the main goal for scientists and investigators is to determine who committed the crime, so they have to focus on looking for evidence at the crime scene. Specialists of forensic microbiology may use biological proof to place people at crime scenes, investigate bioterrorism events, or determine the cause of and time of death [8, 11, 33]. Microorganisms isolated from the human body after death could be considered as etiological or a contributing factor to death. Also, the presence of isolated microbes at the crime scene may make it easier to determine the involvement of other people in committing a crime or transporting the corpses to another location after committing homicide [8, 41]. Microorganisms that are present in soil, water, or plants can be released into the air as bioaerosols and can be transported over long distances [37]. Their presence at a crime scene may be evidence or a source of important crime information.
In this article, the author describes the importance and role of bioaerosol in forensic investigations, based on the available information from the literature (including examples from case studies).
Nowadays, one of the fast-evolving multidisciplinary science is aerobiology, related to the study of biological molecules in the air. It is an interdisciplinary science related to various fields of knowledge, including botany, palynology, mycology, phenology, meteorology, and allergology [1]. The air that we breathe consists not only of gases but also contains organic and inorganic particles. Particles of biological origin are present in the air in the form of bioaerosols. Their diameters range from 0.01 µm to 100 µm. The bioaerosol consists mainly of bacteria, fungal spores, viruses, pollen, products or fragments of fungi and bacterial cells (toxins), fragments of plants or insects (and other organic substances or biota) [15, 17, 28, 31]. Bioaerosols are present in enclosed spaces (e.g. inside buildings) and the external environment. Indoors, the presence of bioaerosol may be associated with the presence of humans, construction materials or room furnishings [4, 16]. The main sources of bioaerosol in the external environment are soil, natural and artificial water reservoirs, and living or dead organisms [17, 27, 40]. Also, the municipal waste facilities have a huge impact on the composition of the microbiome of the air (by emitting a specific biological aerosol which is typical for municipal landfills and sewage treatment plants) [5]. Bacteria or fungal spores are released into the atmosphere as a result of their removal from plant or soil surfaces, possibly through wind or thermal convection processes, and after spontaneous or rain forced emissions from natural water reservoirs [3, 37]. Microbes cannot grow during airborne transport but can survive in the air for some time. The survival time depends on the properties of the microorganisms and environmental conditions: access to nutrients and physical or chemical factors of environmental stress. The small components of biological aerosol retain their viability in the environment longer than larger microorganisms. Also, bacterial endospores can survive in the air for a long time. The most sensitive, vegetative forms die quickly. Due to the relatively small size of the cell, the most adapted forms of microorganisms are cocci and bacteria whose cells are covered with a layer of mucus or produce yellow and red carotenoid dyes that protect them from harmful UV radiation [25, 32, 39]. For example, in the air the survival time of
Sampling bioaerosols aims to efficiently capture (as much as possible) all biological particles from the air and then gather them to enable their subsequent detection, i.e. without changing and/or damaging their structure and maintaining their ability to grow on an appropriate microbiological medium. The most commonly used bioaerosol sampling techniques are impaction, filtration, and electrostatic precipitation [28]. The central topics of bioaerosols studies focus on health hazards (especially worker’s health), effects on the atmosphere and climate, or bioterrorism [8, 24–26, 35, 38, 42, 44, 45, 47]. In addition to the fact that bioaerosols can be harmful to humans, they are also significant in other ways.
The fungal spores can be isolated from soils, sediments, vegetation, and plant litter. Fungi can also grow on stones, bricks, wooden objects, leather, plastics, rubber, or textiles. Some of the fungi species that produce dry spores and grow on the aerial parts of living plants will be easier caught up in wind currents and can be transmitted more widely through the air (in low concentrations). The spores of certain species that are present on leaves (e.g.
Specialists in biology and forensic science point out the importance of microbiology, palynology, and mycology in investigations of committed crimes [1]. One of the factors that affect the possibility of resolving a crime are traces – amounts of material that might be valuable in a court as evidence. The cases described by Hawksworth and Wiltshire [22], show that microorganisms present in the air may be useful for this purpose. According to the authors, a young woman’s body was found dumped in plants called ‘stinging nettles’ (
Fungal spores present in the air (in the form of a biological aerosol) can likewise affect the colonization of exposed human bones (under favorable conditions and long-time exposure). Also, the sporing cycle of fungi can help in determining the time of events. In one of the cases conducted in London, in 2004, it was possible to determine when the body of a young woman was placed in a shallow grave. It was possible due to the presence of black pustules on the underside of the leaves (present in the grave), while the leaf’s tissue associated with them was red-purple. It was caused by one plant rust pathogen –
For forensic purposes, it is more important to determine the degree of similarity of the samples taken than to identify 100% of all the pollen grains or spores revealed in the samples from the crime scene. Plant pollen is carried by vectors, mostly by wind (in the form of bioaerosol). So, pollen and spores are carried up and away from the parent plant. Pollen derived from wind-pollinated plants are common components in the airspora and are often over-represented. Crime scenes are often dominated by self-pollinated plants. In this case, the pollen falls to the ground around the plant and rarely gets into the air but it may be the most abundant on an item of footwear. In this situation, pollen from the air at the crime scene may form only a small proportion of the profile relevant to the criminal investigation. Pollen and spores can be relatively easily determined, collected, protected, and tested. The diversity of pollen and spores means that samples taken at a distance of several meters from each other may have different characteristics, and this can be a very valuable clue for establishing evidence [2, 6, 20, 34, 54, 56].
The importance of pollen in crime investigations can be illustrated by a case from South Wales, where a murder victim was buried on a hillside dominated by
Plant pollen is most often revealed on clothing, footwear (with mud or soil), or other objects (paintings, furniture, firearms, documents). During breathing, sporomorphs (in the form of bioaerosol) are absorbed into the human respiratory tract and then penetrate the nasopharynx and lungs. Pollen was also isolated from the content from the coronary tract, and – in the form of a biological aerosol – can stick on hair (especially on the head) and may stay there longer than on the body surface (it does not wash out and rinse so quickly). It confirms that plant pollen (as bioaerosol component) present in the environment may constitute evidence in criminal casework [55, 56].
Aerosol particles also include cellular material and proteins emitted by humans and can be considered biological information – particles that carry biochemical information specific to living organisms. For example, living organisms, including humans, constantly emit a great deal of dead skin cells into the environment. Nowadays, with the development of analytical techniques, these particles could be isolated and characterized in terms of biochemistry. It may seem that a lot of biological structures and metabolic pathways are common to all people resulting in apparently common biochemical profiles, but these pathways and structures exhibit extensive polymorphisms and divergent post-translational modifications that reflect individual genetics. It can have a big impact and significance for development of biochemical forensics or medical profiling. Also, the concentration, degradation and type of aerosol may depend on human presence at a specified place and time, and maybe this information can be used during crime investigation and court proceedings [12, 13].
Forensic microbiology is a science that is constantly evolving. Microbiological analysis of the evidence of crimes can influence the determination of potential offenders. Bioaerosols may have a huge importance in tracking down crime suspects. As the cases (described in the literature) show, biological material – in the form of bioaerosol – can be important evidence at crime scenes and bioaerosol analysis would appear to be an important tool that can be used during crime investigations.