TY - JOUR
T1 - Opportunities and Challenges in Applying AI to Evolutionary Morphology
AU - He, Yichen
AU - Mulqueeney, J M
AU - Watt, E C
AU - Salili-James, Arianna
AU - Barber, N S
AU - Camaiti, M
AU - Hunt, E S E
AU - Kippa, O
AU - Knapp, A
AU - Lanzetti, A
AU - Rangel-de Lázaro,, G
AU - McMinn, J K
AU - Minus, J
AU - Mohan, A V
AU - Roberts, L E
AU - Adhami, D
AU - Grisan, Enrico
AU - Gu, Q
AU - Herridge, V
AU - Poon, S T S
AU - West, T
AU - Goswami, Anjali
PY - 2024/9/23
Y1 - 2024/9/23
N2 - Synopsis Artificial intelligence (AI) is poised to revolutionize many aspects of science, including the study of evolutionary morphology. While classical AI methods such as principal component analysis and cluster analysis have been commonplace in the study of evolutionary morphology for decades, recent years have seen increasing application of deep learning to ecology and evolutionary biology. As digitized specimen databases become increasingly prevalent and openly available, AI is offering vast new potential to circumvent long-standing barriers to rapid, big data analysis of phenotypes. Here, we review the current state of AI methods available for the study of evolutionary morphology, which are most developed in the area of data acquisition and processing. We introduce the main available AI techniques, categorizing them into 3 stages based on their order of appearance: (1) machine learning, (2) deep learning, and (3) the most recent advancements in large-scale models and multimodal learning. Next, we present case studies of existing approaches using AI for evolutionary morphology, including image capture and segmentation, feature recognition, morphometrics, and phylogenetics. We then discuss the prospectus for near-term advances in specific areas of inquiry within this field, including the potential of new AI methods that have not yet been applied to the study of morphological evolution. In particular, we note key areas where AI remains underutilized and could be used to enhance studies of evolutionary morphology. This combination of current methods and potential developments has the capacity to transform the evolutionary analysis of the organismal phenotype into evolutionary phenomics, leading to an era of “big data” that aligns the study of phenotypes with genomics and other areas of bioinformatics.
AB - Synopsis Artificial intelligence (AI) is poised to revolutionize many aspects of science, including the study of evolutionary morphology. While classical AI methods such as principal component analysis and cluster analysis have been commonplace in the study of evolutionary morphology for decades, recent years have seen increasing application of deep learning to ecology and evolutionary biology. As digitized specimen databases become increasingly prevalent and openly available, AI is offering vast new potential to circumvent long-standing barriers to rapid, big data analysis of phenotypes. Here, we review the current state of AI methods available for the study of evolutionary morphology, which are most developed in the area of data acquisition and processing. We introduce the main available AI techniques, categorizing them into 3 stages based on their order of appearance: (1) machine learning, (2) deep learning, and (3) the most recent advancements in large-scale models and multimodal learning. Next, we present case studies of existing approaches using AI for evolutionary morphology, including image capture and segmentation, feature recognition, morphometrics, and phylogenetics. We then discuss the prospectus for near-term advances in specific areas of inquiry within this field, including the potential of new AI methods that have not yet been applied to the study of morphological evolution. In particular, we note key areas where AI remains underutilized and could be used to enhance studies of evolutionary morphology. This combination of current methods and potential developments has the capacity to transform the evolutionary analysis of the organismal phenotype into evolutionary phenomics, leading to an era of “big data” that aligns the study of phenotypes with genomics and other areas of bioinformatics.
UR - https://academic.oup.com/iob/article/6/1/obae036/7769702?login=true
U2 - 10.1093/iob/obae036
DO - 10.1093/iob/obae036
M3 - Article
SN - 2517-4843
VL - 6
JO - Integrative Organismal Biology
JF - Integrative Organismal Biology
IS - 1
M1 - obae036
ER -