ABSTRACT
The digestive tract of fish has many morphological adaptations related to habitat and nutrition. Intestinal biometry may reflect these adaptations. Here, we aimed to describe histometric patterns in farmed fish and their relationship with feeding by using a standardized protocol considering cell density by tissue area. Five juvenile specimens of each species (Pseudoplatystoma corruscans, Piaractus mesopotamicus, and Oreochromis niloticus) were used. O. niloticus possessed higher intestinal weight and length besides higher intestinal quotient and intestinal somatic index than the other species. The general histological composition was similar between species. However, P. corruscans showed differences in thickness between the anterior and posterior segments. O. niloticus had thinner serosa and muscularis layers than the other species. The cell density was distinct in both species and segments. Comparing the intestinal segments, O. niloticus displayed the lowest count of granulocytes. Goblet cell density was lower in P. mesopotamicus in all segments. However, the volume of these cells was higher in the anterior and middle anterior segments. Our data demonstrated that intestinal structural plasticity is associated with the difference in feeding habits. Here, we used quantitative standardized histometric criteria to understand the morphophysiological diversity of the fish digestive tract, and this technique can be applied in future studies to evaluate changes in the digestive tracts of vertebrates.
Subject(s)
Catfishes , Cichlids , Animals , Intestines , Cell Count/veterinaryABSTRACT
Lambda-cyhalothrin is a synthetic pyrethroid that mimics the structure and insecticidal properties of pyrethrin, a natural insecticide derived from chrysanthemums. In fish, it disrupts the nervous system, causing motor paralysis and several other alterations associated with varying levels of mortality. This study aimed to evaluate osmoregulatory responses and histological changes in the gills of Oreochromis niloticus chronically exposed to a sublethal dosage (0.86 µg/L) of lambda-cyhalothrin. The mean serum values for Na2+, K+, Cl-, Ca2+, pH, lactate, H+, HCO3, and glucose along to degree of tissue change (DTC) at 24, 96, 168, and 240 h post-exposure (hpe) were evaluated. Lambda-cyhalothrin affected the neuronal motor function at 24 hpe, followed by the increase of the K+, Ca2+, H+, and glucose levels in the exposed group, compared to the control group. Lactate and H+ levels in the exposed group were higher than those in the control group at 168 and 240 hpe respectively. HCO3, and Cl- levels increased at 240 hpe, although there was no change in the pH values. DTC was higher in treated fish than in control fish, but there were no significant differences among time-exposure. The changes detected ranged from hyperemia of the branchial vasculature, eosinophilic granulocytic cell infiltration, mucous cell hyperplasia, and partial fusion of secondary lamellae at 24 hpe to vascular aneurysm formation, and necrosis of the lamellar epithelium at 240 hpe. Thus, a sublethal dosage of lambda-cyhalothrin in the long-term is toxic for Nile tilapia, characterized by hypokalemia, hypercalcemia, hyperglycemia, and respiratory alkalosis, followed by time-dependent histological changes.
