University of Maine graduate student Christine Conte in 2018 counting small mammals and tick attachments for a study of tick populations in managed and unmanaged forest plots. Courtesy of Allison Gardner

Active management of forests, including timber harvesting to meet silvicultural objectives, can influence the transmission dynamics of tick-borne diseases such as Lyme, anaplasmosis and babesiosis, according to a new study by a team of University of Maine researchers.

Christine Conte, an ecology and environmental sciences student who earned a master’s degree from UMaine in 2019, led the study of blacklegged tick populations in recently harvested and unharvested forest plots to determine the impact of forest management on nymphal tick abundance and infection prevalence. The study was conducted in Hancock County on privately owned small woodlots and land trust properties.

Using trail camera videography to capture large mammal visits to the study plots, live small mammal trapping and tick counts, vegetation surveys and off-host tick collection methods, Conte, and faculty members Allison Gardner and Jessica Leahy gathered data from forest plots harvested in the last five years and those unharvested for at least 20 years. 

The researchers found that recently harvested forest plots hosted fewer small mammals and blacklegged tick nymphs, and reduced densities of adult blacklegged ticks as compared to the unmanaged control plots. Microclimate analysis revealed significantly higher temperature and vapor pressure deficits (VPDs) in the recently harvested parcels, conditions which may limit tick-host interactions, and reduce tick longevity and questing behaviors. 

A subset of blacklegged ticks collected from all sites in year one of the two-year study were tested for the pathogens Borrelia burgdorferi, Anaplasma phagocytophilum and Babesia microti. Active forest management, which was shown to limit nymphal tick populations and the density of adult ticks, reduce host density to divert blood meals away from pathogen competent hosts, and create environmental conditions that reduce tick viability, did not appear to impact infection prevalence among blacklegged tick nymphs. 

Twenty percent of blacklegged ticks tested positive for B. burgdorferi, the causative agent of Lyme disease; 2 percent were positive for A. phagocytophilum, which causes human granulocytic anaplasmosis; and 3 percent were positive for B. microti (human babesiosis). Results suggest that overall, the density of nymphs rather than nymphal infection prevalence drives entomological risk of infection with tick-borne disease in this system. 


The team’s findings, published in the journal EcoHealth, suggest that managing  forests to support forest health may also provide a sustainable method of reducing the risk of exposure to pathogens and zoonotic diseases via biotic and abiotic tick control mechanisms that impact habitat quality. Ongoing research efforts, including the Maine Forest Tick Survey, seek to build upon these findings.