Despite the prevalence of elephant poaching and ivory trafficking, domestic and international ivory markets around the world are slowly closing due to increased education and enforcement efforts. This includes California’s ivory market in 2016 after the passage of Assembly Bill 96 (AB 96), which prohibits the purchase, sale, offer for sale, possession, or importation with intent to sell, of ivory from elephant, mammoth, and mastodon along with other non-proboscidean species. To assist with enforcement efforts, the California Department of Fish and Wildlife’s Wildlife Forensic Laboratory (CDFW-WFL) has created and implemented a scientific workflow to taxonomically identify, geographically assign, and age California’s seized ivory. Here we discuss the application of this scientific workflow to a 32-piece ivory chess set, which was purchased in 1969 and donated to and examined by the WFL in 2021. Genetic data revealed 11 unique haplotypes and 19 unique genotypes, suggesting a diverse set of African elephants from numerous locations in Africa were used to assemble the chess set. Stable isotope data corroborated these findings and radiocarbon dating suggested the ivory used to carve these chess pieces grew approximately 6 years prior to the chess set being purchased. Our results indicate that the use of a variety of scientific techniques provides a wide scope of information; furthermore, taxonomically identifying, geographically assigning, and aging the ivory chess set demonstrates to law enforcement officers how our ivory workflow can assist them in coordinating efforts locally, nationally, and internationally to help stop the illegal importation of ivory into California.

Ocean currents, driven by gravity, wind, and water density, disperse marine biota worldwide, often leading species to shorelines alive or as carcasses. These carcasses provide vital information about species' health conditions and threats within their habitats. Marine animal strandings thus offer crucial insights into the ecological implications of population mortality. This research is instrumental for conservation efforts and identifying trends and threats. Scientists use human and animal forensics approaches to trace the origins of beached bodies. The capability to backtrack carcass drift and estimate death sites helps evaluate anthropogenic impacts. This information also forms the basis for legal applications and gives ecological indicators for marine megafauna conservation. Using backtracking in forensic ecology for conservation research presents expansive investigative opportunities. This paper offers a comprehensive review of: 1) Physical and environmental processes; 2) Drift applications; 3) Marine megafauna examples; 4) Forensic principles; 5) Postmortem intervals; 6) Marine megafauna backtracking. We further discuss these findings' potential conservation applications for endangered species. Our review aims to enhance understanding of coastal animal distribution, estimate mortality rates from strandings, explore seasonal variations for beach monitoring programs, and investigate anthropogenic impacts.