Amphibian

Ambystoma mexicanum, commonly known as the Mexican axolotl, is a critically important model organism in scientific research.
This aquatic salamander has gained significant attention for its remarkable regenerative abilities, making it a valuable subject for studies on tissue repair, stem cell biology, and developmental processes.
Researchers across various fields, from cell and molecular biology to neuroscience and regenerative medicine, utilize Ambystoma mexicanum in their experimental protocols to uncover fundamental insights that can contribute to advancements in human health and biotechnology.

Amphibians are a diverse group of vertebrates that have gained significant attention in the scientific community due to their unique biological characteristics and their widespread use in various research applications.
From toxicological studies to regenerative medicine, amphibians serve as valuable model organisms, offering insights into developmental processes, environmental responses, and even potential therapeutic interventions.
Researchers across fields, including ecology, evolution, and biomedicine, often rely on amphibian-based protocols to further their understanding of biological systems and drive scientific progress.

Anura, the order of amphibians that includes frogs and toads, has become a valuable subject in scientific research due to its unique physiological and behavioral characteristics.
Commonly used in a variety of experimental protocols, Anura species offer insights into fields ranging from developmental biology and neuroscience to toxicology and environmental studies.
Researchers seeking robust, reproducible protocols involving Anura will find a wealth of resources exploring the diverse applications of these captivating creatures in modern scientific investigations.

Bufonidae, commonly known as true toads, are a family of amphibians that have become increasingly relevant in scientific research and experimentation.
As ectothermic vertebrates, Bufonidae offer unique insights into various physiological processes and serve as valuable model organisms in a wide range of studies, including toxicology, developmental biology, and environmental monitoring.
Researchers frequently utilize Bufonidae in protocols exploring topics such as skin permeability, endocrine function, and the impact of environmental stressors, making this family of amphibians a crucial component in advancing our understanding of biological systems.

Newts, amphibian creatures belonging to the family Salamandridae, have long been a subject of interest in the scientific community.
These small, slender-bodied animals possess remarkable regenerative capabilities, making them valuable models for studying tissue repair and development.
Newts are commonly used in a variety of research applications, including studies on stem cell biology, wound healing, and the mechanisms of limb and organ regeneration, providing valuable insights that can inform advancements in human medicine and biomedical engineering.

Rana, the genus of true frogs, is a widely used model organism in scientific research.
These amphibians offer valuable insights into diverse fields, from developmental biology and neuroscience to ecotoxicology and evolutionary studies.
Researchers commonly employ Rana species, such as the American bullfrog (Rana catesbeiana) and the common frog (Rana temporaria), to investigate topics ranging from stem cell dynamics and regeneration to the impact of environmental contaminants on aquatic ecosystems.

Rana catesbeiana, commonly known as the American bullfrog, is a widely-used model organism in various scientific experiments and research protocols.
Its large size, quick growth, and well-understood biology make it a valuable subject for studies in fields such as developmental biology, physiology, and neuroscience.
Bullfrogs' sensitivity to environmental factors and ease of maintenance in laboratory settings contribute to their widespread adoption as a reliable model for investigating topics ranging from toxicology to regenerative medicine.

Salamanders, members of the order Caudata, have long been a subject of scientific fascination and a widely used model organism in a variety of research protocols.
These amphibians, known for their remarkable regenerative abilities, are particularly valuable in studies exploring stem cell biology, tissue repair, and developmental processes.
Salamanders' unique physiological characteristics and their suitability for laboratory experimentation make them a versatile and invaluable tool for researchers across disciplines, including cell biology, genetics, and environmental toxicology.

Tadpole, the larval stage of amphibians, is a valuable model organism in various scientific experiments.
Its unique developmental stages and responsiveness to environmental cues make it highly relevant for research in fields such as evolutionary biology, developmental biology, and ecotoxicology.
Tadpoles are commonly used to investigate topics like metamorphosis, the effects of environmental pollutants, and the genetic regulation of embryonic development, providing valuable insights that can inform our understanding of both human and animal health.

Xenopus, a genus of aquatic frogs, has long been a valuable model organism in scientific research.
This amphibian's unique biological features, such as its rapid development and large embryos, make it a popular choice for studies in developmental biology, cell signaling, and toxicology.
Xenopus is widely used in a variety of experimental protocols, from gene expression analysis to high-throughput drug screening, offering researchers a versatile and well-characterized system to advance their scientific investigations.

Xenopus laevis, the African clawed frog, is a widely used model organism in scientific research, particularly in the fields of developmental biology, cell biology, and neuroscience.
Its ease of maintenance, rapid embryonic development, and well-characterized genetics make it a valuable tool for studying fundamental biological processes, such as cell signaling, gene expression, and organ formation.
Xenopus laevis is commonly employed in a variety of experimental protocols, including embryo manipulation, oocyte injection, and protein expression, making it a versatile and indispensable model system for researchers across multiple disciplines.