Chicken Interferon γ,IFN-γ ELISA Kit

SKU:BHE10500457
Overview
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Quantitative ELISA kit for measuring chicken Interferon γ (IFNG) in serum, plasma, and tissue homogenates to support immunology studies. Sensitivity 3.125 pg/mL, detection range 3.125 pg/mL–800 pg/mL, typical assay time 1–5 h.
Target IFN-γ
Species Gallus gallus (Chicken)
Sample Type(s) serum, plasma, tissue homogenates
Assay Type Competitive ELISA (quantitative)
Sensitivity 3.125 pg/mL
Detection Range 3.125 pg/mL-800 pg/mL
Assay Time 1-5h
Options selector
Catalog no. Size
CSB-E08550Ch-96T 96 T
CSB-E08550Ch-96TX5 96 T×5
CSB-E08550Ch-96TX10 96 T×10
Available Options

Select from the available variant options shown for this product. Availability and lead time can vary by option.

  • Options: Size (96 T, 96 T×10, 96 T×5).
  • Lead time: options listed as "In Stock at Manufacturer" typically ship in 5–7 business days; other statuses may take longer.
  • Storage: refer to the product datasheet for storage and handling.
  • Sales terms and conditions: Please review prior to ordering.
Field Specification
Mfr No CSB-E08550Ch
Alternative Names IFNG ELISA Kit; Interferon gamma ELISA Kit; IFN-gamma ELISA Kit
Assay Time
  • 1-5h
Assay Type
  • Competitive ELISA (quantitative)
Detection Range 3.125 pg/mL-800 pg/mL
Detection Wavelength 450 nm
Product Type
  • ELISA Kits
Reactivity
  • Chicken
Sample Type(s) serum, plasma, tissue homogenates
Sensitivity 3.125 pg/mL
Species Gallus gallus (Chicken)
Target IFN-γ
UniProt # P49708

Background

Interferon γ (IFNG) is a biological molecule commonly studied in immunology research. It is commonly used as a molecular readout in mechanistic and biomarker-focused studies.

UniProt: P49708

Biological context

Researchers often monitor Interferon γ in serum, plasma, and tissue homogenates to better understand themes such as innate and adaptive immune responses, cytokine signaling networks, and host–pathogen interactions. In many model systems, measured levels can shift with physiology, experimental perturbation, or disease-associated changes, making careful biological interpretation important.

Interpreting changes in measured levels

Depending on sample matrix and study design, increases or decreases in Interferon γ may reflect differences in expression, secretion, turnover, or compartmentalization rather than a single mechanism. Interpretation is typically strengthened by evaluating related molecules (for example, cytokines, chemokines, acute-phase proteins, and immune-cell activation markers) and by keeping pre-analytical variables consistent across groups.

Nomenclature

In publications and databases, Interferon γ may also appear under names such as IFNG and Interferon gamma. When comparing studies, confirm that the reported analyte refers to the same molecule and species context.

Why ELISA data are widely used

ELISA is a common approach for quantitative measurement of proteins and biomarkers in complex samples, enabling comparisons across experimental groups and time points. When integrating results with other readouts, consider species biology, sample type, and the broader pathway context that Interferon γ participates in.

Can’t Find What You’re Looking For? We can help you source the best match or customize an ELISA solution for your study. Options may include alternative target synonyms, different species reactivity, sample type/matrix compatibility (serum/plasma/lysate/supernatant), assay format (sandwich/competitive), sensitivity/range, detection chemistry (colorimetric/fluorescent/chemiluminescent), plate format (pre-coated/uncoated, strips vs full plate), and bulk or custom packaging. Click Talk to a Scientist to submit a request form, email us at support@biohippo.com, or explore our Research Services for additional support. Our team will be in contact with you shortly.

Spleen transcriptomics reveals breed-specific mechanisms of Salmonella resistance under heat stress in chickens

Y Wang, Q Wang, Z Wang, X Li, MS Elsharkawy, Y Lu,Poultry Science,2025

Modulation of Intestinal Health and Metabolism by Dietary Portulaca oleracea L. Extract Enhances Growth Performance, Immune Function, and Meat Quality in Wenchang chickens

Y Zhang, Y Yang, Y Li, Y Sun, X Han, H Liu, X Zhao,Poultry Science,2025

The inhibitory effect of Hypericum japonicum on H9N2 avian influenza virus

H Hu, J Li, S Zheng, K Zhao, Y Xia, X Wei, M Han,Advanced Biotechnology,2024

Effects of Escherichia coli strain Nissle 1917 on immune responses of Japanese quails (Coturnix japonica) to Newcastle disease vaccines

R Abbasi Kali, Iranian Journal of Veterinary Research,2023

Investigation of the Potential of Heterophil/Lymphocyte Ratio as a Biomarker to Predict Colonization Resistance and Inflammatory Response to Salmonella enteritidis Infection in Chicken

M Thiam,Pathogens,2023

Effect of Two Particle Sizes of Nano Zinc Oxide on Growth Performance, Immune Function, Digestive Tract Morphology, and Intestinal Microbiota Composition in Broilers

J Qu,Animals,2023

Impact of stocking density and dietary nano-zinc supplementation on stress indicators, immunity, and DNA damage in broiler chickens

Ö Sevim,Journal of the Hellenic Veterinary Medical Society,2023

Comparative Analysis of the Liver Transcriptome of Beijing You Chickens and Guang Ming Broilers under Salmonella enterica Serovar Typhimurium Infection

Z Wang,Microorganisms ,2022

Synergistic Immunosuppression of Avian Leukosis Virus Subgroup J and Infectious Bursal Disease Virus Is Responsible for Enhanced Pathogenicity

W Chen,Viruses,2022

Evaluation of immunoprotective effects of recombinant protein and DNA vaccine based on Eimeria tenella surface antigen 16 and 22 in vivo

Rui Fang,Parasitology Research,2021

Effects of different levels of Hermetia illucens larvae meal on performance, egg quality, yolk fatty acid composition and oxidative status of laying hens

Xin Liu,Italian Journal of Animal Science,2021

In vivo immunoprotective comparison between recombinant protein and DNA vaccine of Eimeria tenella surface antigen 4

P Zhao,Veterinary Parasitology,2020

A Novel Adjuvant “Sublancin” Enhances Immune Response in Specific Pathogen-Free Broiler Chickens Inoculated with Newcastle Disease Vaccine

Liu Y, et al,Journal of Immunology Research,2019

Effect of Acute Heat Stress on the mRNA Levels of Cytokines in Broiler Chickens Subjected to Embryonic Thermal Manipulation

Saleh KMM, et al,Animals,2019

Immunogenic potential and protective efficacy of a sptP deletion mutant of Salmonella Enteritidis as a live vaccine for chickens against a lethal challenge

Yaxin Guo, et al,International Journal of Medical Microbiology,2019

Lack of Toxic Interaction Between Fusariotoxins in Broiler Chickens Fed throughout Their Life at the Highest Level Tolerated in the European Union

Metayer JP, et al,Toxins,2019

The effects and combinational effects of Bacillus subtilis and montmorillonite supplementation on performance, egg quality, oxidation status, and immune response in laying hens

J.F.Chen, et al,The Egyptian Journal of Neurology, Psychiatry and Neurosurgery,2019

Effects of Supplementing Laying Hens with Purified Amino Acid Prepared from Animal Blood

N. Joshi, et al,Tropical animal science journal,2019

Grape Seed Proanthocyanidin Extract Alleviates AflatoxinB1-Induced Immunotoxicity and Oxidative Stress via Modulation of NF-κB and Nrf2 Signaling Pathways in Broilers

Shahid Ali Rajput, et al,Toxins,2019

Dietary Supplementation of Purified Amino Acid Derived from Animal Blood on Immune Response and Growth Performance of Broiler Chicken

T. G. Wandita.et al,Tropical Animal Science Journal,2018

The molecular characterization and protective efficacy of microneme 3 of Eimeria mitis in chickens

XinmeiHuang.et al,Veterinary Parasitology,2018

Gene cloning, expression and immune adjuvant properties of the recombinant fusion peptide Ta1-BLP on avian influenza inactivate virus vaccine

CongZhang.et al,Microbial Pathogenesis,2018

Molecular characterisation and the protective immunity evaluation of Eimeria maxima surface antigen gene

Tingqi Liu.et al,Parasites & Vectors,2018

Validation of immunomodulatory effects of lipopolysaccharide through expression profiling of Th1 and Th2 biased genes in Newcastle disease virus vaccinated indigenous chicken

Rabia Bhardwaj.et al,Veterinary World,2018

Heat stressDecreases expression of the cytokines, avian B-defensins 4 and 6 and Toll-like receptor 2 in broiler chickens infected with Salmonella Enteritidis

W.M. Quinteiro-Filho.et al,Veterinary Immunology and Immunopathology,2017

The Molecular Characterization and Immunity Identification of Microneme 3 of Eimeria acervulina.

Zhang Z.et al,J Eukaryot Microbiol.,2016

Immunization with avian metapneumovirus harboring chicken Fc induces higher immune responses.

Paudel S.et al,Virus Res.,2016

Effect of Antibiotic Growth Promoters on Anti-oxidative and Anti-inflammatory Activities in Broiler Chickens

Kabploy K.et al,The Thai Journal of Veterinary Medicine,2016

Influenza Inactive Virus Vaccine with the Fusion Peptide (rTa1- BP5) Enhances Protection Against Influenza Through Humoral and Cell-Mediated Immunity

Chen Wang.et al,/,2016

Glycated serum albumin stimulates expression of endothelial cell specific molecule-1 in human umbilical vein endothelial cells: Implication in diabetes mediated endothelial dysfunction

Nirala BK. et al,Diab Vasc Dis Res,2015

Immune responses to oral vaccination with Salmonella-delivered avian pathogenic Escherichia coli antigens and protective efficacy against colibacillosis.

Lee JH.et al,Can J Vet Res.,2015

Immune protection of Microneme 7 (EmMIC7) against Eimeria maxima challenge in chickens

Huang J. et al,Avian Pathol,2015

Eimeria maxima microneme protein 2 delivered as DNA vaccine and recombinant protein induces immunity against experimental homogenous challenge

Huang J. et al,Parasitol Int,2015

Expression analysis of programmed death ligand 2 in tumors caused by the avian oncovirusMarek's disease virus

Matsuyama-Kato A et al,Arch Virol,2014

Omega-3 polyunsaturated fatty acids enrichment alters performance and immune response in infectious bursal disease challenged broilers

Elham Maroufyan et al,Lipids in Health and Disease,2012

Improving the potency of DNA vaccine against Chicken Anemia Virus (CAV) by fusing VP1 protein of CAV toMarek's Disease Virus (MDV) Type-1 VP22 protein

Hassan Moeini et al,Virology Journal,2011

Development of a DNA vaccine against chicken anemia virus by using a bicistronic vector expressing VP1 and VP2 proteins of CAV

/,Comparative Immunology, Microbiology and Infectious Diseases,2011

Bursopentine as a Novel Immunoadjuvant Enhances both Humoral and Cell-Mediated Immune Responses to Inactivated H9N2 Avian Influenza Virus in Chickens

/,clinical and vaccine immunology,2011

Lactobacillus acidophilus as a live vehicle for oral immunization against chicken anemia virus

Hassan Moeini et al,Tumor Biology,2010

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