Cardiac effusion and serum biochemical abnormalities of Salmonella gallinarum infection in point of lay pullets

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Publicado: Jan 16, 2025
DOI: https://doi.org/10.12681/jhvms.37369
SC Okafor
Department of Veterinary Pathology and Microbiology, Faculty of Veterinary Medicine, University of Nigeria, Nsukka, 410002, Enugu State, Nigeria
JI Ihedioha
Department of Veterinary Pathology and Microbiology, Faculty of Veterinary Medicine, University of Nigeria, Nsukka, 410002, Enugu State, Nigeria
https://orcid.org/0000-0002-0780-7531
WS Ezema
Department of Veterinary Pathology and Microbiology, Faculty of Veterinary Medicine, University of Nigeria, Nsukka, 410002, Enugu State, Nigeria
Resumen

The aim of this study was to evaluate some lesions and biochemical abnormalities of fowl typhoid (FT) in point of lay (POL) pullets. Fifty POL pullets were randomly assigned to two groups of 25 infected orally with S. gallinarum (109 S. gallinarum colony forming units (CFUs)/mL), and 25 uninfected controls. Blood samples were collected from four randomly selected pullets in each group weekly for 35 days post infection (PI), and the harvested serum used for biochemical evaluations, following standard techniques. Relevant tissues were processed for histopathology. Significant (P < 0.05) loss of body weight, 48% morbidity, 12% overall mortality, significant drop in egg production and severe pericardial effusion were observed in the infected pullets when compared to the uninfected controls. There was significantly (P < 0.05) higher serum alanine aminotransferase (ALT), aspartate aminotransferase (AST), alkaline phosphatase (ALP), superoxide dismutase (SOD) and catalase (CAT) activities, malondialdehyde (MDA), serum total protein, globulin, total cholesterol, total bilirubin, uric acid, and creatinine levels, and lower serum albumin level in the infected POL pullets than that of the uninfected controls on days 7, 14, 21, 28 and 35 PI. The assayed biochemical parameters variably correlated with egg production, with MDA, SOD and CAT highly significant (P < 0.01). Inflammatory, degenerative and necrotic changes were observed in the heart, liver, spleen, kidneys, lungs, intestine and ovary of the infected POL pullets. Based on the significant elevation in MDA level in the infected POL pullets when compared to the uninfected controls coupled with highly significant correlation between the MDA, and egg production, oxidative stress (OS) may play a significant role in the pathology caused by FT. An association was established between elevated OS markers with antioxidant properties (SOD and CAT) and clinical outcome, including survival/health improvement indices such as improved weight gain and egg production as well as low mortality rate in an acute disease like FT. This suggests that inclusion of antioxidants in the treatment of FT in POL pullets may further ameliorate morbidity, development of lesions, improve weight gain and egg production, and reduce mortality, more so, considering the global menace of antimicrobial resistance.

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Citas
Anchinmane VT, Puranik GV (2011) The diagnostic separation of transudates
and exudates in ascitic fluid and pleural fluid. Bombay Hosp
J 53 (2):166-172.
Ayala A, Munoz MF, Arguelles S (2014) Lipid peroxidation: Production,
metabolism, and signaling mechanisms of malondialdehyde and
-hydroxyl-2-monenal. Oxid Med Cell Longev 360438.
Baldrey V (2012) Interpreting blood profiles in avian. Vet Times. https://
www.vettimes.co.uk. Accessed October 22.
Barbour EK, Ayyash DB, Alturkistni W, Alyahiby A, Yaghmoor S, Iyer A,
Yousef J, Kumosani T, Harakeh S (2015) Impact of sporadic reporting
of poultry Salmonella serovars from selected developing countries. J
Infect Dev Ctries 9: 1-7.
Braun U, Pospischil A, Pusterla N, Winder C (1995) Ultrasonographic
findings in cows with cholestasis. Vet Rec 18: 537-543.
Chickipedia (2019) Health and Biosecurity: What is a Healthy Hen?
Chickipedia.com. 60 - 68. https://hn-int.com/health -biosecurity/
Chiroma MA, Adamu S, Gadzama JJ, Esievo KAN, Abdulsalam H, Balami
AG, Enam SJ, Muhammad Y, Atata AJ (2017b) Some plasma biochemical
changes in layers experimentally infected with Salmonella
gallinarum. Afr J Cell Pathol 9: 66-77.
Colville J (2002) Blood chemistry. In: Hendrix CM (ed). Laboratory Procedures
for Veterinary Technicians. 4th ed, Missouri, USA, Mosby
Inc: pp75-103.
Davoudi SM, Eshagian M, EdalatiNasab M (2013) Overview of hepatic
disease in large animals. Adv Biores 4: 12-20, ISSN 2277-1573.
Doumas BT, Peters TJr (1997) Serum and urine albumin: a progress report
on their measurement and clinical significance. Clinica Chimica Acta
(1): 3-20.
Draper HH, Hadley M (1990) Malondialdehyde determination as an index
of lipid peroxidation. Meth Enzymol 186: 421-431.
Forbes N (2008) Avian hematology and biochemistry panels. LafeberVet
Website. Available at https://lafeber.com/vet/avian-hematology/
Galovicova L, Borotova P, Vukovic NL, Vukic M, Kunova S, Hanus P,
Kowalczewski PL, Bakay L, Kacaniova M (2022) The Potential Use
of Citrus aurantifolia L. Essential Oils for Decay Control, Quality
Preservation of Agricultural Products, and Anti-Insect Activity.
Agronomy 12: 735. https://doi.org/10. 3390/agronomy12030735.
Gonzales R, Auclair C, Voison E, Gautero H, Dhermy D, Boivin P (1984)
Superoxide dismutase, catalase and glutathione peroxidase in red
blood cells from patients with malignant diseases. Cancer Res 44:
-4139.
Gregory PS, Carl RK (2001) Cerebrospinal, synovial and serous body fluids.
In John Bernard Henry editor. Clinical diagnosis and management
by laboratory methods. Philadelphia, WB Saunders: pp 415-422.
Haque AKMZ, Akter MR, Islam SS, Alam J, Neogi SB, Yamasaki S,
Kabir SML (2021) Salmonella gallinarum in small-scale commercial
layer flock. Vet Sci 8: 71.
Harr KE (2006) “Diagnostic value of biochemistry”. In: Harrison GJ,
Lightfoot TL, eds. Clinical Avian Medicine. Palm Beach, FL, Spix
Publishing: pp 611-629.
Hegele RA (2013) Lipoprotein and lipid metabolism. In: Emery and Rimoin’s
principles and practice of medical genetics. 6th ed.
Higgins T, Beutler E, Doumas BT (2008b) Bilirubin. Analytical methodology-
serum bilirubin. In: Burtis CA, Ashwood ER, Bruns DE eds.
Tietz Fundamentals of Clinical Chemistry. 6th ed, Missouri, Saunders
Elsevier: pp 524-525.
Ivanov AV, Valuev-Elliston VT, Ivanova ON, Kochetkov SN, Starodubova
ES, Bartosch B, Isaguliants MG (2016) Oxidative stress during HIV
infection: Mechanisms and consequences. Oxid Med Cell Longev
Johnson AM (2008) Amino acids and proteins. In: Burtis CA, Ashwood
ER, Bruns DE eds. Tietz Fundamentals of Clinical Chemistry. 6th ed,
Missouri, Saunders Elsevier: pp 206-316.
Kaneko JJ (1997) Serum proteins and the dysproteinemias. In: Kaneko J,
Harvey J, Bruss M, eds. Clinical Biochemistry of Domestic Animals.
th ed, San Diego, CA, Academic Press: pp 117-138.
Kokosharov T (2006) Changes in the protein profile in birds with experimental
acute fowl typhoid. Bulgarian J Vet Med 9(3): 189-192.
Lamb EJ, Price CP (2008) Creatinine, urea and uric acid. In: Burtis CA,
Ashwood ER, Bruns DE eds. Tietz Fundamentals of Clinical Chemistry.
th ed, Missouri, Saunders Elsevier: pp 363-372.
Lopes PD, Freitas Neto OC, Batista DFA, Denadai J, Alarcon MFF,
Almeida AM, Vasconcelos RO, Setta A, Barrow PA, Berchieri Junior
A (2016) Experimental infection of chickens by a flagellated motile
strain of Salmonella enterica serovar gallinarum biovar gallinarum.
The Vet J 214: 40-46.
OIE (2012). World Organization for Animal Health. Manual of Diagnostic
Tests and Vaccines for Terrestrial Animals. `Marian Truszczynski
eds. WOAH Standard commission Publication, Office International
Epizooties. 1-19.
Okafor SC, Ihedioha JI, Ezema WS (2023) Hematological alterations in
laying hens infected with Salmonella gallinarum, and their relationship
with egg production. J Vet Appld Sci 13(1): 109-117.
Okoroafor ON, Ogunniran TM, Ikenna-Ezeh NH, Udeani IJ, Omeke JN,
Ezema WS, Anene B (2021) Effects of dietary supplementation of
Vitamins E and C on oxidative stress induced by a Nigerian velogenic
strain of the Newcastle disease virus (KUDU 113) in the brain and
bursa of Fabricius of broiler chickens. Vet World 14(9): 2452-2461.
Okwori AEJ, Ogbe R, Chollom SC, Agada GOA, Ujah A, Okwori E, Adeyanju
ON, Echeonwu GON (2013) Isolation of Salmonella gallinarum
from poultry droppings in Jos metropolis, Plateau State. Nig J
Agric Vet Sci 5(2):14-44.
Palipoch S, Koomhin P (2015) Oxidative stress associated pathology: A
review. Sains Malaysiana 44(10): 1441-1451.
Parvej MS, Nazir KH, Rahman MB, Jahan M, Khan MF, Rahman M
(2016) Prevalence and characterization of multi-drug resistant Salmonella
Enterica serovar Gallinarum biovar Pullorum and Gallinarum
from chicken. Vet World 9: 65-70.
Patterson RA, Leacke DS (1998) Human serum cysteine and histidine
inhibit the oxidation of low- density lipoprotein less at acidic pH.
Federal Euro Biochem Soc Letters 434: 317-321.
Paul PK, Haider MG, Khaton R, Ghosh SK, Das PM, Hossain MM (2015)
Pathological investigation of fowl typhoid in chickens in Mymensingh.
Ann Bangladesh Agric 19: 33-41.
Rifai N, Warnick GR, Remaley AT (2008) Analysis of lipids, lipoproteins
and apolipoproteins. In: Burtis CA, Ashwood ER, Bruns DE eds. Tietz
Fundamentals of Clinical Chemistry. 6th ed, Missouri, Saunders
Elsevier: pp 422-427.
Samour J, Silvanose C, Pendi H, Bailey TA (2015) Clinical and laboratory
diagnostic examination. In: Samour J, ed. Avian Medicine. 3rd ed, St
Louis, MO, Elsevier Health Sciences.
Shah SN, Kamil SA, Darzi MM, Mir MS, Bhat SA (2013) Hematological
and some biochemical changes in experimental fowl typhoid infection
in broiler chickens. Comp Clin Pathol 22: 83-91. Doi 10.1007/
s00580-011-1371-8.
Shivaprasad HL, Barrow PA (2008) Pullorum disease and fowl typhoid.
In: Calnek BW, Barnes HJ, Beard CW, McDougald LR, Saif YM,
eds. Diseases of poultry. 12th ed, Ames, IA, Blackwell Publishing: pp 620-636.
Sikandar A, Zaneb F, Younus M, Masood S, Aslam A, Khattak F, Ashraf
S, Yousaf MS, Rehman H (2017) Effect of sodium butyrate on performance,
immune status, microarchitecture of small intestinal mucosa
and lymphoid organs in broiler chickens. Asian-Australian J Anim
Sci 30(5): 690-699.
Simsek S, Yuce A, Utuk AE (2006) Determination of serum malondialdehyde
levels in sheep naturally infected with Dicrocoelium dendriticum.
Firat Univ Saglik Bil Dergisi 20: 217-220.
Weydert CJ, Cullen JJ (2010) Measurement of superoxide dismutase, catalase
and glutathione peroxidase in cultured cells and tissues. Nature
Protocols 5(1): 51-66.
Yasmin S, Nawaz M, Anjum AA, Ashraf K, Ullah N, Mustapha A, Ali
MA, Mehmood A (2019) Antibiotic susceptibility pattern of Salmonellae
isolated from different districts of Punjab, Pakistan. Pak Vet J
: 98-102.
Zanetti NS, De Carli S, Sonza MN., Lehmann FKM., Kipper D, Dias
KKR, Fonseca ASK, Lunge VR, Ikuta N (2019) Molecular detection
and Characterization of Salmonella gallinarum from poultry farms in
Brazil. J Appld Poult Res 28: 1335-1341.
Zhou X, Kang X, Zhou K, Yue M (2022) A global dataset for prevalence
of Salmonella gallinarum between 1945 and 2021. Sci Data 9: 495.
doi: 10.1038/s41597-022-01605-x.