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Common vampire bat

The Common vampire bat (Desmodus rotundus), the most widespread of the three extant vampire bat species, is a small, leaf-nosed bat in the family Phyllostomidae, subfamily Desmodontinae, measuring 70–90 mm in length and weighing 15–50 grams, with dark brown fur, no external tail, and specialized sharp incisors for piercing skin. Endemic to the Neotropics, it ranges from sea level to elevations of 3,600 m across northern Mexico through Central America to central Chile and northern Argentina, with models predicting potential northward expansion into the southern United States due to climate change as of 2025, inhabiting diverse ecosystems including tropical forests, savannas, grasslands, deserts, and disturbed agricultural areas. These bats are highly social, roosting in colonies of 10 to over 5,000 individuals—typically female-dominated—in humid, dark sites such as hollow trees, caves, mine shafts, wells, and abandoned buildings, where they maintain constant temperatures for resting during the day. Exclusively hematophagous, D. rotundus feeds nocturnally on blood from a broad array of vertebrates, consuming 20–30 mL per meal—about 20–50% of its body weight—from primarily medium- to large-bodied mammals like livestock (cattle, horses, pigs) and wildlife (tapirs, peccaries, deer, capybaras), with occasional birds and rare human bites. It locates prey using heat-sensing receptors on its nose to detect blood flow and can identify targets by breathing sounds, approaching stealthily on foot with a hopping gait before making painless incisions with its self-sharpening fangs and lapping the flowing blood, which its saliva anticoagulates via enzymes like draculin to prevent clotting. Foraging within 5–8 km of roosts, these bats exhibit reciprocal altruism, regurgitating blood to share with starving roostmates regardless of relatedness, alongside allogrooming and complex social bonds akin to primate friendships, which enhance colony survival. Reproductively, females reach maturity at 9–10 months, with a 7-month gestation yielding single pups birthed bimodally (peaking April–May and October–November), nursed for about 9 months; wild lifespan averages 9 years, extending to 20 in captivity. Ecologically, D. rotundus populations thrive with livestock expansion but pose significant challenges as the primary reservoir and vector for rabies virus in Latin America, transmitting it to cattle, wildlife, and humans via bites and causing economic losses exceeding millions annually, while also carrying pathogens like Bartonella and coronaviruses. Despite their vampiric reputation, these bats play roles in biodiversity and inspire medical research, such as stroke treatments derived from their saliva.

Taxonomy and phylogeny

Classification

The common vampire bat is scientifically classified under the binomial name Desmodus rotundus (É. Geoffroy Saint-Hilaire, 1810). It belongs to the order Chiroptera, the family Phyllostomidae (New World leaf-nosed bats), the subfamily Desmodontinae (vampire bats), and the genus Desmodus. The subfamily Desmodontinae comprises three extant species of obligate sanguivorous bats: the common vampire bat (Desmodus rotundus), the hairy-legged vampire bat (Diphylla ecaudata), and the white-winged vampire bat (Diaemus youngi). The basionym for D. rotundus is Phyllostoma rotundum, as originally described by Geoffroy in 1810; historical synonyms include Vampyrus rotundifolius, Rhinolophus ecaudatus, Desmodus rufus, Phyllostoma infundibuliforme, Edostoma cinerea, and Desmodus murinus. The type locality was designated as "Paraguay" in the original description and later restricted to Asunción, Paraguay, by A. Cabrera in 1958. Within the subfamily Desmodontinae, D. rotundus shares a close phylogenetic relationship with D. ecaudata and D. youngi, forming a monophyletic group specialized for .

Evolutionary

The common vampire bat (Desmodus rotundus) belongs to the Desmodontinae, one of the earliest-diverging lineages within the family Phyllostomidae, with molecular phylogenetic analyses estimating the divergence of Desmodontinae from other phyllostomid bats around 20 million years ago during the early Miocene. This split coincided with the initial adaptive radiation of Phyllostomidae in the Neotropics, where sanguivory emerged as a specialized dietary niche, distinguishing vampire bats from their primarily insectivorous, frugivorous, or nectarivorous relatives. The evolution of blood-feeding likely provided access to a stable, nutrient-rich resource in forested environments, driving morphological and physiological specializations unique to this . Fossil evidence for Desmodontinae is limited but indicates a relatively recent origin compared to the molecular divergence estimates, with the oldest known specimens dating to the Pliocene-Pleistocene boundary approximately 3-4 million years ago. A notable example is a giant vampire bat fossil from the El Breal de Orocual asphaltic deposits in Venezuela, representing one of the earliest records of the subfamily and suggesting that larger body sizes were present in early desmodontines. Later Pleistocene fossils include Desmodus draculae, an extinct giant relative up to 30% larger than modern D. rotundus, known from sites in Argentina, Brazil, and Mexico dating back at least 100,000 years, which highlight the historical diversity and northward expansion of vampire bats during the Quaternary. Mitochondrial DNA analyses have elucidated the phylogenetic relationships within Desmodontinae, confirming the close monophyletic grouping of the three extant vampire bat genera—Desmodus, Diphylla, and Diaemus—with Desmodus rotundus exhibiting the broadest distribution and significant intraspecific population structure shaped by Pleistocene vicariance events. These genetic studies, based on cytochrome b and control region sequences, reveal low gene flow among populations, underscoring D. rotundus as the most derived and widespread member adapted to diverse Neotropical habitats. Key evolutionary adaptations for sanguivory include the development of anticoagulant components in saliva, such as draculin, a glycoprotein that inhibits coagulation factor IXa and originated through the co-option of an ancestral lactoferrin-like protein in the Desmodontinae lineage. This innovation, evolving alongside blood-feeding specialization, enabled efficient meal consumption by preventing clotting at wound sites, representing a critical step in the transition to obligate hematophagy around 10-15 million years ago.

Physical characteristics

Morphology

The common vampire bat (Desmodus rotundus) is a small-bodied species, with adults typically weighing 25–40 g and possessing a forearm length of 52–64 mm. The head and body length ranges from 68–93 mm, while the wingspan extends to 350–400 mm. It is tailless, with a greatly reduced uropatagium between the hind limbs. Distinctive external features include short, rounded ears; a compact, swollen muzzle lacking the prominent leaf-shaped nose structure found in most other phyllostomid bats, instead featuring only a simple fold over the nostrils; and a long thumb armed with a sharp claw for gripping surfaces. The pelage varies from dark brown to grayish, appearing lighter on the ventral surface compared to the dorsal side. The dentition is highly specialized, with large, razor-sharp upper incisors and canines suited for piercing, and ; the molars are notably reduced, with only one per side in each jaw to accommodate a liquid diet. Skeletal features emphasize robust forelimbs, which support quadrupedal movement on the ground through strengthened bones and joints in the shoulder and elbow regions.

Sensory and physiological adaptations

The common vampire bat (Desmodus rotundus) employs a suite of sensory adaptations tailored to its nocturnal, hematophagous lifestyle, with echolocation serving primarily for navigation rather than prey detection. Unlike many insectivorous bats that rely heavily on high-frequency echolocation for foraging, D. rotundus produces echolocation calls typically in the 40-100 kHz range, with peak frequencies around 60-70 kHz, enabling orientation and obstacle avoidance during flight in cluttered environments. However, for locating suitable prey, the bat depends more on olfaction and vision; its acute sense of smell allows detection of host breath and body odors from distances up to 1 meter, while large eyes facilitate visual identification of potential targets in low-light conditions. Complementing these, specialized infrared-sensitive pit organs on the nasal region detect thermal radiation from blood vessels, enabling precise targeting of warm, vascular sites on homeothermic prey even through fur or feathers. These pit organs contain heat-sensitive membranes innervated by trigeminal nerve fibers that respond to infrared wavelengths around 10 μm, providing a thermal imaging capability unique among mammals. Salivary adaptations in D. rotundus are critical for sustaining blood flow during feeding, featuring potent anticoagulants and vasodilators that counteract host hemostatic responses. The primary anticoagulant, draculin, is a glycoprotein that selectively inhibits coagulation factors IXa and Xa, preventing clot formation and maintaining liquidity of ingested blood for up to 24 hours post-feeding. Additionally, vasodilatory peptides in the saliva, such as those acting on calcitonin gene-related peptide receptors, induce localized vessel dilation to enhance blood flow and reduce bite-site pressure, minimizing detection by the host. These components are secreted in high concentrations during feeding, ensuring efficient meal acquisition of 20-30 ml of blood in under two minutes. Metabolically, D. rotundus exhibits remarkable adaptations to its exclusive blood diet, including rapid digestion and energy conservation strategies to cope with irregular feeding schedules. The bat's digestive system processes blood swiftly, with plasma water absorbed in the stomach within minutes and proteins broken down in the intestine over 1-2 hours, allowing excretion of concentrated urine mid-meal to avoid weight overload during flight. Genomic analyses reveal losses in genes for lipid metabolism and vitamin synthesis, reflecting reliance on blood-derived nutrients, while elevated protein catabolism supports energy needs during fasting periods of up to 72 hours. This high tolerance for nutrient scarcity is further evidenced by reduced basal metabolic rates during food deprivation, enabling survival on infrequent, protein-rich meals.

Distribution and habitat

Geographic range

The common vampire bat (Desmodus rotundus) is native to the Neotropical region of the Americas, with its range extending from northern Mexico southward through Central America to northern Argentina and central Chile. This distribution encompasses a broad latitudinal span from approximately 28°N to 33°S, covering diverse ecosystems across the mainland. The species is notably absent from the Baja California Peninsula in Mexico, southern Chile, and most Caribbean islands, though it occurs on Trinidad, Tobago, and Margarita Island off the coast of Venezuela. Historically, D. rotundus underwent a post-Pleistocene expansion southward following the last glacial maximum, with genetic evidence indicating demographic expansions and population structure shaped by Pleistocene vicariance events in regions like the Amazon and Atlantic Forest. Fossil records from late Pleistocene and Holocene deposits confirm its presence in southern limits, including sites in Argentina and Chile, supporting a gradual colonization of these areas as climates warmed. Recent occurrence data compiled up to 2022 document D. rotundus presence in at least 25 countries across North, Central, and South America, with over 39,000 reports from 7,576 unique locations derived from scientific literature, museum records, and field surveys. Density maps from these datasets highlight higher concentrations in Mexico (over 7,600 reports), Colombia, Peru, and Argentina (each exceeding 2,000 reports), reflecting ongoing monitoring efforts for rabies transmission risks. The species occupies an altitudinal range from sea level to 3,600 meters, particularly along Andean slopes.

Habitat preferences and environmental influences

The common vampire bat (Desmodus rotundus) prefers tropical and subtropical environments, including forests, savannas, and agricultural landscapes, where it can access mammalian hosts for feeding. These bats exhibit broad habitat tolerance, occurring from sea level to elevations over 3,500 meters across diverse ecosystems ranging from rainforests to more open arid areas. Roosting sites are typically selected in hollow trees, caves, crevices, abandoned mines, and human-made structures such as buildings and wells, which provide shelter near foraging grounds. Roosting ecology emphasizes colonial living in groups of 20 to 1,000 individuals, often favoring dark, humid, and warm sites that maintain stable microclimates and facilitate social interactions like grooming and food sharing. These preferences support predator avoidance and ectoparasite minimization while keeping colonies close to water sources and livestock, enhancing foraging efficiency. Environmental changes, particularly climate warming, are projected to drive northward range shifts for D. rotundus, with models indicating expansions of up to 200 km by 2080 under high-emission scenarios, alongside increased suitable habitat overall but losses in tropical core areas like the central Amazon. Key climatic drivers include rising minimum temperatures in the coldest month and altered precipitation patterns, potentially exacerbating rabies transmission risks in newly suitable regions such as the southern United States. Anthropogenic influences, including deforestation and urbanization, have enabled D. rotundus to thrive in modified landscapes by increasing access to domestic livestock and providing alternative roosts in human infrastructure. This species demonstrates high tolerance for deforested and urbanized areas, leading to range expansions in anthropized neotropical environments and heightened human-wildlife interactions.

Behavior and ecology

Foraging and feeding

The common vampire bat (Desmodus rotundus) maintains an exclusively sanguivorous diet, subsisting solely on vertebrate blood obtained through hematophagy. A comprehensive 2023 review documented 63 prey species, comprising 47 mammals (75.4% of total) such as livestock (e.g., cattle, goats) and wildlife (e.g., deer, tapirs), alongside 7 bird species, reflecting opportunistic selection based on prey availability and accessibility. Bats preferentially target large, social, diurnal mammals that rest in groups at night, with cattle comprising the most frequently reported prey due to their abundance in anthropogenic landscapes. Foraging occurs nocturnally, with bats departing roosts in early evening and traveling typical distances of 5-10 km, up to 20 km to reach suitable feeding sites, often navigating via echolocation to locate prey in pastures or forests. Upon arrival, the bat lands quietly on the ground near a sleeping or resting animal and approaches on foot using quadrupedal locomotion, relying on keen hearing and tactile cues to avoid detection. Once positioned, it climbs onto the prey and selects a vascular site, such as the neck or heel, for feeding. Feeding mechanics involve specialized adaptations for efficient blood extraction without deep penetration. The bat's upper incisors, razor-sharp and blade-like, create a shallow (3-5 mm) incision in the skin, producing a steady flow of blood that the bat laps up with grooved movements of its tongue at rates of approximately 4 laps per second. Saliva plays a critical physiological role, containing potent anticoagulants like draculin that inhibit clotting by targeting thrombin, ensuring unimpeded flow during the 20-40 minute feeding bout. A single meal yields 20-30 ml of blood, representing 50% or more of the bat's body mass (typically 25-40 g), providing essential nutrients but necessitating rapid digestion and diuresis to reduce weight for return flight. This high intake supports the bat's high metabolic demands, as it must feed every 1-2 nights to avoid starvation.

Social structure and cooperation

The common vampire bat, Desmodus rotundus, exhibits a harem-based social organization characterized by stable groups of related adult females and their offspring, with males maintaining territories that overlap with these female harems. These female groups, typically consisting of 8-12 individuals, roost together in specific hollow trees and demonstrate kin-biased associations that promote group cohesion. Adult males defend feeding territories but join female roosts temporarily for mating, without forming long-term bonds with the group. A hallmark of their cooperation is reciprocal food sharing through regurgitation of blood, often termed vampire bat altruism, where successful foragers donate meals to unsuccessful roost-mates, particularly kin and frequent associates. This behavior, first documented in wild populations in the 1980s, enhances survival rates for recipients who might otherwise starve after two nights without feeding, and donors benefit from future reciprocation independent of kinship. Subsequent studies confirm that such sharing occurs more frequently among bats with prior grooming or roosting associations, providing mutual direct fitness benefits beyond kin selection. Communication in these colonies relies on vocalizations and physical grooming to maintain social bonds. Contact calls, produced by isolated adults, vary by individual and colony and serve to attract past food-sharing partners or reunite group members. Allogrooming, where bats mutually clean each other's fur, reinforces relationships and reduces ectoparasite loads, with vampire bats dedicating 1.5-6.3% of awake time to this activity—far higher than in other bat species. Roost group sizes exhibit fission-fusion dynamics, with subgroups forming and dissolving based on resource availability and seasonal changes in roost conditions, leading to variable colony compositions over time. While overall colonies can number in the hundreds, core female units remain stable across years, adapting to environmental shifts like tree availability during dry seasons.

Reproduction and development

The common vampire bat (Desmodus rotundus) employs a polygynous mating system, where dominant adult males defend access to groups of females within roosts and mate with multiple partners, often leading to multiple paternity within litters. Lek-like courtship displays are rare, with mating typically occurring opportunistically in the colony during nighttime hours. Females are monoestrous, undergoing one reproductive cycle annually, with births peaking from April to July in tropical regions to coincide with increased food availability during the rainy season, with peaks varying by region, often bimodal in alignment with rainy seasons (e.g., April-May and October-November in many areas). Gestation lasts 205–215 days, after which a single pup is born, though twins occur rarely. Newborn pups weigh approximately 5–7 g and are altricial but mobile, clinging tightly to their mother's fur or nipple immediately after birth. Pups remain highly dependent on maternal care for 7–9 months, during which time mothers carry them while roosting and foraging for the first 1-2 months. Pups begin to fly after 4-5 months of age, achieve foraging independence around 10 months through regurgitation of blood from adults, and full weaning by 9 months. Allomaternal care is prevalent in colonies, with non-maternal females providing grooming, nursing, and food sharing to pups, particularly orphans, enhancing pup survival through cooperative behaviors.

Conservation and threats

Population status

The common vampire bat (Desmodus rotundus) is classified as Least Concern on the IUCN Red List, a status reflecting its broad geographic distribution across Central and South America and its remarkable adaptability to diverse habitats, including human-altered landscapes. This assessment, last formally updated in 2015, indicates no immediate risk of extinction due to the species' large and presumed stable populations. Population estimates suggest that D. rotundus is abundant in suitable Neotropical habitats, particularly those supporting livestock, where the species thrives due to reliable blood meal sources. Roost colonies typically range from 10 to several thousand individuals, and a comprehensive 2022 database documents 39,120 occurrence records across 7,576 unique geographic locations, underscoring its widespread presence and ecological success in modified environments. While precise range-wide totals are unavailable, local studies report densities varying from 1 to 3.5 individuals per km² in surveyed areas, with higher abundances near agricultural zones. Overall population trends appear stable to increasing in human-modified landscapes, driven by expansion into deforested and ranching areas that enhance foraging opportunities. In contrast, densities remain low or show local declines in pristine forest habitats, where natural prey scarcity limits growth. These patterns highlight the species' opportunistic nature, with agricultural development correlating to range expansions observed over the past century. Monitoring efforts for D. rotundus populations rely on established bat survey techniques, including mark-recapture methods to quantify local abundances and roost dynamics, as demonstrated in livestock-focused studies in regions like Yucatan, Mexico. Acoustic surveys, leveraging the species' low-frequency social and navigational calls, complement these by enabling non-invasive detection of activity and distribution across larger areas. Such approaches provide critical data for tracking trends amid environmental changes.

Major threats

The common vampire bat (Desmodus rotundus) faces significant habitat loss primarily driven by deforestation, which reduces available roost sites in natural forests such as hollow trees and caves. Anthropogenic pressures, including agricultural expansion and urbanization, have paradoxically expanded the species' overall range by creating new foraging opportunities near livestock, but they simultaneously fragment core habitats, leading to isolated populations vulnerable to local extirpation. A 2025 study in Biological Conservation highlights how these human-modified landscapes reshape bat distributions, increasing edge effects and reducing connectivity in undisturbed forest areas essential for roosting and social behaviors. Climate change poses another major threat through predicted distributional shifts, with models forecasting southern range contraction in tropical regions due to warming and drying conditions, while northern expansion into subtropical areas like southern North America becomes more likely under future scenarios. These shifts, detailed in a February 2025 Scientific Reports article (Nature portfolio), could expose new ecosystems to the bat's presence, potentially altering ecological dynamics and facilitating unintended interactions. Such changes risk exacerbating pressures on the species by pushing populations into suboptimal habitats with varying resource availability. Persecution remains a direct anthropogenic threat, as culling programs targeting vampire bats due to rabies transmission fears continue across Latin America, often employing anticoagulant poisons applied as pastes to captured individuals. These methods, which rely on social grooming to spread the toxin within colonies, have been implemented since the 1970s but can lead to non-target effects and population instability in affected areas. A 2023 Science Advances analysis underscores the widespread use of such vampiricides, noting their role in ongoing efforts to control bat numbers despite limited long-term efficacy. Other factors include increased competition from co-occurring bat species in altered landscapes, where habitat fragmentation intensifies resource overlap for roosting and foraging sites. Novel ecological interactions, such as a documented 2025 record of predation or attempted feeding on the greater naked-tailed armadillo (Cabassous tatouay) in Brazil, illustrate emerging pressures from changing predator-prey dynamics in disturbed environments. This interaction, captured via camera traps and reported on ResearchGate, highlights how landscape modifications may expose vampire bats to unusual risks from ground-dwelling mammals.

Conservation efforts

Research programs focused on the common vampire bat (Desmodus rotundus) emphasize safe handling and genetic monitoring to support ecological studies without compromising bat welfare or human safety. In 2025, protocols for land transport of wild-caught vampire bats were developed, utilizing custom containers that allow for extended travel exceeding 40 hours, including provisions for feeding during transit to minimize stress and mortality. Additionally, genetic databases compiling occurrence reports and molecular data enable population monitoring and assessment of gene flow across regions, aiding in the identification of diversity hotspots and potential hybridization events. Management strategies prioritize non-lethal interventions in agricultural settings to control vampire bat populations while mitigating rabies risks. Trap-based methods, such as mist netting at roosts, are recommended over anticoagulant poisons to reduce bat numbers selectively and avoid secondary poisoning of non-target wildlife, promoting sustainable coexistence with livestock. Educational campaigns emphasize rabies prevention through livestock vaccination and human post-exposure prophylaxis, discouraging widespread extermination efforts that disrupt ecosystems and fail to curb disease transmission effectively. The common vampire bat benefits indirectly from protected areas across the Neotropics, where roosts in caves, hollow trees, and foliage are safeguarded within biodiversity hotspots. In Amazonian national parks, such as those in Peru and Brazil, conservation of intact forests preserves essential roosting sites and foraging grounds, supporting bat populations amid habitat pressures. Future conservation directions incorporate modeling to predict vampire bat responses to climate change, focusing on behavioral adaptations to shifting habitats. Recent studies using state-space models on GPS-tracked bats reveal varied reactions to human disturbance, informing adaptive management strategies for range expansions under warming scenarios. Social-ecological network analyses further highlight how bat social structures can be leveraged for resilience planning in the face of environmental shifts.

Human interactions

Disease transmission

The common vampire bat (Desmodus rotundus) serves as the primary reservoir host for the rabies virus in Latin America, where it maintains and transmits rabies virus (RABV), specifically the vampire bat variant. Recent 2025 studies highlight its role in causing significant livestock losses, with thousands of cattle deaths reported annually due to bat-borne rabies outbreaks across the region. For instance, an average of 450 outbreaks occur each year in Central and South America, contributing to economic impacts estimated in the tens of millions of U.S. dollars. Transmission of rabies occurs primarily through the bat's saliva during feeding bites on mammals, including livestock and occasionally humans, as the virus is shed in oral secretions. The RABV strain circulates endemically in vampire bat populations, with active infection prevalence typically ranging from 0.8% to 1.5% in sampled colonies, though seroprevalence can be higher due to non-lethal exposures that confer immunity. This low but persistent prevalence enables sustained viral maintenance without causing high mortality in the reservoir host. Beyond rabies, vampire bats harbor other pathogens with zoonotic potential, including trypanosomes such as Trypanosoma evansi and Trypanosoma cruzi, which can be transmitted mechanically via contaminated mouthparts during feeding. Recent research indicates high infection rates of these parasites in bat populations (up to 70% in some studies), alongside bacteria like Bartonella spp., raising concerns about increased spillover risks through diverse host-pathogen interactions exacerbated by habitat changes and livestock density. While henipaviruses are primarily associated with fruit bats, emerging virome surveys suggest potential exposure in hematophagous bats like D. rotundus, warranting further investigation into cross-species transmission dynamics. Epidemiologically, vampire bat feeding behavior—characterized by repeated bites on multiple individuals within a herd (affecting 6–52% of animals per night)—facilitates rapid rabies spread, often leading to clustered infections and outbreaks in livestock populations. In bats, the incubation period can extend from weeks to several months (typically 2–3 months), allowing asymptomatic carriers to disperse the virus across roosts and foraging areas before clinical signs appear. This prolonged latency, combined with social grooming and roost sharing, sustains enzootic cycles and amplifies spillover events to naive hosts.

Agricultural and economic impacts

The common vampire bat (Desmodus rotundus) inflicts substantial agricultural damage by feeding on the blood of livestock, particularly cattle, leading to anemia from repeated blood loss, secondary bacterial infections at bite sites, and decreased milk yields in affected animals. Severely bitten cows experience marked reductions in milk production, while sows with teat bites may be unable to nurse their young, compounding productivity losses in dairy and beef operations. These direct effects weaken livestock health and vitality, with annual weight loss in beef cattle estimated at around 39.7 kg per head due to persistent feeding. Across Latin America, these predation impacts result in annual economic losses of approximately US$97 million for livestock producers, stemming from reduced animal productivity, veterinary treatments, and mortality from complications like infections. Vampire bats show a strong preference for large domestic mammals over wildlife in farm settings, drawn by the abundance and accessibility of cattle in pastures and enclosures. Indirect agricultural harm arises from bats roosting in farm infrastructure, such as barns and abandoned buildings, which brings colonies into close proximity to livestock and heightens feeding frequency without directly damaging crops. Control efforts focus on targeted anticoagulant treatments to reduce bat populations and attacks. Systemic administration of anticoagulants like diphenadione to livestock via intraruminal injection has demonstrated a 93% reduction in bat bites, as bats ingest the poison during feeding. Topical applications of anticoagulants, such as warfarin or chlorophacinone pastes to captured bats or livestock wounds, achieve 70-100% efficacy in inducing bat mortality and curbing attacks, depending on the method and dosage. Recent 2025 research highlights how anthropogenic landscape modifications, including deforestation and pasture expansion, have boosted D. rotundus abundance, intensifying these agricultural conflicts and necessitating adaptive management strategies.

Cultural and scientific significance

The common vampire bat (Desmodus rotundus) has profoundly influenced cultural narratives, particularly in folklore linking it to vampirism. Bram Stoker's 1897 novel Dracula popularized the association between bats and blood-sucking vampires in Western literature, drawing on the bat's hematophagous feeding habits to symbolize nocturnal terror and immortality, though the transformation motif was Stoker's invention rather than rooted in pre-existing bat lore. In Latin American indigenous traditions, the bat appears in diverse myths: among the Classic Veracruz culture of Mexico, bat gods featured in human sacrifice rituals where participants donned vampire bat suits; in Mayan highland lore from the Popol Vuh, the death bat Camazotz decapitated a hero twin in an underworld ball game, embodying death and the afterlife; and in Costa Rican creation stories, a vampire bat drinking jaguar blood animates the earth and fosters plant growth, symbolizing fertility and rebirth. Known locally as murciélago vampiro, the bat evokes fear in rural Latin American communities due to its blood-feeding on livestock and perceived threat of rabies transmission, fostering a maligned image that perpetuates folklore of predatory night creatures. Scientifically, the common vampire bat serves as a key model organism for studying social behavior, anticoagulation mechanisms, and disease ecology. Its complex social structure, including food sharing via regurgitation among roostmates and kin, highlights reciprocal altruism and cooperation, providing insights into mammalian social evolution uncommon in solitary species. The bat's saliva contains draculin, a glycoprotein anticoagulant that acts as a tight-binding, noncompetitive inhibitor of activated factor X (FXa), preventing blood clotting during feeding; this 88.5 kDa protein, with a dissociation constant (Kd) of 14.8 nM, has inspired medical research into novel blood thinners for stroke treatment and thrombosis prevention, as it selectively targets coagulation factors IXa and Xa without broad hemorrhagic risks. In disease ecology, the bat's role as the primary reservoir for rabies virus in Latin America informs transmission dynamics and control strategies, emphasizing its impact on wildlife-livestock-human interfaces. Recent research underscores the bat's contributions to behavioral and evolutionary biology. A 2025 study using state-space modeling of GPS data revealed diverse responses to human disturbance, including roost abandonment, extended flight distances, and heightened vigilance, varying by individual and context, which advances understanding of anthropogenic effects on chiropteran ecology. In evolutionary biology, genomic analyses have identified 13 bat-specific gene losses, such as FFAR1 and SLC30A8 (reducing insulin secretion for a blood-only diet), REP15 (enhancing iron excretion to manage heme overload), and PDE6H/PDE6C (eliminating cone-based vision suited to nocturnality), illuminating molecular adaptations to sanguivory and offering a comparative framework for dietary specialization in mammals. Conservation education efforts aim to reframe the vampire bat's image from a pest to an integral ecosystem component, countering its fearsome folklore to support biodiversity protection. Initiatives, including films and public outreach, highlight its non-pest roles—such as nutrient cycling through blood consumption and indirect regulation of disease vectors via population dynamics—while addressing misconceptions that hinder habitat preservation in expanding agricultural landscapes.

References

  1. [1]
    A database of common vampire bat reports - PMC - PubMed Central
    Feb 16, 2022 · Desmodus rotundus is a strictly sanguivorous species that feeds mainly on the blood of medium to large-bodied terrestrial mammals and some birds ...
  2. [2]
    Ricardo Nieves
    The common vampire bat (Desmodus rotundus) is a small, New World bat, 70-90mm long, with 20 teeth, that feeds on mammal blood.Missing: ecology | Show results with:ecology
  3. [3]
    Vampire Bats – Look Beyond the Fangs and Blood To See Animal ...
    Nov 1, 2024 · Vampire bats have unique adaptations like heat-sensing noses and anticoagulant saliva. They share blood, form complex social relationships, and ...
  4. [4]
    A review of the diet of the common vampire bat (Desmodus rotundus ...
    Jun 12, 2023 · The common vampire bat (Desmodus rotundus) maintains a diverse, sanguivorous diet, utilizing a broad range of prey taxa.Missing: facts | Show results with:facts
  5. [5]
    Creepin' it Real: Why Bats Don't Suck | U.S. Fish & Wildlife Service
    Although the common vampire bat feeds on mammals (yes, sometimes humans), the hairy-legged and white-winged vampire bats prefer bird blood. Scientists have ...
  6. [6]
    Desmodus rotundus - NCBI
    Desmodus rotundus, basionym: Phyllostoma rotundum Geoffroy, 1810, Genbank common name: common vampire bat, NCBI BLAST name: bats, Rank: species.
  7. [7]
    Desmodus rotundus (vampire bat) - Animal Diversity Web
    Scientific Classification ; Order, Chiroptera bats ; Family, Phyllostomidae New World leaf-nosed bats ; Genus, Desmodus vampire bat ; Species, Desmodus rotundus ...
  8. [8]
    Vampire Bats - Explore the Taxonomic Tree | FWS.gov
    Tribe, Desmodontini. Genus, Desmodus. Scientific NameDesmodus rotundus rotundus. Common Name. Taxonomic Rank. Subspecies. FWS Focus. Explore BranchExplore ...
  9. [9]
    Common Vampire Bat - an overview | ScienceDirect Topics
    Three genera and species of vampire bats, belonging to the family Phyllostomidae, subfamily Desmodontinae, include the following species: the common vampire bat ...
  10. [10]
    Desmodus rotundus • Common Vampire Bat
    Taxonomy ; Suborder, : Yangochiroptera ; Superfamily, : Noctilionoidea ; Family, : Phyllostomidae ; Subfamily, : Desmodontinae ; Tribe, : Desmodontini.
  11. [11]
    Evolutionary patterns and processes in the radiation of phyllostomid ...
    The early period of phyllostomid diversification is marked by a burst of shape, size, and diet disparity (before 20 Mya), larger than expected by neutral ...
  12. [12]
    Comprehensive phylogenetic trait estimations support ancestral ...
    The New World leaf-nosed bats (family Phyllostomidae) represent an adaptive radiation with highly diverse diets, including arthropods, nectar, and fruits.
  13. [13]
    A giant vampire bat (Phyllostomidae, Desmodontinae) from the ...
    Aug 18, 2020 · Numerous molecular phylogenetic analyses support the Desmodontinae (vampire bats) as one of the earliest-diverging lineages of Phyllostomidae ( ...
  14. [14]
    A giant vampire bat (Phyllostomidae, Desmodontinae) from the ...
    Aug 18, 2020 · As such, the Venezuelan fossil represents the oldest or at least one of the oldest vampire bats yet known, similar in body size to the late ...
  15. [15]
    100,000-Year-Old Fossil of Giant Vampire Bat Found in Argentina
    Jul 26, 2021 · Paleontologists in Argentina have found a fossilized jaw of the extinct bat species Desmodus draculae inside an ancient burrow of a giant sloth.
  16. [16]
    Mitochondrial DNA phylogeography reveals marked population ...
    Jul 23, 2007 · Mitochondrial DNA phylogeography reveals marked population structure in the common vampire bat, Desmodus rotundus (Phyllostomidae).
  17. [17]
    Phylogeography of the common vampire bat (Desmodus rotundus)
    Dec 20, 2009 · The common vampire bat, Desmodus rotundus Geoffroy, 1810, is a species with a wide geographical distribution: it ranges from southern Mexico to ...Missing: type | Show results with:type<|control11|><|separator|>
  18. [18]
    Dracula's children: molecular evolution of vampire bat venom
    Aug 26, 2013 · This study found a novel DSPA isoform, a large draculin sequence, and other proteins in vampire bat venom, showing a complex secretion profile.
  19. [19]
    Dracula's children: Molecular evolution of vampire bat venom
    Aug 26, 2013 · A venom component that has been researched considerably is draculin, an anticoagulant factor. It is an 88.5 kDa glycoprotein that inhibits ...
  20. [20]
    Desmodus rotundus (E. Geoffroy Saint-Hilaire, 1810)
    Jan 6, 2025 · Head-body 68-93 mm (tailless), ear 16-21 mm, hindfoot 13-22 mm, forearm 52-64 mm; weight 25-40 g. Females are larger than males in most ...Missing: grams length
  21. [21]
    [PDF] MAMMALIAN SPECIES No. 202, pp. 1-6, 3 figs. - Desmodus rotundus.
    Apr 8, 1983 · Vampire bats commonly forage in an area of 5 to 8 km around the diurnal roost (Crespo et al., 1961); in certain regions this dis- tance may ...Missing: facts | Show results with:facts
  22. [22]
    Locomotor morphology of the vampire bat, Desmodus rotundus
    Dec 7, 2009 · By. Altenbach, J. Scott · American Society of Mammalogists. Type ... 1979. Subjects. Desmodus rotundus , Locomotion , Vampire bats , Wings ...
  23. [23]
    Echolocation Performance of the Vampire Bat (Desmodus rotundus)
    The neotropical vampire bats (Desmodus rotundus) echolocate using ultrasonic pulses like those of the Latin American phyllostomatid bats.
  24. [24]
    Use of Olfaction during Prey Location by the Common Vampire Bat ...
    The common vampire bat, Desmodus rotundus, feeds on mammalian blood and is a major agricultural pest in Latin America. One way to prevent bats f.
  25. [25]
    Biological infrared imaging and sensing - PubMed
    IR pit organs of common vampire bats (Desmodus rotundus) enable them to detect IR radiation emitted by blood-rich locations on homeothermic prey. The beetle ...
  26. [26]
    Expression of biological activity of draculin, the anticoagulant factor ...
    Draculin, a glycoprotein isolated from vampire bat (Desmodus rotundus) saliva, is a natural anticoagulant which inhibits activated coagulation factors IX (IXa) ...
  27. [27]
    Vampire Venom: Vasodilatory Mechanisms of Vampire Bat ...
    Jan 8, 2019 · Previous studies have demonstrated that D. rotundus venom contains two important anticoagulant toxins: Draculin [6,7,13]; and DSPA (Desmodus ...
  28. [28]
    Gene losses in the common vampire bat illuminate molecular ...
    Mar 25, 2022 · Breidenstein, Digestion and assimilation of bovine blood by a vampire bat (Desmodus rotundus). J. Mammal. 63, 482–484 (1982). Crossref · Web ...<|control11|><|separator|>
  29. [29]
    Metabolic responses induced by fasting in the common vampire bat ...
    Aug 5, 2025 · However, the hematophagous bat Desmodus rotundus exhibits high susceptibility when subjected to food deprivation, though its diet is rich in ...
  30. [30]
    Present and Potential Future Distribution of Common Vampire Bats ...
    Aug 10, 2012 · There are no known occurrences of D. rotundus on Baja peninsula (Mexico) or in the Caribbean islands, except Trinidad, Tobago, and Margarita ...
  31. [31]
    A review of the diet of the common vampire bat (Desmodus rotundus ...
    Jun 12, 2023 · The common vampire bat (Desmodus rotundus) maintains a diverse, sanguivorous diet, utilizing a broad range of prey taxa.
  32. [32]
    A database of common vampire bat reports | Scientific Data - Nature
    Feb 16, 2022 · The common vampire bat, Desmodus rotundus (É. Geoffroy, 1810) is a member of the family Phyllostomidae, subfamily Desmodontinae. Desmodus ...<|separator|>
  33. [33]
    Vampire Bat Rabies: Ecology, Epidemiology and Control - PMC
    Apr 29, 2014 · Humans have also provided vampire bats with roosting sites in the form of buildings, bridges and wells. This in turn has contributed to an ...
  34. [34]
    [PDF] The social organization of the common vampire bat
    In this paper I attempt to identify the factors responsible for the dispersion pattern of the com- mon vampire bat, Desmodus rotundus. After docu- menting long- ...
  35. [35]
    Future climate change and the distributional shift of the common ...
    Feb 18, 2025 · This study used current and future climate data and historic occurrence locations of the vampire bat species Desmodus rotundus, a reservoir of the rabies virus.<|separator|>
  36. [36]
    The common vampire bat Desmodus rotundus (Chiroptera ...
    The common vampire bat Desmodus rotundus (E. Geoffroy, 1810) is the main responsible for the maintenance and transmission of the rabies virus (RABV) to ...Missing: Phyllostoma rotundum locality
  37. [37]
    Beyond climate: Anthropogenic pressures reshape vampire bat ...
    The subfamily Desmodontinae (Chiroptera, Phyllostomidae), commonly known as vampire bats, is native to America, with a range extending from Mexico to northern ...
  38. [38]
    The biting and feeding habits of the Vampire bat, Desmodus rotundus
    Observations of how the common vampire bat, Desmodus rotundus, prepares wound sites with the teeth and tongue are described, as well as how the wounds are ...
  39. [39]
    Vampire bats go with the flow - PMC - NIH
    These permissions are granted for the duration of the World Health ... Desmodus rotundus is one of only three species of bats that feed exclusively ...
  40. [40]
    Desmodus rotundus - an overview | ScienceDirect Topics
    2.22.2.5.2 Cuneate–Gracile Complex. The skeletal arrangement of bat wings follows the typical mammalian forelimb plan, but with digits 2–5 elongated. The wing ...
  41. [41]
    The social organization of the common vampire bat I. Pattern and ...
    Aug 7, 2025 · At a site in Costa Rica, three groups of 8-12 adult female vampire bats, Desmodus ro-tundus, utilize group-specific sets of hollow trees as ...
  42. [42]
    Reciprocal food sharing in the vampire bat - Nature
    Mar 8, 1984 · Here, I show that food sharing by regurgitation of blood among wild vampire bats (Desmodus rotundus) depends equally and independently on degree ...
  43. [43]
    Food sharing in vampire bats: reciprocal help predicts donations ...
    Food sharing in vampire bats provides mutual direct fitness benefits, and is not explained solely by kin selection or harassment.
  44. [44]
    Adult Vampire Bats Produce Contact Calls When Isolated
    We found that isolated adult vampire bats produce contact calls that vary by species, population, colony, and individual. However, much variation occurred ...
  45. [45]
    Social Grooming in Bats: Are Vampire Bats Exceptional? - PMC - NIH
    Oct 7, 2015 · Vampire bats have 14 times higher social grooming rates than other bats, spending 1.5-6.3% of their awake time on it, compared to 0.1-0.5% in ...Missing: vocalizations | Show results with:vocalizations
  46. [46]
    [PDF] Social network characteristics and predicted pathogen transmission ...
    Feb 21, 2016 · Females change roosts every few days, but not all members of each subgroup move together, resulting in variable group size and composition (e.g. ...<|control11|><|separator|>
  47. [47]
    (PDF) The social organization of the common vampire bat - II. Mating ...
    Aug 7, 2025 · Occasional movements of unrelated females between groups lead to the formation of multiple matrilines within groups. Although males fight ...Missing: reproduction gestation litter
  48. [48]
    [PDF] Bat Mating Systems - Gary F. McCracken and Gerald S. Wilkinson
    Although it has been suggested that these species may mate in harems or perhaps leks, we categorize these bats as mating in 'multi-male/multi-female polygynous ...<|control11|><|separator|>
  49. [49]
    Common Vampire Bat - Facts, Diet, Habitat & Pictures on Animalia.bio
    Females give birth to one offspring per pregnancy, following a gestation period of about 7 months. The young are raised primarily by females. Mothers leave ...Distribution · Mating Habits · Related AnimalsMissing: system parental care
  50. [50]
    Vampire Bat - Center for Perinatal Discovery
    The Latin name comes from desmos (Gr. bundle) and odous (Gr. from ondontous) because of their 'bundled' cone-shaped upper central incisors (Gotch ...
  51. [51]
    Vampire Bat - Denver Zoo Conservation Alliance
    Classification ; CLASS: Mammalia ; ORDER: Chiroptera ; FAMILY: Phyllostomidae ; GENUS: Desmodus ; SPECIES: rotundus ...Missing: taxonomy | Show results with:taxonomy
  52. [52]
    [PDF] NATURAL HISTORY - AZA Bat Taxon Advisory Group
    There are 3 species of vampire bats: Common Vampire Bats (Desmodus rotundus), White- winged Vampire Bats (Diamus youngii) and Hairy-legged Vampire Bats ( ...<|control11|><|separator|>
  53. [53]
    Non-kin adoption in the common vampire bat - Journals
    Feb 10, 2021 · After four to five months, pups will have grown fourfold in mass and will begin to fly and feed on blood [26]. Weaning does not occur until ...
  54. [54]
    Non-kin adoption in the common vampire bat - PMC - NIH
    Feb 10, 2021 · We describe patterns of allogrooming and food sharing before and after an instance of non-kin adoption between two adult female common vampire bats.
  55. [55]
    Movements of Cave Bats in Southeastern Brazil, with Emphasis on ...
    Aug 5, 2025 · ... Desmodus rotundus, Carollia perspicillata. Anoura caudifer, Artibeus ... rotundus varied monthly from one to 3.5 individuals per km2 ...
  56. [56]
    Host Preference of the Common Vampire Bat (Desmodus rotundus
    Feb 20, 2006 · Thus, vampire bats could easily access the habitat dominated by C3 plants (rainforest) as well as that dominated by C4 plants (pasture). We ...
  57. [57]
    Climate change linked to vampire bat expansion and rabies virus ...
    Oct 26, 2023 · Here, we report the impacts of climate change on the distributional ecology of the common vampire bat Desmodus rotundus across the last century.
  58. [58]
    Common vampire bat (Desmodus rotundus) abundance ... - PubMed
    Mar 8, 2022 · This study's objective was to analyze the relationship between D. rotundus abundance and number of bovines attacked in livestock landscapes in Yucatan.
  59. [59]
    [PDF] Monitoring Trends in Bat Populations - USGS Publications Warehouse
    O'Shea, T.J. and Bogan, M.A., eds., 2003, Monitoring trends in bat populations of the United States and territories: problems and prospects: U.S. Geological ...
  60. [60]
    Effects of culling vampire bats on the spatial spread and spillover of ...
    Mar 10, 2023 · In Latin America, vampire bats have been culled for decades in hopes of mitigating lethal rabies infections in humans and livestock. Whether ...
  61. [61]
    (PDF) First documented record of interaction between vampire bat ...
    Sep 3, 2025 · We reported the interaction between a common vampire bat (Desmodus rotundus) and a greater naked-tailed armadillo (Cabassous tatouay) ...
  62. [62]
    Transporting Common Vampire Bats (Desmodus rotundus) by Land
    May 30, 2025 · This article describes the design of a container to safely transport wild-caught vampire bats in a trip requiring >40 h of driving and one feeding session.
  63. [63]
    How To Stop Vampire Bats From Spreading Rabies - NPR
    Sep 13, 2016 · Right now, farmers try to stop outbreaks by killing vampire bats. They trap the bats and rub a pasty poison on their bodies. The animals ...Missing: agriculture | Show results with:agriculture
  64. [64]
    Management of vampire bats and rabies: Past, present, and future
    Apr 25, 2023 · Vaccination of vampire bats against rabies could lower the incidence of VBR and prevent viral transmission to cattle and humans without the ...
  65. [65]
    Vampire bats' maligned reputation hinders efforts at conservation
    Aug 19, 2021 · For most wildlife, biodiversity loss and habitat degradation has a detrimental effect, but bats are a generalist species, with high ecological ...
  66. [66]
    Lush Life: Neotropical Rainforest Bats - Bat Conservation International
    Mar 19, 2025 · The rainforests of South America contain the widest diversity of bats in the world, home to insectivorous, frugivorous, carnivorous, and nectarivorous species.
  67. [67]
    Roosting Ecology of Amazonian Bats: Evidence for Guild Structure ...
    Dec 14, 2016 · Bats that often roost in caves in Central America (e.g., Desmodus rotundus) cannot be widely distributed in Amazonian habitats (as they ...
  68. [68]
    Diverse behavioural responses of vampire bats to human ... - bioRxiv
    Diverse behavioural responses of vampire bats to human disturbance revealed by state-space modelling of sparse GPS dataMissing: climate adaptation
  69. [69]
    Drivers of rabies virus spillover risk from vampire bats to livestock in ...
    Sep 26, 2025 · The common vampire bat (Desmodus rotundus) regularly transmits rabies virus (RABV) to livestock in Latin America. Vampire-bat borne RABV causes ...
  70. [70]
    Dynamics of Rabies Transmission in Vampire Bats (Desmodus ...
    Sep 11, 2025 · Vampire bats (Desmodus rotundus) are the primary spreader of rabies, a lethal disease that harms livestock and people across Latin America.Missing: facts | Show results with:facts<|control11|><|separator|>
  71. [71]
    Rabies transmitted from vampires to cattle: An overview | PLOS One
    The common vampire bat, Desmodus rotundus, is the main reservoir and transmitter of rabies virus (RABV) to domestic animals in Latin America.
  72. [72]
    Epidemiology and biology of a herpesvirus in rabies endemic ...
    Nov 23, 2020 · In total, 96.9% (124/128) of the vampire bat saliva samples were BHV-positive by semi-nested PCR, with 46.9% (60/128) positive after a single ...
  73. [73]
    Detection and Prevalence of Rabies in Bats from Oaxaca - MDPI
    This study aimed to determine the prevalence of the virus in Desmodus rotundus and other non-hematophagous bat species in Oaxaca.
  74. [74]
    Genetic diversity, infection prevalence, and possible transmission ...
    Sep 27, 2018 · We present results from a two-year, spatially replicated study of common vampire bats, which have previously shown high infection prevalence of ...
  75. [75]
    Diversity and Epidemiology of Bat Trypanosomes: A One Health ...
    Transmission of this type typically occurs when the metacyclic trypanosomes within the faeces penetrate the mucosal membranes around the eye or mouth or via ...
  76. [76]
    Livestock abundance predicts vampire bat demography, immune ...
    Mar 12, 2018 · Prevalence of Bartonella and haemoplasmas in 173 bats as assessed by PCR was 70% and 68%, ranging from 40 to 100% for Bartonella and 45–86% for ...<|control11|><|separator|>
  77. [77]
    Vampire bat rabies: is it actually 100% fatal? - BMC blog network
    Jul 10, 2020 · The incubation period is typically 2–3 months, but may vary from 1 week to 1 year, dependent upon factors such as location of virus entry and ...Missing: patterns | Show results with:patterns
  78. [78]
    [PDF] Vampire bats, which transmit paralytic rabies, pose a major - Iris Paho
    The milk yield of severely bitten cows drops markedly, and sows bitten on their teats are often unable to nurse their young.
  79. [79]
    [PDF] Some Social and Economic Aspects in Controlling Vampire Bats
    Vampire bats (Desmodus rotundus) cause social and economic hardship because they feed on humans and livestock and often transmit paralytic rabies.<|control11|><|separator|>
  80. [80]
    Vampire Bats and Rabies: Toward an Ecological Solution to a Public ...
    Jun 19, 2014 · Campaigns in which bats are culled using a topical anticoagulant poison remain common in Latin America; however, empirical and theoretical ...
  81. [81]
    Distribution of Desmodus rotundus and Its Implications for Rabies in ...
    Jun 17, 2025 · ... economic loss of US$97 million per year in Latin America. The common vampire bat (Desmodus rotundus) is the primary reservoir for livestock ...
  82. [82]
    Vampire Bat Control by Systemic Treatment of Livestock with an ...
    Cattle at three ranches in Mexico treated with single intraruminal injections of diphenadione experienced a reduction in vampire bat bites of 93 percent.
  83. [83]
    Anticoagulants for the Control of the Common Vampire Bat ...
    Dec 22, 2024 · The body of literature indicates effectiveness of up to 100% in the use of anticoagulants to induce bat mortality.
  84. [84]
    Five Things Everyone Should Know about … Vampire Bats
    Oct 17, 2018 · Bram Stoker's 1897 novel Dracula popularized the connection between Eastern European vampires and bats. But Old World vampire folklore was well ...
  85. [85]
    Living Vampires | Royal Ontario Museum
    Nov 29, 2019 · Vampire bats are also a symbol of fertility and rebirth. In a creation myth from Costa Rica, the earth came to life after a vampire bat drank ...<|separator|>
  86. [86]
    Draculin, the anticoagulant factor in vampire bat saliva, is a tight ...
    Draculin is a noncompetitive, tight-binding inhibitor of FXa, a characteristic so far unique amongst natural FXa inhibitors.
  87. [87]
    A database of common vampire bat reports
    Dec 1, 2022 · The common vampire bat,Desmodus rotundus, is the main reservoir and transmitter of rabies virus (RABV) to domestic animals in Latin America.
  88. [88]
    How two Bruins used film and science to reframe a 'spooky' species
    Oct 16, 2025 · There are only three species of vampire bats, and only one drinks mammal blood. ... Conservation Science, discusses the diversity of bat species ...