Unveiling mode of action of anthelmintics in Caenorhabditis elegans with SydLab™, an on-a-chip automated and high-content screening system

Anthelmintic resistance in parasitic nematodes presents a growing challenge to animal and human health, driving the need for innovative tools to accelerate drug discovery and mechanistic research. Here, we introduce SydLab™, a microfluidic-based, automated phenotypic screening platform that combines continuous imaging, machine vision, and computational analysis for high-content assessment of Caenorhabditis elegans responses to anthelmintics.

We systematically evaluated eight anthelmintic compounds spanning major chemical classes— albendazole, ivermectin, milbemycin oxime, emodepside, levamisole, tribendimidine, monepantel, and closantel—across multiple doses. Using wild-type (N2 Bristol) and mitochondrial stress-sensitive ( hsp-6::gfp ) strains, SydLab™ captured real-time, dose-dependent phenotypic profiles over 120 hours, measuring developmental growth, reproduction, motility, and morphology. Emodepside, monepantel, and macrocyclic lactones induced severe larval arrest, reduced worm volume, and distinct morphological changes consistent with neuromuscular paralysis. In contrast, albendazole and closantel showed limited effects at tested concentrations.

Machine learning-based shape classification revealed drug-specific morphological signatures, including coiling and cuticular damage, offering insights into compound modes of action. Validation with larval development and migration assays confirmed SydLab™’s high sensitivity and reproducibility in detecting subtle phenotypic and strain-specific responses.

Our study demonstrates how integrating microfluidics, automated imaging, and computational phenotyping enables precise dissection of complex drug-induced effects in nematodes. SydLab™ provides a scalable, high-throughput platform for anthelmintic screening and mechanistic studies, offering new avenues for antiparasitic drug discovery and resistance research.

Author summary

Resistance to anthelmintic drugs is a global concern threatening the control of parasitic nematodes that impact human and animal health. New tools are needed to better understand drug effects and accelerate the discovery of effective treatments. In this study, we present SydLab™, an automated microfluidic platform that combines real-time imaging and computational analysis to assess the impact of anthelmintic drugs on the model nematode Caenorhabditis elegans .

By monitoring development, reproduction, motility, and morphology, we identified unique drug-induced phenotypes linked to specific modes of action. Compounds like emodepside, ivermectin, and monepantel caused larval arrest and neuromuscular paralysis, while albendazole and closantel showed limited activity. Machine learning algorithms detected drug-specific morphological patterns, offering deeper mechanistic insights.

Our work highlights SydLab™ as a powerful high-throughput phenotyping system that can reveal subtle biological responses and support the discovery of next-generation anthelmintics. This approach strengthens our ability to investigate drug resistance and improve therapeutic strategies against parasitic nematodes.