Glioblastoma

Glioblastoma, previously known as glioblastoma multiforme (GBM), is one of the most aggressive types of cancer that begin within the brain. Initially, signs and symptoms of glioblastoma are nonspecific. They may include headaches, personality changes, nausea, and symptoms similar to those of a stroke. Symptoms often worsen rapidly and may progress to unconsciousness.

The cause of most cases of glioblastoma is not known. Uncommon risk factors include genetic disorders, such as neurofibromatosis and Li–Fraumeni syndrome, and previous radiation therapy. Glioblastomas represent 15% of all brain tumors. They can either start from normal brain cells or develop from an existing low-grade astrocytoma. The diagnosis typically is made by a combination of a CT scan, MRI scan, and tissue biopsy.

There is no known method of preventing the cancer. Treatment usually involves surgery, after which chemotherapy and radiation therapy are used. The medication temozolomide is frequently used as part of chemotherapy. High-dose steroids may be used to help reduce swelling and decrease symptoms. Surgical removal (decompression) of the tumor is linked to increased survival, but only by some months.

Despite maximum treatment, the cancer almost always recurs. The typical duration of survival following diagnosis is 10–13 months, with fewer than 5–10% of people surviving longer than five years. Without treatment, survival is typically three months. It is the most common cancer that begins within the brain and the second-most common brain tumor, after meningioma. About 3 in 100,000 people develop the disease per year. The average age at diagnosis is 64, and the disease occurs more commonly in males than females.

Signs and symptoms

Common symptoms include seizures, headaches, nausea and vomiting, memory loss, changes to personality, mood or concentration, and localized neurological problems. The kind of symptoms produced depends more on the location of the tumor than on its pathological properties. The tumor can start producing symptoms quickly, but occasionally is an asymptomatic condition until it reaches an enormous size.

Risk factors

The cause of most cases is unclear. About 5% develop from certain hereditary syndromes.

Genetics

Uncommon risk factors include genetic disorders such as neurofibromatosis, Li–Fraumeni syndrome, tuberous sclerosis, or Turcot syndrome. Previous radiation therapy is also a risk. For unknown reasons, it occurs more commonly in males.

Environmental

Other associations include exposure to smoking, pesticides, and working in petroleum refining or rubber manufacturing.

Glioblastoma has been associated with the viruses SV40, HHV-6, and cytomegalovirus.

Other

Research has been done to see if consumption of cured meat is a risk factor. No risk had been confirmed as of 2013. Similarly, exposure to radiation during medical imaging, formaldehyde, and residential electromagnetic fields, such as from cell phones and electrical wiring within homes, have been studied as risk factors. As of 2015, they had not been shown to cause GBM.

Pathogenesis

The cellular origin of glioblastoma is unknown. Because of the similarities in immunostaining of glial cells and glioblastoma, gliomas such as glioblastoma have long been assumed to originate from glial-type cells. More recent studies suggest that astrocytes, oligodendrocyte progenitor cells, and neural stem cells could all serve as the cell of origin.

Glioblastomas are characterized by the presence of small areas of necrotizing tissue that are surrounded by anaplastic cells. This characteristic, as well as the presence of hyperplastic blood vessels, differentiates the tumor from grade 3 astrocytomas, which do not have these features.

GBMs usually form in the cerebral white matter, grow quickly, and can become very large before producing symptoms. Fewer than 10% form more slowly following degeneration of low-grade astrocytoma or anaplastic astrocytoma. These are called secondary GBMs and are more common in younger patients (mean age 45 versus 62 years). The tumor may extend into the meninges or ventricular wall, leading to high protein content in the cerebrospinal fluid (CSF) (> 100 mg/dl), as well as an occasional pleocytosis of 10 to 100 cells, mostly lymphocytes. Malignant cells carried in the CSF may spread (rarely) to the spinal cord or cause meningeal gliomatosis. However, metastasis of GBM beyond the central nervous system is extremely unusual. About 50% of GBMs occupy more than one lobe of a hemisphere or are bilateral. Tumors of this type usually arise from the cerebrum and may exhibit the classic infiltration across the corpus callosum, producing a butterfly (bilateral) glioma.

Glioblastoma classification

Brain tumor classification has been traditionally based on histopathology at macroscopic level, measured in hematoxylin-eosin sections. The World Health Organization published the first standard classification in 1979 and has been doing so since. The 2007 WHO Classification of Tumors of the Central Nervous System was the last classification mainly based on microscopy features. The new 2016 WHO Classification of Tumors of the Central Nervous System was a paradigm shift: some of the tumors were defined also by their genetic composition as well as their cell morphology.

The grading of gliomas changed importantly and glioblastoma was now mainly classified according to the status of isocitrate dehydrogenase (IDH) mutation: IDH-wildtype or IDH-mutant.

In 2021, the fifth edition of the WHO Classification of Tumors of the Central Nervous System was released. This update eliminated the classification of secondary glioblastoma and reclassified those tumors as Astrocytoma, IDH mutant, grade 4. Only tumors that are IDH wild type are now classified as glioblastoma

Molecular alterations

Four subtypes of glioblastoma have been identified based on gene expression:
* Classical: Around 97% of tumors in this subtype carry extra copies of the epidermal growth factor receptor (''EGFR'') gene, and most have higher than normal expression of ''EGFR'', whereas the gene'' TP53'' (p53), which is often mutated in glioblastoma, is rarely mutated in this subtype. Loss of heterozygosity in chromosome 10 is also frequently seen in the classical subtype alongside chromosome 7 amplification.
* The proneural subtype often has high rates of alterations in ''TP53'' (p53), and in ''PDGFRA'', the gene encoding a-type platelet-derived growth factor receptor, and in '' IDH1'', the gene encoding isocitrate dehydrogenase-1.
* The mesenchymal subtype is characterized by high rates of mutations or other alterations in ''NF1'', the gene encoding neurofibromin 1 and fewer alterations in the ''EGFR'' gene and less expression of ''EGFR'' than other types.
* The neural subtype was typified by the expression of neuron markers such as NEFL, GABRA1, SYT1, and SLC12A5, while often presenting themselves as normal cells upon pathological assessment.

Many other genetic alterations have been described in glioblastoma, and the majority of them are clustered in two pathways, the RB and the PI3K/AKT. Glioblastomas have alterations in 68–78% and 88% of these pathways, respectively.

Another important alteration is methylation of MGMT, a "suicide" DNA repair enzyme. Methylation impairs DNA transcription and expression of the MGMT gene. Since the MGMT enzyme can repair only one DNA alkylation due to its suicide repair mechanism, reserve capacity is low and methylation of the MGMT gene promoter greatly affects DNA-repair capacity. MGMT methylation is associated with an improved response to treatment with DNA-damaging chemotherapeutics, such as temozolomide.

Cancer stem cells

Glioblastoma cells with properties similar to progenitor cells (glioblastoma cancer stem cells) have been found in glioblastomas. Their presence, coupled with the glioblastoma's diffuse nature results in difficulty in removing them completely by surgery, and is therefore believed to be the possible cause behind resistance to conventional treatments, and the high recurrence rate. Glioblastoma cancer stem cells share some resemblance with neural progenitor cells, both expressing the surface receptor CD133. CD44 can also be used as a cancer stem cell marker in a subset of glioblastoma tumour cells. Glioblastoma cancer stem cells appear to exhibit enhanced resistance to radiotherapy and chemotherapy mediated, at least in part, by up-regulation of the DNA damage response.

Metabolism

The ''IDH1'' gene encodes for the enzyme isocitrate dehydrogenase 1 and is uncommonly mutated in glioblastoma (primary GBM: 5%, secondary GBM >80%). By producing very high concentrations of the oncometabolite D-2-hydroxyglutarate and dysregulating the function of the wild-type IDH1 enzyme, it induces profound changes to the metabolism of ''IDH1''-mutated glioblastoma, compared with ''IDH1'' wild-type glioblastoma or healthy astrocytes. Among others, it increases the glioblastoma cells' dependence on glutamine or glutamate as an energy source. ''IDH1''-mutated glioblastomas are thought to have a very high demand for glutamate and use this amino acid and neurotransmitter as a chemotactic signal. Since healthy astrocytes excrete glutamate, ''IDH1''-mutated glioblastoma cells do not favor dense tumor structures, but instead migrate, invade, and disperse into healthy parts of the brain where glutamate concentrations are higher. This may explain the invasive behavior of these ''IDH1''-mutated glioblastoma.

Ion channels

Furthermore, GBM exhibits numerous alterations in genes that encode for ion channels, including upregulation of gBK potassium channels and ClC-3 chloride channels. By upregulating these ion channels, glioblastoma tumor cells are hypothesized to facilitate increased ion movement over the cell membrane, thereby increasing H₂O movement through osmosis, which aids glioblastoma cells in changing cellular volume very rapidly. This is helpful in their extremely aggressive invasive behavior because quick adaptations in cellular volume can facilitate movement through the sinuous extracellular matrix of the brain.

MicroRNA

As of 2012, RNA interference, usually microRNA, was under investigation in tissue culture, pathology specimens, and preclinical animal models of glioblastoma. Additionally, experimental observations suggest that microRNA-451 is a key regulator of LKB1/ AMPK signaling in cultured glioma cells and that miRNA clustering controls epigenetic pathways in the disease.

Tumor vasculature

GBM is characterized by abnormal vessels that present disrupted morphology and functionality. The high permeability and poor perfusion of the vasculature result in a disorganized blood flow within the tumor and can lead to increased hypoxia, which in turn facilitates cancer progression by promoting processes such as immunosuppression.

Diagnosis

When viewed with MRI, glioblastomas often appear as ring-enhancing lesions. The appearance is not specific, however, as other lesions such as abscess, metastasis, tumefactive multiple sclerosis, and other entities may have a similar appearance. Definitive diagnosis of a suspected GBM on CT or MRI requires a stereotactic biopsy or a craniotomy with tumor resection and pathologic confirmation. Because the tumor grade is based upon the most malignant portion of the tumor, biopsy or subtotal tumor resection can result in undergrading of the lesion. Imaging of tumor blood flow using perfusion MRI and measuring tumor metabolite concentration with MR spectroscopy may add diagnostic value to standard MRI in select cases by showing increased relative cerebral blood volume and increased choline peak, respectively, but pathology remains the gold standard for diagnosis and molecular characterization.

Distinguishing primary glioblastoma from secondary glioblastoma is important. These tumors occur spontaneously (''de novo'') or have progressed from a lower-grade glioma, respectively. Primary glioblastomas have a worse prognosis and different tumor biology, and may have a different response to therapy, which makes this a critical evaluation to determine patient prognosis and therapy. Over 80% of secondary glioblastomas carry a mutation in ''IDH1'', whereas this mutation is rare in primary glioblastoma (5–10%). Thus, ''IDH1'' mutations are a useful tool to distinguish primary and secondary glioblastomas, since histopathologically they are very similar and the distinction without molecular biomarkers is unreliable.

File:Histopathology of glioblastoma, high magnification, annotated.jpg, Histopathology of glioblastoma, showing high grade astrocytoma features of marked nuclear pleomorphism, multiple mitoses (one at white arrow) and multinucleated cells (one at black arrow), with cells having a patternless arrangement in a pink fibrillary background on H&E stain.
File:Glioblastoma (1).jpg, Lower magnification histopathology, showing necrosis surrounded by pseudopalisades of tumor cells, conferring a diagnosis of glioblastoma rather than anaplastic astrocytoma.

Prevention

There are no known methods to prevent glioblastoma. It is the case for most gliomas, unlike for some other forms of cancer, that they happen without previous warning and there are no known ways to prevent them.

Treatment

Treating glioblastoma is difficult due to several complicating factors:
* The tumor cells are resistant to conventional therapies.
* The brain is susceptible to damage from conventional therapy.
* The brain has a limited capacity to repair itself.
* Many drugs cannot cross the blood–brain barrier to act on the tumor.

Treatment of primary brain tumors consists of palliative (symptomatic) care and therapies intended to improve survival.

Symptomatic therapy

Supportive treatment focuses on relieving symptoms and improving the patient's neurologic function. The primary supportive agents are anticonvulsants and corticosteroids.
* Historically, around 90% of patients with glioblastoma underwent anticonvulsant treatment, although only an estimated 40% of patients required this treatment. Recently, neurosurgeons have been recommended that anticonvulsants not be administered prophylactically, and should wait until a seizure occurs before prescribing this medication. Those receiving phenytoin concurrent with radiation may have serious skin reactions such as erythema multiforme and Stevens–Johnson syndrome.
* Corticosteroids, usually dexamethasone, can reduce peritumoral edema (through rearrangement of the blood–brain barrier), diminishing mass effect and lowering intracranial pressure, with a decrease in headache or drowsiness.

Surgery

Surgery is the first stage of treatment of glioblastoma. An average GBM tumor contains 10¹¹ cells, which is on average reduced to 10⁹ cells after surgery (a reduction of 99%). Benefits of surgery include resection for a pathological diagnosis, alleviation of symptoms related to mass effect, and potentially removing disease before secondary resistance to radiotherapy and chemotherapy occurs.

The greater the extent of tumor removal, the better. In retrospective analyses, removal of 98% or more of the tumor has been associated with a significantly longer healthier time than if less than 98% of the tumor is removed. The chances of near-complete initial removal of the tumor may be increased if the surgery is guided by a fluorescent dye known as 5-aminolevulinic acid. GBM cells are widely infiltrative through the brain at diagnosis, and despite a "total resection" of all obvious tumor, most people with GBM later develop recurrent tumors either near the original site or at more distant locations within the brain. Other modalities, typically radiation and chemotherapy, are used after surgery in an effort to suppress and slow recurrent disease.

Radiotherapy

Subsequent to surgery, radiotherapy becomes the mainstay of treatment for people with glioblastoma. It is typically performed along with giving temozolomide. A pivotal clinical trial carried out in the early 1970s showed that among 303 GBM patients randomized to radiation or nonradiation therapy, those who received radiation had a median survival more than double those who did not. Subsequent clinical research has attempted to build on the backbone of surgery followed by radiation. On average, radiotherapy after surgery can reduce the tumor size to 10⁷ cells. Whole-brain radiotherapy does not improve when compared to the more precise and targeted three-dimensional conformal radiotherapy. A total radiation dose of 60–65 Gy has been found to be optimal for treatment.

GBM tumors are well known to contain zones of tissue exhibiting hypoxia, which are highly resistant to radiotherapy. Various approaches to chemotherapy radiosensitizers have been pursued, with limited success . , newer research approaches included preclinical and clinical investigations into the use of an oxygen diffusion-enhancing compound such as trans sodium crocetinate as radiosensitizers, and a clinical trial was underway. Boron neutron capture therapy has been tested as an alternative treatment for glioblastoma, but is not in common use.

Chemotherapy

Most studies show no benefit from the addition of chemotherapy. However, a large clinical trial of 575 participants randomized to standard radiation versus radiation plus temozolomide chemotherapy showed that the group receiving temozolomide survived a median of 14.6 months as opposed to 12.1 months for the group receiving radiation alone. This treatment regimen is now standard for most cases of glioblastoma where the person is not enrolled in a clinical trial. Temozolomide seems to work by sensitizing the tumor cells to radiation, and appears more effective for tumors with ''MGMT'' promoter methylation. High doses of temozolomide in high-grade gliomas yield low toxicity, but the results are comparable to the standard doses. Antiangiogenic therapy with medications such as bevacizumab control symptoms, but do not appear to affect overall survival in those with glioblastoma. The overall benefit of anti-angiogenic therapies as of 2019 is unclear. In elderly people with newly diagnosed glioblastoma who are reasonably fit, concurrent and adjuvant chemoradiotherapy gives the best overall survival but is associated with a greater risk of haematological adverse events than radiotherapy alone.

Other procedures

Alternating electric field therapy is an FDA-approved therapy for newly diagnosed and recurrent glioblastoma. In 2015, initial results from a phase-III randomized clinical trial of alternating electric field therapy plus temozolomide in newly diagnosed glioblastoma reported a three-month improvement in progression-free survival, and a five-month improvement in overall survival compared to temozolomide therapy alone, representing the first large trial in a decade to show a survival improvement in this setting. Despite these results, the efficacy of this approach remains controversial among medical experts. However, increasing understanding of the mechanistic basis through which alternating electric field therapy exerts anti-cancer effects and results from ongoing phase-III clinical trials in extracranial cancers may help facilitate increased clinical acceptance to treat glioblastoma in the future.

A Tel Aviv University study showed that pharmacological and molecular inhibition of the P-selectin protein leads to reduced tumor growth and increased survival in mouse models of glioblastoma. The results of this research could open to possible therapies with drugs that inhibit this protein, such as crizanlizumab.

Prognosis

The most common length of survival following diagnosis is 10 to 13 months, with fewer than 1 to 3% of people surviving longer than five years. In the United States between 2012 and 2016 five-year survival was 6.8%. Without treatment, survival is typically 3 months. Complete cures are extremely rare, but have been reported.

Increasing age (> 60 years) carries a worse prognostic risk. Death is usually due to widespread tumor infiltration with cerebral edema and increased intracranial pressure.

A good initial Karnofsky performance score (KPS) and MGMT methylation are associated with longer survival. A DNA test can be conducted on glioblastomas to determine whether or not the promoter of the ''MGMT'' gene is methylated. Patients with a methylated MGMT promoter have longer survival than those with an unmethylated MGMT promoter, due in part to increased sensitivity to temozolomide. Another positive prognostic marker for glioblastoma patients is mutation of the ''IDH1'' gene, which can be tested by DNA-based methods or by immunohistochemistry using an antibody against the most common mutation, namely IDH1-R132H.

More prognostic power can be obtained by combining the mutational status of ''IDH1'' and the methylation status of ''MGMT'' into a two-gene predictor. Patients with both ''IDH1'' mutations and ''MGMT'' methylation have the longest survival, patients with an ''IDH1'' mutation or ''MGMT'' methylation an intermediate survival, and patients without either genetic event have the shortest survival.

Long-term benefits have also been associated with those patients who receive surgery, radiotherapy, and temozolomide chemotherapy. However, much remains unknown about why some patients survive longer with glioblastoma. Age under 50 is linked to longer survival in GBM, as is 98%+ resection and use of temozolomide chemotherapy and better KPSs. A recent study confirms that younger age is associated with a much better prognosis, with a small fraction of patients under 40 years of age achieving a population-based cure. Cure is thought to occur when a person's risk of death returns to that of the normal population, and in GBM, this is thought to occur after 10 years.

UCLA Neuro-oncology publishes real-time survival data for patients with this diagnosis.

According to a 2003 study, GBM prognosis can be divided into three subgroups dependent on KPS, the age of the patient, and treatment.

Epidemiology

About three per 100,000 people develop the disease a year, although regional frequency may be much higher. The frequency in England doubled between 1995 and 2015.

It is the second-most common central nervous system cancer after meningioma. It occurs more commonly in males than females. Although the average age at diagnosis is 64, in 2014, the broad category of brain cancers was second only to leukemia in people in the United States under 20 years of age.

History

The term glioblastoma multiforme was introduced in 1926 by Percival Bailey and Harvey Cushing, based on the idea that the tumor originates from primitive precursors of glial cells ( glioblasts), and the highly variable appearance due to the presence of necrosis, hemorrhage, and cysts (multiform).

Research

Gene therapy

Gene therapy has been explored as a method to treat glioblastoma, and while animal models and early-phase clinical trials have been successful, as of 2017, all gene-therapy drugs that had been tested in phase-III clinical trials for glioblastoma had failed. Scientists have developed the core–shell nanostructured LPLNP-PPT (long persistent luminescence nanoparticles. PPT refers to polyetherimide, PEG and trans-activator of transcription, and TRAIL is the human tumor necrosis factor-related apoptosis-induced ligand) for effective gene delivery and tracking, with positive results. This is a TRAIL ligand that has been encoded to induce apoptosis of cancer cells, more specifically glioblastomas. Although this study was still in clinical trials in 2017, it has shown diagnostic and therapeutic functionalities, and will open great interest for clinical applications in stem-cell-based therapy.

Oncolytic virotherapy

Oncolytic virotherapy is an emerging novel treatment that is under investigation both at preclinical and clinical stages. Several viruses including herpes simplex virus, adenovirus, poliovirus, and reovirus are currently being tested in phases I and II of clinical trials for glioblastoma therapy and have shown to improve overall survival.

Intranasal drug delivery

Direct nose-to-brain drug delivery is being explored as a means to achieve higher, and hopefully more effective, drug concentrations in the brain. A clinical phase-I/II study with glioblastoma patients in Brazil investigated the natural compound perillyl alcohol for intranasal delivery as an aerosol. The results were encouraging and, as of 2016, a similar trial has been initiated in the United States.

Cannabinoids

The efficacy of cannabinoids (cannabis derivatives) is known in oncology (through capsules of tetrahydrocannabinol (THC) or the synthetic analogue nabilone), on the one hand to combat nausea and vomiting induced by chemotherapy, on the other to stimulate appetite and lessen the sense of anguish or the actual pain.
Their ability to inhibit growth and angiogenesis in malignant gliomas in mouse models has been demonstrated.
The results of a pilot study on the use of THC in end-stage patients with recurrent glioblastoma appeared worthy of further study.
A potential avenue for future research rests on the discovery that cannabinoids are able to attack the neoplastic stem cells of glioblastoma in mouse models, with the result on the one hand of inducing their differentiation into more mature, possibly more "treatable" cells, and on the other hand to inhibit tumorigenesis.

See also

* Adegramotide
* List of people with brain tumors

References

External links

Information about Glioblastoma Multiforme (GBM)
from the American Brain Tumor Association

AFIP Course Syllabus
nbsp;– Astrocytoma WHO Grading Lecture Handout

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