Eukaryote

Acanthamoeba, a free-living protist, has emerged as a crucial organism in various scientific research domains.
As a model organism, Acanthamoeba provides valuable insights into cell biology, host-pathogen interactions, and environmental microbiology, making it a popular choice for researchers conducting studies related to phagocytosis, cell signaling, and the pathogenesis of amoebic infections.
Its versatility and ease of cultivation have positioned Acanthamoeba as a preferred experimental subject in protocols exploring topics such as cellular dynamics, immune responses, and environmental remediation strategies.

Aedes, a genus of mosquitoes, has become a crucial subject of scientific research due to its role as a vector for various infectious diseases.
As a common model organism, Aedes mosquitoes are frequently utilized in experiments studying vector-borne illnesses, such as dengue, Zika, and chikungunya, allowing researchers to gain valuable insights into disease transmission dynamics and the development of effective prevention and control strategies.
Protocols involving Aedes mosquitoes are of great interest to the scientific community, as they provide a reliable platform for investigating the complex interplay between mosquito biology, pathogen interactions, and the impact on human health.

Agelas, a genus of marine sponges, has become a valuable research subject in the scientific community.
Known for its unique chemical composition and bioactive compounds, Agelas sponges have garnered attention for their potential applications in various fields, including pharmacology, marine biology, and biotechnology.
Researchers often utilize Agelas in experimental protocols to investigate antimicrobial properties, secondary metabolite production, and the sponge's role in marine ecosystems, making it a versatile and important model organism for a wide range of scientific investigations.

Amoeba, a single-celled eukaryotic organism, has long been a subject of scientific interest due to its unique cellular structure and behavior.
As a versatile model organism, amoebas are commonly used in a wide range of biological research, from cell biology and genetics to environmental studies and biotechnology applications.
Researchers frequently employ amoeba-based protocols to investigate topics such as cell motility, phagocytosis, signal transduction, and the effects of various environmental stressors on eukaryotic cells, making the humble amoeba an invaluable tool in the scientific toolkit.

Amoebida, a group of free-living, single-celled eukaryotic organisms, have gained significant attention in the scientific research community due to their diverse applications.
As professional-grade amoebae, Amoebida species are widely utilized in a range of experimental protocols, from studying fundamental cellular processes to evaluating the efficacy of novel therapeutic compounds.
Researchers across fields, including cell biology, microbiology, and drug discovery, often incorporate Amoebida into their experimental designs, leveraging their unique characteristics and versatility to yield valuable insights.

Amphipoda, a diverse order of small crustaceans, have gained significant attention in the scientific community due to their wide range of applications in research protocols.
These versatile organisms, often referred to as "scuds" or "sideswimmers," have become essential models for studying various ecological, toxicological, and behavioral phenomena, making them highly relevant for researchers across multiple disciplines.
From aquatic ecosystem assessments to the development of novel biomonitoring techniques, Amphipoda's unique characteristics and adaptability have solidified their position as a valuable tool in the arsenal of the modern scientific investigator.

Ancylostomatoidea, a superfamily of parasitic nematodes, plays a significant role in various scientific experiments and research protocols.
These hookworms are commonly used as model organisms in the study of host-parasite interactions, the development of anthelmintic drugs, and the investigation of the human immune response to parasitic infections.
Researchers often utilize Ancylostomatoidea in experimental settings to gain insights into the mechanisms of disease transmission, the efficacy of therapeutic interventions, and the potential for vaccine development, making it a valuable subject in the fields of parasitology, immunology, and pharmacology.

Anisoptera, commonly known as dragonflies, are a diverse group of insects that have gained significant attention in the scientific community.
These powerful flyers possess unique physiological and behavioral traits that make them valuable subjects for a wide range of research protocols, from biomechanics and neuroscience to ecology and evolutionary biology.
Anisoptera's versatility as a model organism, coupled with their accessibility and ease of study, has led to their widespread use in various experimental settings, contributing to our understanding of animal form, function, and the fundamental principles of life.

Anopheles mosquitoes are a genus of mosquitoes that are of great importance in scientific research, particularly in the fields of vector-borne disease studies and malaria research.
As the primary vector for the Plasmodium parasite, which causes malaria, Anopheles plays a crucial role in understanding the epidemiology, transmission dynamics, and control strategies of this devastating disease.
Researchers frequently utilize Anopheles mosquitoes in various experimental protocols, such as vector competence studies, insecticide resistance assessments, and the development of novel interventions aimed at reducing malaria burden.

Anopheles gambiae, a notorious mosquito species, is a central focus in numerous scientific experiments and research protocols.
As a primary vector for the transmission of malaria, this insect plays a crucial role in studying disease epidemiology, novel intervention strategies, and vector biology.
Researchers commonly utilize Anopheles gambiae in protocols related to insecticide testing, transgenic modification, and behavioral analysis, contributing to a deeper understanding of this important public health challenge.

Anoplura, more commonly known as sucking lice, are a group of ectoparasitic insects that have long been of interest to researchers in various scientific fields.
As obligate parasites of mammals, Anoplura species play a crucial role in understanding host-parasite interactions, disease transmission, and evolutionary biology.
Researchers frequently utilize Anoplura in experimental protocols, such as exploring insecticide efficacy, evaluating host immune responses, and investigating the dynamics of louse-borne pathogen spread, making them an invaluable model organism for a wide range of scientific investigations.

Ants, the fascinating eusocial insects, have long been a subject of interest in the scientific community.
These tiny creatures, with their complex social structures and intricate behaviors, offer a wealth of research opportunities across various fields, from animal behavior and ecology to neuroscience and genetics.
As model organisms, ants are widely used in experimental protocols, providing insights into topics such as collective decision-making, navigation, chemical communication, and colony organization, making them invaluable tools for researchers studying the intricacies of social insect biology.

Aphids, small sap-sucking insects, are a widely used model organism in various scientific experiments, particularly in the fields of plant-insect interactions, host-pathogen relationships, and evolutionary biology.
These tiny pests offer valuable insights into topics such as plant defense mechanisms, virus transmission, and the adaptation of insects to changing environmental conditions.
Researchers frequently incorporate Aphids into their experimental protocols to investigate a range of biological phenomena, making them a crucial component of many research studies across diverse scientific disciplines.

Apis, the genus of honey bees, plays a crucial role in scientific research and experimentation.
As important pollinators, Apis species are widely utilized in various fields, including agricultural research, ecotoxicology, and behavioral studies.
Researchers often rely on Apis as model organisms to investigate topics ranging from colony dynamics and foraging behavior to the impact of environmental stressors on pollinator populations, making them a valuable asset in developing robust scientific protocols.

Aplysia, commonly known as the sea hare, is a genus of large marine gastropod mollusks that have become a valuable model organism in scientific research.
Due to its relatively simple nervous system and well-characterized neural pathways, Aplysia has been widely utilized in a variety of neuroscience experiments, including studies on learning, memory formation, and neural plasticity.
Researchers in fields such as neurophysiology, behavioral biology, and cellular and molecular biology frequently employ Aplysia as a model system to gain insights into fundamental biological processes, making it a crucial subject in many experimental protocols.

Arachnida, the class of arthropods that includes spiders, scorpions, and mites, holds immense significance in scientific research.
As a diverse group with unique physiological and behavioral characteristics, Arachnids are widely employed in a variety of experimental protocols, offering valuable insights into topics such as venom research, toxicology, ecology, and even biomimetic engineering.
From studying the complex web-spinning abilities of spiders to investigating the regenerative potential of scorpion limbs, Arachnids have become indispensable models for researchers across multiple scientific disciplines.

Artemia, commonly known as brine shrimp, is a widely-used organism in scientific research across various fields, including ecology, toxicology, and aquaculture.
As a small crustacean with a simple life cycle, Artemia is an invaluable model organism for studying topics such as environmental stress responses, developmental biology, and nutrient dynamics.
Researchers often utilize Artemia in experimental protocols due to its ease of cultivation, short generation time, and sensitivity to environmental changes, making it a versatile and reliable tool for scientific investigations.

Arthropods, a diverse group of invertebrates that includes insects, arachnids, and crustaceans, have become increasingly relevant in scientific research protocols across various fields.
As model organisms, arthropods offer numerous advantages, such as rapid life cycles, ease of manipulation, and well-characterized genomes, making them invaluable tools for studying topics ranging from developmental biology and neuroscience to ecology and evolution.
From Drosophila (fruit flies) in genetics research to Caenorhabditis elegans (nematodes) in biomedical investigations, arthropods have proven to be indispensable in advancing our scientific understanding and driving impactful discoveries.

Ascaris, a genus of parasitic roundworms, is a common subject of interest in scientific research and experimentation.
As a model organism, Ascaris offers valuable insights into various biological processes, including host-parasite interactions, developmental biology, and molecular genetics.
Researchers across diverse fields, from parasitology to pharmacology, frequently utilize Ascaris in their studies, leveraging its well-understood life cycle and ease of laboratory cultivation to investigate a wide range of research questions.

Ascaris lumbricoides, a common intestinal nematode, is a widely utilized model organism in scientific research.
This parasitic roundworm is particularly relevant for studies investigating host-parasite interactions, immune responses, and the efficacy of anthelmintic drugs.
Researchers often employ Ascaris lumbricoides in experimental protocols examining the mechanisms of parasitic infections, the development of novel treatment strategies, and the optimization of diagnostic techniques, making it a valuable tool for advancing our understanding of parasitology and human health.

Ascidiacea, commonly known as sea squirts, are a class of marine invertebrates that have gained significant attention in scientific research.
As sessile organisms with a unique life cycle, sea squirts offer valuable insights into developmental biology, evolutionary processes, and environmental monitoring.
Researchers often utilize Ascidiacea in experimental protocols involving regenerative biology, biomaterials science, and the study of marine ecosystems, making them a valuable model organism for a wide range of scientific disciplines.

Astacoidea, a superfamily of freshwater crayfish, has emerged as a valuable model organism in various scientific experiments and research protocols.
These decapod crustaceans possess unique physiological and behavioral characteristics that make them highly relevant for studies in fields such as neurobiology, ecotoxicology, and evolutionary biology.
Researchers often utilize Astacoidea species as experimental subjects to investigate topics ranging from nervous system function and regeneration to the impacts of environmental pollutants on aquatic ecosystems, making them a versatile and widely-employed model in the scientific community.

Australorbis glabratus, also known as the Schistosoma-transmitting snail, is a species of freshwater snail that holds significant relevance in various scientific experiments and research protocols.
As a host for the parasitic flatworm Schistosoma, Australorbis glabratus plays a crucial role in the study of schistosomiasis, a neglected tropical disease affecting millions worldwide.
Researchers commonly utilize Australorbis glabratus in laboratory settings to investigate host-parasite interactions, test anti-schistosomal drugs, and develop control strategies for this important public health concern.

Babesia, a genus of protozoan parasites, has become an increasingly important subject of study in the field of scientific research.
These tick-borne parasites, known for their ability to infect red blood cells, are commonly used in experiments related to vector-borne diseases, host-pathogen interactions, and the development of diagnostic and therapeutic interventions.
Researchers across various disciplines, including microbiology, immunology, and veterinary science, have recognized the value of incorporating Babesia into their experimental protocols, making it a crucial component in advancing our understanding of infectious diseases and improving public health outcomes.

Bedbugs (Cimex lectularius) are a common household pest that have gained significant attention in the scientific community due to their potential use in various research applications.
As ectoparasites, bedbugs are valuable model organisms for studying host-parasite interactions, vector-borne disease transmission, and the development of novel pest control strategies.
Researchers often utilize bedbugs in experiments related to insecticide testing, behavioral studies, and the evaluation of new diagnostic tools, making them a relevant and valuable subject in the field of entomology and public health research.

Bees, the industrious pollinators, play a crucial role in scientific research and experiments.
As a model organism, bees offer valuable insights into topics ranging from behavioral studies and toxicology to pollination ecology and environmental monitoring.
Researchers across diverse fields frequently utilize bees to investigate complex phenomena, from the impacts of pesticides on colony health to the intricate communication networks within hive structures, making bees an indispensable component in a wide array of scientific protocols.

Beetles, members of the insect order Coleoptera, have long been a subject of fascination for scientists across various disciplines.
These diverse arthropods offer a wealth of research opportunities, making them a valuable model organism in numerous experimental protocols.
From neurological studies and behavioral investigations to ecological research and toxicology assessments, beetles' unique physiological and behavioral characteristics have proven instrumental in advancing our scientific understanding across a wide range of fields.

Bivalves, a diverse group of mollusks, have long been a subject of interest in scientific research.
These aquatic organisms, which include clams, oysters, and mussels, are widely used in a variety of experimental protocols due to their unique physiological traits and environmental sensitivity.
Bivalves are particularly valuable in studies related to water quality assessment, ecotoxicology, and environmental monitoring, making them an essential component of many research projects focused on understanding the impact of various stressors on aquatic ecosystems.

Blastocystis is a ubiquitous protist that has gained significant attention in the scientific community due to its potential role in various gastrointestinal and systemic disorders.
As a commonly encountered microorganism, Blastocystis has become a subject of extensive research, with its study often incorporated into experimental protocols across fields such as microbiology, parasitology, and gastroenterology.
Researchers investigating the prevalence, genetic diversity, and pathogenic potential of Blastocystis commonly employ techniques like PCR, sequencing, and in vitro culture to better understand this enigmatic protist and its implications for human and animal health.

Bombyx, the silkworm, is a versatile model organism widely used in scientific research and experiments.
As a member of the Lepidoptera order, Bombyx offers valuable insights into insect physiology, development, and genetics, making it a preferred choice for studies ranging from metamorphosis to immune response.
Researchers across various fields, including biology, biotechnology, and materials science, routinely incorporate Bombyx-based protocols to explore innovative applications, from silk production to the development of novel biomaterials.