We refer to the case of a five year old girl who has a known medical history of premature thelarche (mentioned at age of 18 months). LHRH diagnostic test revealed a pre-pubertal type of response, excluding the diagnosis of premature puberty. Radiographic evaluation of bone maturity revealed a slight discrepancy between the skeletal and chronological age, in favor of the skeletal age. The patient was under endocrinological evaluation and she underwent an MRI of the region of the hypophysis-hypothalamus for further diagnostic investigation. No symptoms of encephalopathy / viral meningitis / encephalitis at the time of the initial MRI were clinically detected and the imaging was executed on an outpatient basis.
The anterior gland of the hypophysis did not reveal any pathologic changes regarding its configuration and shape, whereas the posterior gland was of normal size, with bright spots recognized within its substance. After the administration of paramagnetic substance, no pathologic uptake was detected from the parenchyma of the gland.
Another finding that was identified during the examination was a focal lesion with pathologic signal characteristics, detected in the white matter of the right cerebellar hemisphere, its maximum diameter measuring 23 mm. It was characterized by the presence of a lobular margin and the presence of moderate midline shift. After contrast administration, there was no contrast uptake· due to these atypical features, MRS was recommended (Figures 1.A, 1.B, 1.C). Neither relevant medical, family, and psychosocial history including relevant genetic information were obtained, no past interventions. The relevant physical examination did not reveal anything and other significant clinical findings were not observed.
MRS revealed that in the substance of the space-occupying lesion there was increased concentration of choline and a moderate decrease in the concentration of NAA. The fractions of the measured metabolites were abnormal (NAA/Cr = 0,89, Cho/Cr = 1,41 and Cho/NAA = 1,58) (Figure 2). The aforementioned measurements were compatible with a low grade lesion, such as a grade I astrocytoma. The imaging evaluation was supplemented to include the entire neuraxis, but no pathologic contrast uptake across its entire length was detected. Futhermore, no pathologic signal intensity was recognized during the evaluation of the entirety of the spinal cord.
A few days after performance of the imaging testing, the patient underwent a right suboccipital craniotomy in order to access and remove the hemispheric lesion. Intraoperatively, no clearly defined space occupying lesion involving the cerebellar hemisphere was identified. There was a discrepancy between the preoperative imaging characteristics and the macroscopic intraoperative findings, so multiple specimens were send for histopathologic analysis.
The immune-histochemical analysis revealed that there was GFAP expression to the existing astrocytes, diffuse synaptophysin expression, neurofilaments 2F11 and NeuN to the existing neurons· no significant expression of the mitotic labeling index Ki- 67/MIB-1 was detected, in any particular cell population. The specimens included cerebellar tissue elements without remarkable gliosis, with heterogeneous vascular congestion and focuses with moderate to severe hemorrhagic deposition and regional necrosis, without other pathognomonic findings.
No inclusions of viral origin into neural cells were recognized. Regions of mild to moderate chronic infection were elicited, without specific characteristics resembling granulomatous infection. The aforementioned findings are not conclusive of a specific histopathologic entity· the possibility that these findings are compatible with being part of a nearby major lesion which is not represented to the excised and examined specimen material, cannot be excluded.
After the operation and while the patient was in the ICU, we executed a CT scan before extubation which revealed the presence of a well circumscribed region in the territory of the right cerebellar hemisphere behind the anatomic position of the fourth ventricle (Figure 3). This finding was thought to represent a remaining tumor remnant.
Facing this diagnostic dilemma, we decided to perform a second-look operation, in order to re-evaluate the surgical bed and the nearby field but the histopathological diagnosis remained unchanged.
Besides that, while the patient was treated in the ICU after the second operation, after the discontinuation of sedation, the patient exhibited intention tremor, slowness in the execution of voluntary movements, inability to speak and occasionally involuntary downward gas movement. Due to episode of gas attachment accompanied by hypertonia and tremor of the extremities, the patient started phenytoin as antiepileptic medication.
After the patient was transferred back to the ward, a new episode of generalized tonic-clonic seizures was reported and oxcarbazepine was added to its medication scheme. EEG was performed, without sleep deprivation, which revealed the presence of δ waves (2-3c/sec), of intermediate to high amplitude, as well as, less frequently, the presence of θ waves (4-5c/s). The EEG diagram seems to be completely disorganized, finding that could be attributed to viral encephalitis. Besides that, the patient became febrile ( ̴ 38,5°C) and there were episodes of salivation and horizontal nystagmoid eye movements. The patient was lethargic, not communicating well, with slurred speech, poor eye contact, was exhibiting decreased psychomotor activity and word comprehension difficulties.
The usual work up for evaluation (culture of blood, CSF and urine samples, x-ray of the chest) of the etiology of fever was negative and the diagnostic possibility of herpes encephalitis was enhanced.
Based on that data, we considered the possibility that we were treating a case of «pseudotumor», that is a lesion masquerading as tumor. We continued our diagnostic work up with the examination of blood samples for RNA of Poliovirus, Coxsackieviruses A and B, Echovirus and Enterovirus. The method was One Step Real Time qRT-PCR (TaqMan) (Gene 5’ UTR, Human RNase P) · the end result was negative.
We also examined CSF samples in order to detect DNA of HSV 1 and 2 (method Real Time PCR (FRET). The genes to be detected were encoding UL28 (ICP18.5) and Glycoprotein B (UL27). The first PCR assay for HSV DNA was negative, but it is well established that if the sample is taken on the first or second day of illness, it could be negative and may become positive on testing of a subsequent CSF specimen [5]. Our strategy was to repeat the examination a few days later· the result was negative for HSV2 but it was positive for HSV1. Similar tests were obtained for the detection of RNA of Influenza viruses A and B and HCMV from CSF samples but the results were negative. Besides, basic CSF testing from both specimens (leukocyte count and protein) were supportive of our diagnosis, since the clinical diagnosis of HSV is essentially non-existent without elevations in these values. More specifically, leukocyte count was 120cells / μL, with mononuclear cell pleocytosis, and protein concentration 96mg/dl (glucose level was 60mg/dl). Blood sample tests did not reveal any leukocytosis (white cell count was 6.300/ μL), or electrolyte imbalance. Erythrocyte sedimentation rate was 62mm/hour, and CRP was 7.5 mg/dL. Urine toxicology screening was negative.
After PCR confirmation of HSV I in CSF, we attended to verify our diagnosis via further evaluation of the received brain biopsy specimens. Before PCR, diagnosis of HSV via brain biopsy was the only method to diagnose HSV. To the best of our knowledge, it remains one of the most specific tests for diagnosis of HSV infection. Individuals may have HSV nucleic acid in their CSF without severe symptoms (i.e., Mollaret's meningitis). In our experience, HSV nucleic acid is necessary, but not sufficient to diagnose HSV encephalitis. Histopathologic analysis was supplemented by viral stain. The demonstration of the presence of HSV antigen by DFA staining (immunofluorescence) of tissue sample, examined using a fluorescence microscope, verified our diagnosis.
As the diagnosis of herpes encephalitis was established, the patient received treatment with acyclovir (60mg/kg, 350 mgx4). The treatment regimen was scheduled to be given for a period of three weeks and to be discontinued if PCR of CSF was negative for HSV1. Actually, this was the case for our patient.
Six months after the operation, a repeat MRI was performed in order to evaluate the progression of the disease. The patient was under medication with oxcarbazepine· the initial daily dose 600 mg/day, given twice a day and the target maintenance dose, which was achieved over two weeks, was 31mg/kg, approximately 900 mg/day. Her cognitive and neurological condition remained unchanged. The repeat MRI revealed that gliotic tissue has appeared in the surgical resection cavity with concordant enlargement of the gyral sulci of the relevant cerebellar hemisphere. The pathologic area located in the region of the resection cavity retains similar imaging characteristics with that identified in the previous imaging that is high signal intensity on T2W and FLAIR sequences, with mild restriction of its dimensions. It also delineated the existence of a limited area with high signal intensity in the region of the right cerebellar peduncle, without enhancement after contrast administration. There is an extensive area of gliosis located to the cortex of the left fronto-parietal region of the cerebral hemisphere, with associated enlargement (ex vacuo) of the body, the frontal and temporal horn of the ipsilateral lateral ventricle (Figure 4.A, 4.B, 4.C) (the patient exhibits a right-sided hemiparesis, with hypertonia of her left side with increased deep tendon reflexes ipsilaterally).
The patient underwent serial repeated MRI examinations, in order to monitor the possible development of additional pathological features, but the only differentiating finding with respect to the previous images was the visualization of atrophic changes in the domain of the right cerebral peduncle, without enhancement after administration of contrast medium. The final imaging was performed 3 years after the initial radiological evaluation, which verified the aforementioned findings (Figure 5.A, 5.B, 5.C, 5.D).
EEG revealed a basic rhythm of θ waves (5-6c/sec) (discharges with rhythmic frequency) when the patient was waking, which could represent an ictal onset pattern. During all the recording period, we recognize the very frequent occurrence of paroxysmal discharges of spike-multispike wave form and of focal sharp waves that are mainly recorded from the scalp electrodes covering the fronto-temporal regions of the left cerebral hemisphere. These tend to propagate from the generating source to the relevant regions of the contralateral hemisphere and become generalized (generalized discharges). It is worthwhile to mention that spikes in the waking state (or during active sleep) provide the best localizing data.
Our basic tenet was to clarify the underlying diagnosis of our patient, given the restrictions that were imposed by the conflicting data of the imaging modalities and the histopathologic specimen analysis. We were confronted with a discrepancy between the clinical picture of our patient at presentation and her imaging characteristics from one side, and the absence of verification of our suspicion from the histopathologic analysis, from the other side.
Eventually, after our patient was operated twice, due to a suspicious finding on the immediate postoperative CT scan, the clinical evolution of the disease directed our diagnostic work-up to the exclusion or verification of encephalitis.
We need to mention that, immediately after the first operation, during our patient stay to the ICU, the imaging modality that was used to evaluate our postoperative outcome was a CT scan. As far as, based on our preoperative data and concerning that the results of the preliminary histopathologic evaluation were not diagnostic about the tissue of origin of the resected specimen, another concern was the execution of an immediate postoperative MRI. Unfortunately, our patient was hemodynamically unstable and the execution of an MRI scan was not considered to be a safe choice. We needed an examination to rule out any offending pathology in the territory of the surgical wound, which would be able to exclude any surgical complication (edema-hematoma-infarction). As soon as CT scan ruled out any major surgical complications but raised suspicion about the completeness of the resection, we had to decide either to perform an MRI as soon as possible, or to re-operate our patient (second look operation). We decided to re-operate, based on the concept that the histopathology specimen did not seem to be diagnostic and on the possibility that a new MRI could yield insufficient information, unable to help us resolve our diagnostic dilemma.
Six months after the operation, a repeat MRI was performed in order to evaluate the progression of the disease. The patient was under medication with oxcarbazepine· the initial daily dose 600 mg/day, given twice a day and the target maintenance dose, which was achieved over two weeks, was 31mg/kg, approximately 900 mg/day. Her cognitive and neurological condition remained unchanged. The repeat MRI revealed that gliotic tissue has appeared in the surgical resection cavity with concordant enlargement of the gyral sulci of the relevant cerebellar hemisphere. The pathologic area located in the region of the resection cavity retains similar imaging characteristics with that identified in the previous imaging that is high signal intensity on T2W and FLAIR sequences, with mild restriction of its dimensions. It also delineated the existence of a limited area with high signal intensity in the region of the right cerebellar peduncle, without enhancement after contrast administration. There is an extensive area of gliosis located to the cortex of the left fronto-parietal region of the cerebral hemisphere, with associated enlargement (ex vacuo) of the body, the frontal and temporal horn of the ipsilateral lateral ventricle (Figure 4A-C) (the patient exhibits a right-sided hemiparesis, with hypertonia of her left side with increased deep tendon reflexes ipsilaterally).
The patient underwent serial repeated MRI examinations, in order to monitor the possible development of additional pathological features, but the only differentiating finding with respect to the previous images was the visualization of atrophic changes in the domain of the right cerebral peduncle, without enhancement after administration of contrast medium. The final imaging was performed 3 years after the initial radiological evaluation, which verified the aforementioned findings (Figure 5A-D).
EEG revealed a basic rhythm of θ waves (5-6c/sec) (discharges with rhythmic frequency) when the patient was waking, which could represent an ictal onset pattern. During all the recording period, we recognize the very frequent occurrence of paroxysmal discharges of spike-multispike wave form and of focal sharp waves that are mainly recorded from the scalp electrodes covering the fronto-temporal regions of the left cerebral hemisphere. These tend to propagate from the generating source to the relevant regions of the contralateral hemisphere and become generalized (generalized discharges). It is worthwhile to mention that spikes in the waking state (or during active sleep) provide the best localizing data.