Essentials of gliomas

Dr. Parag Moon
Senior resident,
Dept. of Neurology
GMC, Kota

 CNS tumors can primarily be divided into
 Primary -originates in the brain (solitary, nodular)
 Secondary-made up of cells that have spread (metastasized)
to the brain from somewhere else in the body.
 Multiple in number, prior h/o cancer , edema +, located at
gray white interface.
 May lodge into
- Brain parenchyma – most common area of metastases
- Leptomeninges – pia mater & arachnoid mater
- Dural space

 Tumors of Neuroepithelial Tissue
 Tumors of Cranial and Spinal Nerves
 Tumors of Meninges
 Lymphomas and Hematopoietic
Neoplasm
 Germ Cell Tumor
 Tumors of Sellar Regions (pituitary
/craniopharyngioma)
 Metastatic Tumors

 Many grading systems (e.g., Kernohan, St.
Anne-Mayo, and Ringertz systems)
 Most of these grading systems share an
assessment of nuclear abnormalities,
mitoses, endothelial proliferation, and
necrosis

 WHO grade I – low proliferative potential.
Possible cure with surgery alone
 WHO grade II – infiltrating, but low in mitotic
activity. Can recur and progress to other
grades
 WHO grade III – Histologic evidence of
malignancy (mitotic activity), infiltrative,
anaplastic
 WHO grade IV – mitotically active, necrosis,
rapid pre and post-surgical progression

Cell of origin can be
1. Astrocytes
2. Oligodendrocytes
3. Ependymal cells
4. Mixed
 Identified by glial fibrillary acidic protein
(GFAP) and S100

 Gliomas-Most common (80%) primary
malignant brain tumours.
 Gliobastoma accounts for 54%.
 Most common is astrocytoma (including
gliobastoma)-76%.
 Slight male preponderance.
 More common in whites.

 Exposure to ionizing radiations is the only
definite risk factor
 They are common in;
 NF type I (15 – 20% develop LGGs)
 NF type II
 Tuberous sclerosis
 Li-Fraumeni syndrome
 Environmental exposure to Nitrites/Nitrates
(nitrosamines/amides)
 Radiofrequency radiation.
 Electromagnetic field radiation(EMF)

 Allergies/IgE levels association
 Vit. E and C consumption.
 Head trauma
 Tobacco, alcohol consumption
 p53 gene mutation (a consistent finding)
 1p/19q mutations in tumours transforming
to high grade

 Well circumscribed both grossly and
radiologically.
 More common in cerebellum, third ventricle,
hypothalamus, optic nerve, spinal cord,
dorsal brainstem.
 Cerebellar-large fluid filled cyst with
enhancing nodule.
 Hyothalamus, optic nerve- solid tumours.
 Outcome excellent (80% 20-year survival)

 Biphasic pattern- compact pilocytic areas
with interspersed microcytic, loose and
spongy areas.
 Rosenthal fibres
 Mulberry shaped eosinophilic granular
inclusion
 Pilomyxoid astrocytoma-variant, more
aggressive, affects children younger than 3
years

Fig 2.4B: Axial T1 Wtd. MRIFig 2.4A: Axial T2 Wtd. MRI Fig 2.4C: Post-Contrast Axial T1 Wtd. MRI
A large cystic tumor (yellow arrow) with a mural enhancing nodule (red arrow) is seen within the left cerebellar
hemisphere.
DIAGNOSIS: PILOCYTIC ASTROCYTOMA
• Grade I Astrocytoma (WHO Classification)
• Children and young adults
• Imaging Features: cyst within enhancing tumor nodule.

 Well differentiated, low grade, simply
astrocytoma.
 Median age at diagnosis-35 years.
 Brainstem gliomas-childhood
 Ill defined non enhancing cerebral masses.
 Grossly poorly circumscribed.
 Lacks mitotic activity, microvascular
proliferation and necrosis
 Low MIB(Ki-67) proliferative index.

 90%-mutation in IDH1 and IDH2 encoding for
isocitrate dehydrogenase in citric acid cycle.
 IDH1 mutation-prognostic significance
 50%- loss of 17p and mutation in TP53.

Axial T1 Wtd. MRIAxial Flair MRI Post-Contrast Axial T1 Wtd. MRI
Non-enhancing tumor (arrow) involving the right temporal lobe.
GRADE II ASTROCYTOMA (LOW GRADE)
• Children and young adults
• Imaging Features: Non-enhancing tumors. Calcification can be seen.

 Mean age- fouth or fifth decade
 Some contrast enhancement on MRI.
 More cellular than grade II
 Presence of mitotic figures.
 High Ki67/MIB index
 High incidence of progression to GBM
 High frequency of TP53, IDH1, IDH2, RB, PTEN
 EFGR mutation-worse prognosis.
 Relative survival at 2 years-40% and at 5 years-
27%

Fig 2.2B: Axial T1 Wtd. MRIFig 2.2A: Axial Flair MRI Fig 2.2C: Post-Contrast Axial T1 Wtd. MRI Fig 2.2D: Post Contrast Coronal T1 Wtd. MRI
An ill-defined non-enhancing tumor (yellow arrows) is seen in the left parietal lobe with spotty areas of
enhancement (red arrows).
DIAGNOSIS: Anaplastic Astrocytoma
• Grade III Astrocytoma (WHO Classification)
• Usually seen between 40 – 60 years of age
• Imaging Features: Ill-defined non-enhancing tumor with or without
feeble enhancement.

 Previously known as glioblastoma multiforme
 Peak age of onset is 50-60yrs.
 Common in deep white matter, basal ganglia,
thalamus, rarely in cerebellum
 Grossly may appear circumscribed
 Microscopic infiltrates widely, often to other
hemisphere via corpus callosum.
 Multifocal
 Extracranial metastasis rare.
 Survival 1-1.5 yrs after treatment.

 Central yellow or white zone of necrosis and
hemorrhage surrounded by hyperemic ring of
endothelial hyperplasia.
 Surrounded by edematous brain (mixture of
vasogenic edema, tumour infiltrates and
gliosis)
 TP53, IDH1 and IDH2 mutation less common
in primary.
 30-40% have EFGR mutation
 MGMT mutation- favorable prognosis.

 Primary GBM
◦ Develops de novo from
glial cells
◦ Accounts for > 90% of
biopsied or resected cases
◦ Clinical history of 6 months
◦ Occurs in older patients
(median age: 60 years)
◦ EFGR mutation
 Secondary GBM
◦ Develops from low-grade or
anaplastic astrocytoma
 ~ 70% of lower grade
gliomas develop into
advanced disease within
5-10 years of diagnosis
◦ Comprises < 5% of GBM
cases
◦ Occurs in younger patients
(median age: 45 years)
◦ TP53, IDH1, IDH2

Fig 2.1B: Axial T1 Weighted
(Wtd.) MRI
Fig 2.1A: Axial Flair MRI Fig 2.1C: Post-Contrast Axial T1
Wtd. MRIAn irregular enhancing ring lesion (arrow) is seen involving the left parietal lobe. Tumor is associated with
edema (E) best noticed on FLAIR image (A).
DIAGNOSIS: GLIOBLASTOMA
E
• Grade IV Astrocytoma (WHO Classification)
• Older Patient
•Imaging Features: Tumor with irregular peripheral enhancement with
central necrosis.

 Average age of diagnosis-26 yrs.
 Involve cerebral cortex and overlying
meninges most common in temporal lobe.
 Bizzare giant cells
 Xanthomatous cells-foamy lipid filled
astrocytes seen in 1/4th cases.
 15-20% have malignant transformation.
 Survival 81% at 5 yrs and 70% at 10 yrs.

large well defined cystic mass in right temporo-parieto-occipital
region with mild vasogenic oedema and mass effects. Post-contrast rim
like enhancement of the cystic mass, with enhancing mural nodule

 Associated with tuberous sclerosis
 Gross- elongated, sausage like or lobulated
 Candle guttering-identical smaller masses on
walls of ventricle.
 Rich vascularity
 Pseudo-rosettes
 Hydrocephalus
 TSC1 and TSC2
 Inhibitors of mTOR found effective.

Hypo- to isointense to gray matter on T1, heterogeneously hyperintense
on FLAIR , T2 punctate hypointensities corresponding to calcium with
avid contrast enhancement.

 Seen in young to middle aged adults.
 Most common in frontal lobe
 Histopath- uniform round nuclei, bland
chromatin, perinuclear halo-Fried egg
 Rich branching capillary network-Chicken
wire
 50-80%-loss of 1p and 19q
 Favorable response to chemotherapy
 IDH1 and IDH2 mutation in grade II (84%) and
grade III (94%).

Hypointense on T1 hyperintense on T2 with no contrast enhancement
mass in rt. Frontal lobe.

 Most difficult to define
 Survival between astrocytoma and
oligodendroglioma.
 Usually grade and treated as
oligodendroglioma.

 Most common in first decade.
 Age<3 years have worse prognosis
 Children-infratentorial
 Adult-spinal
 Well circumscribed mass that compresses and
not infiltrates surrounding parenchyma
 May seed subarachnoid space in 5%
 Perivascular rosettes
 22q deletion in NF2 mutation-spinal
ependymoma.

 Seen in filum terminale
 More common in adults
 Thin collagenous capsule
 Prognosis excellent if capsule intact
 May metastasize to lungs

Hypointense mass on T1 and hyperintense with some hypointense signal
within due to hemorrhage within on T2

 Seen in adults
 Small and incidental
 Glistening pearly white lobulated
intraventricular proteburance
 Most often in fourth ventricle
 May cause hydrocephalus
 Low proliferative index

 Presenting symptoms determined by
 Tumour’s size,
 Location
 Rate of growth

 Classically (17%) starts in early morning and
disappears soon after pt. gets up
 Initially mild, becomes progressively more
severe, frequent and of longer duration
 Worse with Valsalva manoeuvre
 Associated with nausea,vomiting
 Forsyth, Posner(1993) showed tension-type
headache(77%), migraine-like headache
(9%),14% had mixture of headaches could not
be easily classified

 Forsyth (1993)- commonest headache site
was frontal region (68%) seen primarily in
supratentorial tumours or with raised ICT.
 73% of patients with infratentorial tumours
had frontal, temporal or parietal headaches
and 24% had nuchal and occipital.
 Related to size of tumour and amount of
midline shift.
 Produced due to traction on pain-sensitive
structures such as blood vessels, dura or
obstruction of CSF pathways

Recommendation Level
A patient with new onset or recurrent headache
uncharacteristic for that patient should also be
imaged, particularly if there are focal neurological
symptoms and signs.
III

Other symptoms
 Limb weakness
 Language disturbances
 Apraxia, agnosia
 Amnesia
 Depression
 Seizures- most common partial motor often
with secondary generalization
 Plateau waves- paroxysmal neurological
symptoms on standing

◦ A discrete or diffuse hypodense to isodense mass
lesion
◦ Minimal or no enhancement (except in 15 – 30%
patients)
◦ Calcifications
(Oligodendrogliomas/Oligoastrocytomas)
◦ Cystic changes (any histologic type)

◦ Hypo- to Iso-intense on T1WI
◦ Hyperintense on T2WI
◦ Minimal- to NO gadolinium enhancement
 (25 – 50% oligodendrogliomas are somewhat enhanced)
◦ No significant mass effect
◦ Tendency to invade & reside in white matter
 Oligodendrogliomas expands along gyri
◦ Calcifications (20% lesions)

 T1-weighted MRI with contrast may
underestimate the extent of an LGG
 The true extent is shown on the T2-
weighted sequences,
 Diffusion tensor MRI used as a marker of
glioma infiltration

 Reduced NAA peaks
 Increased choline peak
 Increased choline/creatinine ratio
 Choline/creatinine peak>3:1 predicts high
grade tumour.

Malignant Transformation:
LGG transformation ranges from 17% to 73% in
clinical studies
Risk of progression increases with tumour
burden
Growth rate of ≥ 8 mm per year  Median
survival of 5.16 years
Growth rate ≤ 8 mm/year  median survival of
≥ 15 years
Residual tumour after surgery is an important
determinant

Observation:
 Advantages:
 No surgical morbidity
 Lesser cost of follow up treatment
 Disadvantages:
 Loss of histological diagnosis
 Loss to follow up (quite frequent than reported)
 Risk of increased malignant transformation
 Risk of increasing tumour burden/neurodeficits

 Supportive treatment
 Antiepileptics- leviteracetam preferred.
Prophylactic antiepileptics not recommended.
 Enzyme inducers avoided.
 Steroids- Dexamethasone most commonly
used.
 Usual dose 8-16mg daily dose.

Surgical intervention:
 Open resection
 Open/stereotactic biopsy
 Guided by patient’s clinical status, location of tumour &
surgeon’s preference
 Goals of surgery:
 Establishing a diagnosis
 Symptoms alleviation
 Decompression
 Tumour cytoreduction

Biopsy:
 Open/Image guided or stereotactic (if available)
 Indicated in high risk patients or when open surgery is
declined/deferred
 Advantages:
 Minimally invasive
 Early identification of histologic type
 Disadvantages:
 Morbidity/mortality with open biopsy
 Image guided biopsy may sample wrong site
 Stereotactic biopsy may be too small for a diagnosis

Surgical Resection:
 It is the principle mode of treatment in the following;
 Whenever possible
 Mass effect
 Raised ICT
 Steroid resistant edema
 Threat of herniation
 CSF flow obstruction
 Seizure control
 Smaller tumours are less aggressive & better surgical
candidates

Surgery has limited role in following;
 Disseminated tumours
 Multifocal tumours
 Eloquent location
Extent of Resection:
◦ Recent evidence favouring early extensive resection
◦ Good life expectancy
◦ Influencing malignant transformation
◦ Progression free survival & overall survival both
improves

 Radiation for Pilocytic astrocytoma after surgery may be
reserved until recurrence or deep lesions
 Fractionated radiation of up to 45-60 Gy (more
focussed, more good)
 Hyperfraction protocol
 Provided to T2 abnormality and margin of 1.5 to 2 cm
 In sharply demarcated tumour 0.5cm margin suffice
 Adjvunt to surgery
 Malignant transformation may be treated with radiation
 Steriotactic radiosurgery-useful in well circumscribed
tumour.
 Brachytherapy

Chemotherapy:
 PCV (Procarbazine, Lomustine, Vincristine) may have a
role in stabilising tumour growth
 Temozolomide may have a role for progressive
astrocytoma
 Oligodendroglioma- chemosensitive
 Recurrence of anaplastic astrocytoma and glioblastoma
multiforme

 Methylating agent
 Principal mechanism is causing damage to DNA
of tumour cell, leading to cell death
 Taken orally, rapidly absorbed
 Penetrates the blood-brain barrier
 TMZ 75 mg/m2 PO QD for 6 weeks, then 150-
200 mg/m2 PO QD on Days 1-5 every 28 days
for 6 cycles
 Used with radiotherapy

 No consensus
 Low dose temozolomide (+/- procarbazine)
 Carboplatin
 BCNU/CCNU
 Bevacizumab (+/- Irinotecan)
 EFGR inhibitors (geftinib)
 PDGFR inhibitors (imatinib)
 Clinical trials if possible

 BCNU(carmustine)-
infused wafers
 Implanted to tumour
bed at time of surgery
 Chemotherapy
released to
surrounding brain
tissue over a period of
2 to 3 weeks
 Clinical trials showed
survival benefit

 Prognosis
◦ Extremely young patients<3yrs or patients > 50 y
◦ Large tumours that enhance
◦ Short clinical history
◦ Absent of mental changes
◦ Cerebellar location
◦ High grade
◦ Completeness of surgical lesion
◦ Evidence of progression on imaging studies

 Clinical course is by no means benign as is manifested
by histology & radiologic appearance
 Aggressive early resection advised but NOT on the
expense of patient’s quality of life
 Diagnosis purely on the basis of radiology has a failure
rate of up to 50%
 Early histologic evidence of the diagnosis is paramount
both for the surgeon & the patient
 Chemo-radiotherapy can be delayed until recurrence
or progression in low grade gliomas.

 Clinical practice guidelines for management
of gliomas: Clinical oncological society of
Australia; Aug2009.
 Malignant Gliomas in Adults;Patrick Y. Wen,
Santosh Kesari:N Engl J Med 2008; 359:492-
507
 Guidelines on management of low-grade
gliomas: report of an EFNS–EANO* Task
Force; European Journal of Neurology 2010,
17: 1124–1133

 High Grade Gliomas: Pathogenesis,
Management And Prognosis;ACNR :VOLUME
12 NUMBER 4 ;SEPTEMBER/OCTOBER 2012
 Practical Guidelines for the Treatment of
Malignant Gliomas;Marc C., Patty A., WJM,
February 1998-Vol 168, No. 2

Essentials of gliomas

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