The main objective of this study was to analyze the clinical and histopathological changes caused by the recurrence of hydrocephalus secondary to shunt dysfunction.
The Morris water maze test is well established in the literature due to its easy application, reliability, applicability and evidence of its validity as an assessment of spatial memory [12].
The test was performed on the P14 and P15 in all groups. The THOT group, exceptionally, was evaluated again on the P19 and P20.
Despite memory impairment, hydrocephalic animals still have the ability to learn. In the present study, when considering the performances within the same group, the THOT group showed improvements in the first and second assessments.
In the comparative analysis between groups, the THOT group, during its first evaluation, presented the longest arrival time among the other animals studied. After unblocking the system, a reduction in arrival time was observed compared to the first assessment in all periods considered. Despite the improvement in the performance between the first and second assessments, there was still a significant difference between the arrival times of this group in relation to others.
These findings show that despite the improvement in performance after shunt revision, the impairment in spatial memory was irreversible during the period studied: the performance of the THOT group was inferior despite the treatment implemented and despite the greater chronological age of this group at the time of comparison (animals in the THOT group were 26 and 27 days old in their second evaluation).
Through histological study with Luxol fast-blue, the control group had the highest average thickness of the corpus callosum compared to the other groups. Furthermore, the untreated hydrocephalic group had a smaller thickness of the corpus callosum compared to the groups undergoing treatment, with or without obstruction. These findings demonstrate that surgical treatment, if instituted in a timely manner, is capable of partially reversing the involvement of the periventricular white matter.
Through an immunohistochemical study using GFAP, a quantitative and qualitative analysis of the astrocytic reaction was carried out.
In the study of the corpus callosum sheets, the THOT group showed a more intense astrocytic reaction compared to the other groups: in addition to the greater astrocytic density, the cells were intensely marked, with coarse and irregular extensions. Astrocytic density and reaction intensity were higher in the surgical groups, even compared to the untreated hydrocephalic group. The inflammatory reaction in response to surgical trauma and the presence of a ventricular catheter can be considered as a possible cause for this finding. Furthermore, it is known that the reconstitution of the periventricular white matter also occurs at the expense of astrocytic proliferation, resulting in an increase in the immunoreaction for GFAP. In the present study, an intense astrocytic reaction was evident in the THOT group, and this discrepancy could be explained both by the recurrence of hydrocephalus and by multiple surgical approaches.
The evaluation of the germinal matrix slides showed differences between all groups. The slides from the surgical groups demonstrated a greater number and greater intensity of marking compared to the control and NTH groups. The THOT group not only demonstrated a greater intensity of the astrocyte reaction, but also a tendency towards a greater number of reactive astrocytes.
In the present study, it was noted that the astrocytic reaction in the CTX_F was less evident in this region when compared to the periventricular regions. However, as previously described, the groups with untreated hydrocephalus and the groups undergoing surgical treatment, especially the THOT group demonstrated a more intense astrocytic reaction than the animals in the control group.
The same pattern can be observed in the CA1 and CA2 subareas of the hippocampus: the groups undergoing surgical treatment demonstrated a higher astrocytic density than the others; the intensity of the reaction was varied. In the dentate gyrus, a greater number of reactive astrocytes was evident in the groups with untreated hydrocephalus and obstructed shunt compared to the others.
A possible explanation for the presence of the intense astrocytic reaction in the group that had the shunt obstructed would be the cumulative effect of the lesions caused by hydrocephalus before treatment and after the catheter was obstructed. Furthermore, considering the possible beneficial effect of the astrocytic reaction on the reconstitution of brain tissue (Aoyama et al., 2006), intense immunostaining with GFAP may also be associated with the treatment of hydrocephalus. In contrast to the treated hydrocephalic group, in which euthanasia was performed 21 days after the procedure, euthanasia in the THOT was performed only 3 days after the last procedure, thus reducing the time available for reduction in the astrocytic response in this group.
When analyzing caspase-3 immunostaining, the findings were contrasting between the different regions, as previously stated. Caspases are involved in the process of programmed cell death essential for brain development, in addition to being effectors in the destruction of aberrant or dysfunctional synapses and axonal connections [13]. Furthermore, it has been demonstrated they are also inducers of cellular apoptosis in response to traumatic and ischemic stimuli [14]. Despite the mechanism that led to the initiation of the apoptosis process, cells in the process of cell death can only be visualized for a short period of time before their disappearance [15].
These factors may have influenced the differences found between the two regions analyzed. Firstly, it was not possible to differentiate whether the cellular immunostaining by caspase occurred in response to the damage induced by hydrocephalus or whether it corresponded to programmed cell death that would occur during brain development. Secondly, the evaluation was carried out on the 28th day after birth in all animals from all groups: the analysis of the slides in a single period does not allow us to conclusively determine in which groups and in which regions there was the highest rate of cell death due to apoptosis.
Cyclooxygenase-2 is an enzyme that catalyzes the transformation of arachidonic acid into several bioactive substances, known as prostaglandins. [16, 17]. Increased expression of COX-2 has been associated with neurotoxicity in acute insults to the nervous system, such as hypoxia, ischemia and seizures [16]. However, strong evidence suggests that COX-2 also exerts essential physiological neuronal functions, being constitutively expressed in some organs such as kidneys, testicles and brain.
In rat brains, physiological expression of COX-2 occurs in neuronal cells; in contrast, in the inflammatory response, COX-2 expression occurs mainly in astrocytes and microglia [17]. It is possible that COX-2 expression in the hippocampus plays an important role in acquisition and processing of spatial memory [18].
Qualitative evaluation demonstrated a large percentage of labeled cells in the THOT group compared to the other groups, both in the corpus callosum and in the germinal matrix. We can infer from these results that the inflammatory response in these regions was greater in this group.
In the cerebral cortex, the THOT group showed great variation in the percentage of COX-2 immunoexpression, demonstrating a high percentage of labeled cells in the CTX_F, but a low percentage in the CTX_D.
In the analysis of the hippocampal subareas, the THOT group showed a much lower percentage of labeled cells in CA3 and dentate gyrus. The lower percentage of marked cells in the THOT group may justify the worse performance of these animals in Morris water maze test.
In the other regions, the percentage of cells with immunostaining for COX-2 was very similar, which may reflect a lower degree of damage in these areas of the hippocampus.
To evaluate the effects of hydrocephalus on the neuronal cell population, Neu-N immunostaining was used. Evaluation of the cerebral cortex showed a greater number of neuronal cells in the THOT group in relation to the other groups, both in CTX_F and in CTX_D. However, when analyzing the percentages of labeled cells, the differences were less evident. The increase in the population of neuronal cells may reflect an attempt to increase cell proliferation in response to the insults caused by both hydrocephalus and the established treatments.
In the hippocampal subareas, the density of neuronal cells was also higher in the THOT group. Despite the apparent lesser severity of the injury caused by hydrocephalus in the hippocampal region, the same mechanisms that justify the greater cell density in the THOT group can be applied to this region.