466
Volume 5, Issue 10: Special Issue
(EJAR)
ISSN: 2181-2020
MPHAPP
THE 6TH INTERNATIONAL SCIENTIFIC AND PRACTICAL
CONFERENCE
“
MODERN PHARMACEUTICS: ACTUAL
PROBLEMS AND PROSPECTS
”
TASHKENT, OCTOBER 17, 2025
in-academy.uz
EXPERIMENTAL ANIMAL MODELS USED IN LIVER DISEASES
Kuranboyeva M.G.
Tashkent Pharmaceutical Institute, Tashkent city, Republic of Uzbekistan
e-mail: quranboyevamehriniso@gmail.com
https://doi.org/10.5281/zenodo.17342474
Relevance:
Liver diseases are among the leading causes of mortality worldwide. Animal
models play a crucial role in the preclinical stage for the development and evaluation of
hepatoprotective drugs. Liver disorders such as hepatitis, steatosis, fibrosis, and cirrhosis pose
significant social and economic challenges globally. According to the World Health
carcinoma. In such circumstances, the development of hepatoprotective therapies becomes an
urgent issue, and reliable experimental model systems are essential for evaluating drug efficacy.
Objective of the study:
This abstract analyzes the mechanisms of various experimental
models, their clinical relevance, evaluation criteria, and modern innovative approaches.
Methods and methodology:
Modern scientific literature was reviewed during the preparation
of this abstract. Data was collected from databases such as PubMed, Scopus, Google Scholar, and
Elsevier.
Results:CCl₄(Carbon tetrachloride):
Causes hepatocyte damage through free radicals,
leading to necrosis. Advantages of this model include high reproducibility and reliability in modeling
fibrosis and cirrhosis. CCl₄ generates free radicals in hepatocytes, damaging cell membranes and
stimulating collagen production. Fibrosis develops within a short period (typically 4–8 weeks).
Widely used in scientific literature with well-established methodology.
Limitations:
The mechanism
does not fully match human hepatotoxicity. CCl₄ vapors are toxic and require safety precautions. It
can also harm other tissues (kidneys, lungs). Sensitivity may vary between animals.
Paracetamol(APAP-acetaminophen):
Useful for studying drug-induced hepatotoxicity
(closely mimics clinical conditions). Like in humans, toxic metabolite N-acetyl-p-benzoquinone
imine (NAPQI) is formed in the liver. Allows assessment of effective antidote therapies (e.g., N-
acetylcysteine).
Limitations:
The toxic dose range is narrow—slight overdose may be fatal for
animals. It models only acute liver injury, not chronic conditions. The activity index changes rapidly,
making the timing of analysis critical.
Thioacetamide(TAA):
Long-term administration reliably models chronic fibrosis and
cirrhosis. Accurately mimics clinical features such as portal fibrosis, nodule formation, and
neovascularization. Mechanistically different from the CCl₄ model—induces fibrosis via
hepatotoxicity.
Limitations:
Less commonly used, and the methodology is more complex. May cause
concurrent kidney damage due to hepatotoxicity. Hypoxia and significant weight loss may lead to
stress in animals.
Paracetamol+Ethanol Combined Model:
APAP is safe at normal doses but converts to the
toxic metabolite NAPQI at high doses. Ethanol induces CYP2E1, increasing NAPQI formation. It
also weakens the glutathione detoxification system, making the liver more vulnerable to NAPQI. This
combination leads to oxidative stress, mitochondrial dysfunction, and necrosis.
Advantages:
Highly
clinically relevant. Accurately models drug–alcohol toxicity seen in humans. Enables realistic
evaluation of hepatoprotective and antidote therapies (e.g., N-acetylcysteine).
Conclusion:
Each model has its own biological advantages and limitations, and should be
selected based on the specific research objective. For instance, while the CCl₄ model is simple and
reproducible, it has high overall toxicity. The paracetamol model closely mimics clinical scenarios
467
Volume 5, Issue 10: Special Issue
(EJAR)
ISSN: 2181-2020
MPHAPP
THE 6TH INTERNATIONAL SCIENTIFIC AND PRACTICAL
CONFERENCE
“
MODERN PHARMACEUTICS: ACTUAL
PROBLEMS AND PROSPECTS
”
TASHKENT, OCTOBER 17, 2025
in-academy.uz
and allows precise assessment of cytotoxicity. The ethanol model is useful in modeling chronic
alcoholic liver diseases, but requires extended duration and may be influenced by individual animal
sensitivity. Combined models (e.g., paracetamol + ethanol) allow for deeper study of complex
pathogenesis.
