Morphometric Features of the Thoracic Esophagus in Rabbits

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Published: Jul 5, 2025
DOI: https://doi.org/10.12681/jhvms.38641
Keywords:
rabbit esophagus mucosa muscular membrane serous membrane
А Tybinka
Department of Normal and Pathological Morphology and Forensic Veterinary Medicine, Stepan Gzhytskyi National University of Veterinary Medicine and Biotechnologies Lviv, Lviv, Ukraine
M Zakrevska
Doctor Markevych’s Veterinary Clinic, Lviv, Ukraine
https://orcid.org/0000-0003-0138-1725
I Kovalskyi
Department of Production and Processing Technologies of Small Animal Products, Stepan Gzhytskyi National University of Veterinary Medicine and Biotechnologies Lviv, Lviv, Ukraine
https://orcid.org/0000-0002-5751-5844
Abstract

The morphometric study of the esophagus wall was carried out on the cross-section of the esophagus’ thoracic part in male rabbits (Oryctolagus cuniculus). The area of individual membranes and their structural parts was determined, the correlation between them was established, and the features of their structure and shape were characterized. The superiority of area indicators over linear dimensions (thickness) during morphometric studies were substantiated. The connective tissue’s quantitative and topographic features in general and its fibers in particular were described. It was found that individual differences in the number of mucosal folds caused a high variability in the esophageal lumen area (CV=46.12%), which occupied 8% of the whole organ’s cross-sectional area. These folds also determined the topographic features of the structure and size of the muscularis mucosae and submucosa. Of the total area of the esophageal wall (14.64 mm2), the proportion of individual membranes was as follows: 20.8% - mucous membrane, 11.2% - submucosa, 62.6% - muscle membrane, and 5.4% - serous membrane. More than a half (60.4%) of the mucous membrane area was occupied by the epithelium, the keratinized layer of which was characterized by the highest concentration of neutral mucosubstances and was also the only place for acidic mucosubstances localization. Among three muscular membrane layers, the circular one accounted for the largest area (4.81 mm2), the inner longitudinal layer hit average values (2.85 mm2), and the outer longitudinal layer demonstrated the smallest value (1.49 mm2). Muscle membrane indicators correlated positively with the muscularis mucosae area and the submucosa area. The low and medium variability level of most indicators showed the esophageal wall’s homogenic structure. The serous membrane area was the most variable (CV=58.20%) with the highest density of collagen fibers. The concentration of elastic fibers reached its peak at the junction of the submucosa with the muscle membrane.

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References
Bor S, Capanoglu D (2009) The additive effect of ethanol and extract
of cigarette smoke on rabbit esophagus epithelium. J Gastroenterol
Hepatol 24(2):316-321.
Cecio A (1976) Further histophysiological observations on the lower
esophagus of the rabbit. Cell Tissue Res 168(4):475-488.
Cecio A, Califano G (1967) Neurohistological observations on the
oesophageal innervation of rabbit. Z Zellforsch Mikrosk Anat
(1):30-39.
Cipou MF, Martonos C, Gal AF, Rus V, Vlasiuc I, Miclauș V, Damian
A (2021) Histological and morphometrical study of the oesofagus
in adult domestic rabbit (oryctolagus cuniculus). Rev Rom Med
Vet 31(4):45-49.
De Hertogh G, Ectors N, Van Eyken P, Geboes K. (2006) Review article:
the nature of oesophageal injury in gastro-oesophageal reflux
disease. Aliment Pharmacol Ther 24(2):17-26.
Goyal RK, Chaudhury A (2008) Physiology of normal esophageal motility.
J Clin Gastroenterol 42(5):610-619.
Hughes FB (1955) The muscularis mucosae of the oesophagus of the
cat, rabbit and rat. J Physiol 130(1):123-130.
Hussein BM, Muna HA, Walaa FO (2017) Histological study of esophagus
in dogs and rabbits. Journal University of Kerbala 15(3):55-62.
Johnson LF, Harmon JW (1986) Experimental esophagitis in a rabbit
model. Clinical relevance. J Clin Gastroenterol 8(1): 26-44.
Jung HY, Puckett JL, Bhalla V, Rojas-Feria M, Bhargava V, Liu J, Mittal
RK (2005) Asynchrony between the circular and the longitudinal
muscle contraction in patients with nutcracker esophagus. Gastroenterology
(5):1179-1186.
Liao D, Cassin J, Zhao J, Gregersen H (2006) The geometric configuration
and morphometry of the rabbit oesophagus during luminal
pressure loading. Physiol Meas 27(8):703-711.
Lu X, Gregersen H (2001) Regional distribution of axial strain and
circumferential residual strain in the layered rabbit oesophagus. J
Biomech. 34(2):225-233.
Mapara M, Thomas BS, Bhat KM (2012) Rabbit as an animal model
for experimental research. Dental Research Journal 9(1):111-118.
Mittal RK (2013) Longitudinal muscle of the esophagus: its role in
esophageal health and disease. Curr Opin Gastroenterol 29(4):421-
Mittal RK (2016) Regulation and dysregulation of esophageal peristalsis
by the integrated function of circular and longitudinal muscle layers
in health and disease. Am J Physiol Gastrointest Liver Physiol
(3):431-443.
Mittal RK, Padda B, Bhalla V, Bhargava V, Liu J (2006) Synchrony
between circular and longitudinal muscle contractions during peristalsis
in normal subjects. Am J Physiol Gastrointest Liver Physiol
(3):G431-G438.
Mohammad HJ, Ali AK, Al-Ali ZAJR (2020) Comparative histochemical
and histomorphometrical study of esophagus structures in sheep
(Ovis aries) and rabbits (Oryctolagus Cuniculus). Periódico Tchê
Química. 17(36):457-475.
Mulisch M, Welsch U (2015) Romeis – Mikroskopische Technik. Berlin:
Springer Spektrum 172-309.
Nikaki K, Sawada A, Ustaoglu A, Sifrim D (2019) Neuronal control
of esophageal peristalsis and its role in esophageal disease. Curr
Gastroenterol Rep. 21(11):59.
Nishimura T, Takasu T (1969) The Adrenergic innervation in the esophagus
and respiratory tract of the rabbit. Acta Oto-Laryngologica
(2-6):444-452.
Orlando RC (1998) Review article: oesophageal mucosal resistance.
Aliment Pharmacol Ther 12(3):191-197.
Orlando RC, Bryson JC, Powell DW (1986) Effect of cigarette smoke on
esophageal epithelium of the rabbit. Gastroenterology 91(6):1536-
Park H, Conklin JL (1999) Neuromuscular control of esophageal peristalsis.
Curr Gastroenterol Rep 1(3):186-197.
Parkinson L, Kuzma C, Wuenschmann A, Mans C (2017) Esophageal
smooth muscle hypertrophy causing regurgitation in a rabbit. J Vet
Med Sci. 79(11):1848-1852.
Percy WH, Miller AJ, Brunz JT (1997) Pharmacologic characteristics
of rabbit esophageal muscularis mucosae in vitro. Dig Dis Sci
(12):2537-2546.
Powell D, Morris S, Boyd D (1975) Water and electrolyte transport by
rabbit esophagus. The American Journal of Physiology 229(2):438-
Ranjan R, Das P (2016) Gross morphology and histo-architecture of
rabbit esophagus. Indian Vet. J 93(5):40-44.
Schulze K, Ellerbroek S, Martin J (2001) Matrix composition in opossum
esophagus. Dig Dis Sci. 46(5):968-975.
Selim A, Hazaa E, Goda W (2017) Comparative histological studies of
the esophagus wall of oryctolagus cuniculus rabbit adult, young and
lactating using light microscope. Cytol Histol 8(2):1-4.
Sokolis DP (2010) Strain-energy function and three-dimensional stress
distribution in esophageal biomechanics. J Biomech 43(14):2753-
Sokolis DP (2013) Structurally-motivated characterization of the passive
pseudo-elastic response of esophagus and its layers. Comput Biol
Med 43(9):1273-1285.
Stavropoulou EA, Dafalias YF, Sokolis DP (2009) Biomechanical and
histological characteristics of passive esophagus: experimental
investigation and comparative constitutive modeling. J Biomech
(16):2654-2663.
Stavropoulou EA, Dafalias YF, Sokolis DP (2012) Biomechanical behavior
and histological organization of the three-layered passive
esophagus as a function of topography. Proc Inst Mech Eng H.
(6):477-490.
Tobey NA, Sikka D, Marten E, Caymaz-Bor C, Hosseini SS, Orlando
RC (1999) Effect of heat stress on rabbit esophageal epithelium.
Am J Physiol 276(6):1322-1330.
Uchida K, Kamikawa Y (2007) Muscularis mucosae - the forgotten
sibling. J Smooth Muscle Res 43(5):157-177.
Vegesna AK, Chuang KY, Besetty R, Phillips SJ, Braverman AS, Barbe
MF, Ruggieri MR, Miller LS (2012) Circular smooth muscle
contributes to esophageal shortening during peristalsis. World J
Gastroenterol 18(32):4317-4322.
Zhang DH, Zhou LY, Dong XY, Cui RL, Xue Y, Lin SR (2010) Factors
influencing intercellular spaces in the rat esophageal epithelium.
World J Gastroenterol 16(9):1063-1069.