Neurotoxicity of Cancer Therapies

NeuroWiki

Neurotoxicity of Cancer Therapies

Advances in cancer treatment have dramatically improved survival across many tumor types, but these therapies carry significant neurologic risks. Neurotoxicity is among the most common dose-limiting side effects of cancer therapy and a leading cause of treatment discontinuation and long-term disability. The landscape of treatment-related neurotoxicity has expanded beyond traditional chemotherapy to include immune checkpoint inhibitors (ICIs), chimeric antigen receptor (CAR) T-cell therapy, targeted molecular agents, and radiation. Neurologists must be prepared to recognize these complications promptly, as early intervention can prevent irreversible neurologic damage and enable continued oncologic treatment when possible. This topic provides a comprehensive, practical guide to the neurotoxicity profiles of major cancer treatment modalities.

Bottom Line

CIPN: Chemotherapy-induced peripheral neuropathy is the most common neurotoxicity of cancer treatment; duloxetine is the only agent with randomized evidence for treatment (CIPN study)
Immune checkpoint inhibitors: Can cause de novo myasthenia gravis (often fulminant with myositis overlap), encephalitis, GBS, and transverse myelitis; hold ICI and start high-dose steroids immediately
CAR-T neurotoxicity (ICANS): Immune Effector Cell-Associated Neurotoxicity Syndrome — encephalopathy, seizures, cerebral edema; graded by ICE score; treat with dexamethasone and anakinra
Methotrexate: Three temporal patterns of neurotoxicity: acute (chemical meningitis), subacute (stroke-like episodes), and chronic (leukoencephalopathy)
Radiation: Acute, early-delayed, and late-delayed toxicity; radiation necrosis vs. tumor recurrence is a critical diagnostic challenge (perfusion MRI, PET, MR spectroscopy)
PRES: Posterior reversible encephalopathy syndrome can be triggered by multiple chemotherapeutic agents; headache, seizures, visual disturbance with characteristic posterior-predominant MRI changes

Chemotherapy-Induced Peripheral Neuropathy (CIPN)

CIPN is the most prevalent neurologic complication of systemic cancer therapy, affecting 30–70% of patients receiving neurotoxic chemotherapy. It is a major cause of dose reduction, treatment discontinuation, and long-term functional impairment. CIPN significantly impacts quality of life through pain, sensory loss, impaired balance, and reduced fine motor function.

Agent Class	Specific Agents	Neuropathy Pattern	Key Features
Platinum compounds	Cisplatin, oxaliplatin, carboplatin	Sensory >> motor; large-fiber predominant	Cisplatin: cumulative, dose-dependent; dorsal root ganglionopathy; proprioceptive loss; "coasting" — neuropathy may worsen for weeks to months after drug cessation. Oxaliplatin: acute cold-triggered dysesthesias (unique) + chronic cumulative sensory neuropathy
Taxanes	Paclitaxel, docetaxel, cabazitaxel	Length-dependent sensory > motor	Microtubule disruption in axonal transport; paclitaxel most neurotoxic; painful neuropathy common; dose-dependent; onset within first few cycles
Vinca alkaloids	Vincristine, vinblastine	Motor > sensory (distinguishing feature)	Vincristine: distal weakness, foot drop, wrist drop; autonomic neuropathy (constipation, ileus); cranial neuropathy possible; cumulative; onset early in treatment
Proteasome inhibitors	Bortezomib, carfilzomib	Painful small-fiber neuropathy	Bortezomib: burning pain, allodynia; subcutaneous administration reduces neuropathy risk vs. IV; partially reversible with dose reduction
Immunomodulatory	Thalidomide, lenalidomide	Sensory, length-dependent	Thalidomide: cumulative, dose-dependent; may be irreversible; lenalidomide has lower neurotoxicity risk
Antibody-drug conjugates	Brentuximab vedotin, polatuzumab	Sensory > motor; length-dependent	Due to MMAE (auristatin) payload; similar to vinca alkaloid mechanism; generally reversible with dose modification

Diagnosis of CIPN

Clinical assessment: Total Neuropathy Score (TNS), CTCAE grading (Grade 1–4), patient-reported outcome measures (EORTC QLQ-CIPN20)
Nerve conduction studies/EMG: Confirm axonal sensory neuropathy (reduced SNAP amplitudes); useful to establish baseline and monitor progression
Key differential: Distinguish from paraneoplastic neuropathy (especially anti-Hu sensory neuronopathy), diabetic neuropathy, nutritional deficiencies (B12), and leptomeningeal disease

CIPN Management: Evidence-Based Approach

Duloxetine 60 mg/day: The ONLY agent with Level A evidence for CIPN treatment (randomized crossover trial showed significant pain reduction vs. placebo)
Dose modification: Primary strategy for prevention — dose reduction or treatment delay based on CTCAE grade
Oxaliplatin acute syndrome: Avoid cold exposure; calcium/magnesium infusions may reduce acute symptoms (no effect on chronic CIPN)
Subcutaneous bortezomib: Reduces CIPN incidence by ~25% compared to IV administration with equivalent efficacy
Not recommended: Gabapentin, pregabalin, tricyclic antidepressants — insufficient evidence specifically for CIPN (though often used empirically)
No proven preventive agents: Vitamin E, glutamine, acetyl-L-carnitine, alpha-lipoic acid, and amifostine have not shown consistent benefit in clinical trials

Cisplatin "Coasting" Phenomenon

Cisplatin neuropathy may worsen for 2–6 months after drug discontinuation
This "coasting" effect is due to ongoing platinum accumulation in dorsal root ganglia with slow clearance
Clinicians and patients must be warned that neuropathy progression after stopping cisplatin does NOT indicate a new neurologic process
Most coasting stabilizes by 6–12 months, though significant residual deficits are common

Immune Checkpoint Inhibitor (ICI) Neurotoxicity

Immune checkpoint inhibitors (anti-PD-1: nivolumab, pembrolizumab; anti-PD-L1: atezolizumab, durvalumab; anti-CTLA-4: ipilimumab) have revolutionized oncology but produce immune-related adverse events (irAEs) in up to 60% of patients. Neurologic irAEs occur in approximately 1–5% of patients, but can be severe and life-threatening. Combination ICI therapy (anti-PD-1 + anti-CTLA-4) carries the highest risk.

Neurologic irAE	Frequency	Clinical Features	Key Points
Myasthenia gravis	0.1–0.2% (most common severe)	De novo MG; rapid onset; bulbar and respiratory predominant; often fulminant	Overlap with myositis in ~30% (elevated CK); overlap with myocarditis in ~10% (lethal triad); anti-AChR antibodies positive in ~65%; anti-striational antibodies common
Myositis	0.4–1%	Proximal weakness, elevated CK (often >5000), myalgias; may involve ocular muscles (ptosis, diplopia)	Frequently overlaps with MG; cardiac involvement (myocarditis) must be excluded with troponin, ECG, echocardiogram
Encephalitis	0.1–0.5%	Altered mental status, seizures, cognitive decline; may be limbic, diffuse, or brainstem	May be autoimmune antibody-positive (anti-NMDAR, anti-Ma2, anti-GAD65) or seronegative; MRI may show T2 changes in medial temporal lobes or be normal
Guillain-Barré syndrome	0.1–0.3%	Ascending weakness, areflexia, CSF albuminocytologic dissociation	May progress faster than typical GBS; IVIG or PLEX preferred over steroids alone; monitor respiratory function closely
Aseptic meningitis	0.1–0.5%	Headache, neck stiffness, photophobia; CSF lymphocytic pleocytosis	Often self-limited; more common with anti-CTLA-4 (ipilimumab); rule out leptomeningeal disease and infection
Transverse myelitis	<0.1%	Sensory level, paraparesis, bowel/bladder dysfunction	Rare but devastating; aggressive immunosuppression required
Cranial neuropathies	0.1–0.5%	Facial nerve palsy most common; optic neuritis; hearing loss	Bilateral facial palsy should raise suspicion; exclude leptomeningeal disease
Peripheral neuropathy	1–3%	Sensorimotor, length-dependent; may be demyelinating or axonal	Usually mild (Grade 1–2); severe cases rare; differentiate from CIPN if prior chemotherapy

ICI-Myasthenia Gravis: The Lethal Triad

ICI-triggered MG is often de novo (no prior MG history) and fulminant with rapid respiratory compromise
Myasthenia + Myositis + Myocarditis overlap occurs in ~10% and carries >50% mortality
Check CK, troponin, ECG, and echocardiogram in ALL patients with ICI-associated MG
Immediate management: Hold ICI permanently, high-dose IV methylprednisolone (1 g/day × 3–5 days), early IVIG or PLEX
Pyridostigmine alone is insufficient and may precipitate cholinergic crisis in ICI-MG

ICI Neurotoxicity Management Algorithm

Grade	Clinical Features	Management
Grade 1 (mild)	Mild symptoms; no interference with daily activities	May continue ICI with close monitoring; consider holding ICI; neurology consultation
Grade 2 (moderate)	Moderate symptoms; some interference with daily activities	Hold ICI; oral prednisone 0.5–1 mg/kg/day; neurology referral; MRI/LP as indicated
Grade 3 (severe)	Severe symptoms; hospitalization required	Permanently discontinue ICI; IV methylprednisolone 1–2 mg/kg/day; consider IVIG or PLEX; ICU monitoring for MG/GBS
Grade 4 (life-threatening)	Life-threatening; urgent intervention required	Permanently discontinue ICI; IV methylprednisolone 1 g/day × 3–5 days; emergent PLEX or IVIG; ICU admission; intubation if respiratory failure

CAR-T Cell Neurotoxicity (ICANS)

Chimeric antigen receptor (CAR) T-cell therapy has transformed the treatment of B-cell malignancies (DLBCL, ALL, mantle cell lymphoma, multiple myeloma). Immune Effector Cell-Associated Neurotoxicity Syndrome (ICANS) is the most common neurologic complication, occurring in 20–65% of patients depending on the CAR-T product and underlying disease. ICANS is believed to result from cytokine-mediated endothelial activation and blood-brain barrier disruption.

Feature	Details
Onset	Typically 3–10 days after CAR-T infusion; often follows or co-occurs with cytokine release syndrome (CRS)
Clinical features	Encephalopathy (most common), aphasia/word-finding difficulty, tremor, seizures, cerebral edema (rare but potentially fatal)
ICE score	Immune Effector Cell-Associated Encephalopathy score: orientation (4 pts), naming (3 pts), following commands (1 pt), writing a sentence (1 pt), attention/counting (1 pt); total 10 points
ICANS Grade 1	ICE 7–9: mild confusion, word-finding difficulty
ICANS Grade 2	ICE 3–6: moderate encephalopathy, but arousable
ICANS Grade 3	ICE 0–2: severe encephalopathy; clinical seizures; focal deficits
ICANS Grade 4	Obtunded/comatose, status epilepticus, cerebral edema, papilledema
Risk factors	High tumor burden, preexisting neurologic conditions, high-grade CRS, elevated ferritin/IL-6/C-reactive protein

ICANS Treatment

Dexamethasone: First-line treatment for ICANS Grade ≥2; 10 mg IV every 6 hours for Grade 2–3; high-dose methylprednisolone (1 g/day) for Grade 4
Tocilizumab (anti-IL-6R): Primary treatment for CRS but does NOT cross the BBB effectively; limited efficacy for isolated ICANS
Anakinra (IL-1 receptor antagonist): Emerging evidence for refractory ICANS; crosses BBB better than tocilizumab; being evaluated in clinical trials
Seizure prophylaxis: Levetiracetam 500–750 mg BID during the risk window (days 0–30) is commonly used at many centers
Cerebral edema management: Rare but potentially fatal; high-dose steroids, hyperosmolar therapy, neurosurgical consultation for severe cases

ICE Score Assessment (Quick Reference)

Orientation (4 points): Year, month, city, hospital — 1 point each
Naming (3 points): Name 3 objects — 1 point each
Following commands (1 point): "Close your eyes and open them"
Writing (1 point): Ability to write a standard sentence
Attention (1 point): Count backwards from 100 by 10s
Total 10 points; perform at baseline and twice daily during CAR-T monitoring period

Methotrexate Neurotoxicity

Methotrexate (MTX) is a cornerstone of treatment for primary CNS lymphoma, ALL (CNS prophylaxis), and leptomeningeal disease. Its neurotoxicity follows three distinct temporal patterns that are critical to recognize.

Pattern	Onset	Route	Clinical Features	Mechanism & Management
Acute	Hours to days	Intrathecal	Chemical meningitis: headache, nausea, vomiting, neck stiffness, fever; CSF pleocytosis	Aseptic inflammation of meninges; self-limited (24–72 hours); supportive care; does not preclude future intrathecal therapy
Subacute	Days to 2 weeks	IV (high-dose) or intrathecal	Stroke-like episodes: transient focal deficits (aphasia, hemiparesis), sometimes with seizures; MRI may show restricted diffusion (DWI+)	Transient focal demyelination; usually self-resolving within 48–72 hours; aminophylline (adenosine antagonist) may be preventive; does not predict chronic toxicity
Chronic	Months to years	IV or intrathecal (especially with concurrent/prior WBRT)	Leukoencephalopathy: progressive cognitive decline, gait ataxia, urinary incontinence (dementia triad); MRI shows diffuse periventricular white matter T2 hyperintensity	Irreversible white matter injury; risk markedly increased with concurrent/prior whole-brain radiation; no effective treatment; dose reduction or avoidance of WBRT is the only prevention

Methotrexate + Whole-Brain Radiation: Synergistic Toxicity

Concurrent or sequential high-dose MTX and WBRT dramatically increases the risk of severe, irreversible leukoencephalopathy
Incidence of leukoencephalopathy: ~25% with combined MTX + WBRT vs. <5% with either alone
In primary CNS lymphoma treatment, the trend has shifted toward deferring WBRT or using reduced-dose WBRT to minimize this risk
Patients >60 years old are at highest risk for treatment-related leukoencephalopathy

Radiation Neurotoxicity

Radiation-induced neurotoxicity is classified by temporal onset into three categories, each with distinct pathophysiology and clinical significance. Differentiating late radiation necrosis from tumor progression is one of the most clinically important and challenging neuroimaging problems in neuro-oncology.

Category	Onset	Clinical Features	Pathophysiology	Prognosis
Acute	During or within weeks of RT	Headache, nausea, worsening of pre-existing focal deficits, fatigue	Vasogenic edema; disrupted blood-brain barrier	Self-limited; responsive to corticosteroids
Early-delayed	2–6 months post-RT	Somnolence syndrome (fatigue, drowsiness, especially in children after WBRT); transient worsening of MRI lesions (pseudoprogression); Lhermitte sign (after spinal RT)	Transient demyelination; resolves spontaneously	Self-limited (weeks to months); important to distinguish from true tumor progression
Late-delayed	>6 months post-RT (may occur years later)	Radiation necrosis: focal enhancing mass, seizures, progressive focal deficits. Cognitive decline: progressive memory and executive dysfunction. Leukoencephalopathy: diffuse white matter injury. Radiation-induced tumors: meningiomas, gliomas (decades later)	Vascular injury, fibrinoid necrosis, gliosis, white matter demyelination	Often irreversible; radiation necrosis may respond to bevacizumab; cognitive decline progressive

Radiation Necrosis vs. Tumor Progression

Distinguishing radiation necrosis from tumor recurrence is a critical diagnostic challenge because both present as enhancing lesions on MRI. Multiple advanced imaging modalities can help differentiate these entities.

Imaging Modality	Radiation Necrosis	Tumor Progression
Perfusion MRI (rCBV)	Low relative cerebral blood volume (hypoperfused)	High rCBV (hyperperfused, neoangiogenesis)
MR spectroscopy	High lipid-lactate peak; low choline; low choline/NAA ratio	Elevated choline; high choline/NAA ratio; elevated choline/creatine
FDG-PET	Hypometabolic (low FDG uptake)	Hypermetabolic (high FDG uptake; limited by high background cortical uptake)
Amino acid PET (FET, MET)	Low uptake	High uptake (more specific than FDG for brain tumors)
DWI/ADC	Variable; may show facilitated diffusion	Restricted diffusion in highly cellular tumor

Bevacizumab for Radiation Necrosis

Bevacizumab (anti-VEGF antibody) is the most effective medical treatment for symptomatic radiation necrosis
Mechanism: reduces VEGF-driven vasogenic edema and vascular permeability in necrotic tissue
Typical regimen: bevacizumab 7.5 mg/kg IV every 2–3 weeks for 4–6 cycles
Response rate: >90% show radiographic improvement; significant steroid-sparing effect
Randomized trial (Levin et al., 2011) demonstrated superiority over placebo for radiation necrosis
Risks: hypertension, proteinuria, wound healing impairment, rare hemorrhage

Posterior Reversible Encephalopathy Syndrome (PRES)

PRES is an acute neurologic syndrome characterized by headache, seizures, visual disturbances, and altered mental status, with characteristic posterior-predominant vasogenic edema on neuroimaging. Multiple chemotherapeutic agents can trigger PRES through endothelial dysfunction.

PRES-Inducing Cancer Therapies

Calcineurin inhibitors: Tacrolimus, cyclosporine (post-transplant setting)
Anti-VEGF agents: Bevacizumab, sorafenib, sunitinib, pazopanib
Cytotoxic chemotherapy: Cisplatin, cytarabine, methotrexate, gemcitabine
Immune checkpoint inhibitors: Rare but reported
CAR-T cell therapy: Associated with CRS/ICANS

Diagnosis and Management

MRI: T2/FLAIR hyperintensity predominantly in parieto-occipital white matter; DWI typically shows facilitated diffusion (vasogenic edema); restricted diffusion suggests cytotoxic edema and worse prognosis
Management: Discontinue offending agent, aggressive blood pressure control, antiepileptic drugs for seizures, magnesium sulfate (especially in eclampsia-related PRES)
Prognosis: Usually reversible within days to weeks with appropriate treatment; permanent injury occurs in ~5–15% with hemorrhagic or cytotoxic edema variants

Ifosfamide Encephalopathy

Feature	Details
Mechanism	Chloroacetaldehyde (neurotoxic metabolite) causes mitochondrial dysfunction; depletes brain glutathione
Onset	Hours to days after ifosfamide infusion
Clinical features	Confusion, somnolence, hallucinations, cerebellar ataxia, seizures; may progress to coma
EEG	Generalized slowing, triphasic waves (may mimic metabolic encephalopathy)
Risk factors	Renal impairment, low serum albumin, prior cisplatin, hepatic dysfunction, pelvic disease (altered drug metabolism)
Treatment	Methylene blue 50 mg IV every 4–6 hours (acts as alternative electron carrier in mitochondrial chain); thiamine supplementation
Prophylaxis	Methylene blue 50 mg IV TID during ifosfamide infusion prevents recurrence in patients with prior encephalopathy
Prognosis	Usually fully reversible within 48–72 hours with methylene blue; mortality <1% with prompt treatment

Other Notable Neurotoxicities

Agent	Neurotoxicity	Key Features
5-Fluorouracil / Capecitabine	Cerebellar syndrome	Acute ataxia, dysarthria, nystagmus; due to dihydropyrimidine dehydrogenase (DPD) deficiency — genetic testing recommended before initiation; reversible with drug cessation
Cytarabine (high-dose)	Cerebellar toxicity	Pancerebellar syndrome at doses ≥3 g/m²; age >50 and renal impairment increase risk; may be irreversible (Purkinje cell loss); assess cerebellar function between doses
Intrathecal cytarabine	Arachnoiditis, myelopathy	Chemical arachnoiditis; co-administer dexamethasone to prevent; transverse myelopathy rare but devastating
Bevacizumab	PRES, hemorrhage, ischemic stroke	Anti-VEGF disrupts vascular homeostasis; monitor blood pressure; increased risk of intracranial hemorrhage in brain tumor patients
Ibrutinib	Intracranial hemorrhage	Subdural hematoma risk, especially with concurrent anticoagulation or antiplatelet agents; mechanism involves platelet dysfunction
Crizotinib/Lorlatinib	CNS effects	Lorlatinib: cognitive effects, mood changes, psychosis, vivid dreams (CNS-penetrant by design); crizotinib: visual disturbances
Fludarabine	Severe neurotoxicity at high doses	Delayed progressive encephalopathy, blindness, coma; rare at standard doses; irreversible at toxic doses
Intrathecal vincristine	FATAL	Intrathecal vincristine administration is universally fatal (ascending myeloencephalopathy); vincristine must NEVER be administered intrathecally — institutional safeguards mandatory

Never-Event: Intrathecal Vincristine

Intrathecal vincristine is uniformly fatal — causing ascending radiculomyeloencephalopathy and death
This has been classified as a "never event" by patient safety organizations worldwide
Institutional safeguards: vincristine must be dispensed in a minibag (not syringe), labeled "FOR IV USE ONLY," and never co-transported with intrathecal medications
WHO has issued specific recommendations to prevent this error

Comprehensive Toxicity Reference by Agent Class

Agent Class	CNS Toxicity	PNS Toxicity	Other Neurologic
Platinum compounds	PRES, ototoxicity (cisplatin)	Sensory neuropathy (all), coasting (cisplatin), cold dysesthesias (oxaliplatin)	Lhermitte sign (cisplatin)
Taxanes	Encephalopathy (rare)	Sensory > motor neuropathy, myalgias	—
Vinca alkaloids	SIADH (vincristine)	Motor > sensory neuropathy, autonomic neuropathy	Cranial neuropathies, jaw pain
Methotrexate	Chemical meningitis, stroke-like episodes, leukoencephalopathy	—	Synergistic toxicity with WBRT
Checkpoint inhibitors	Encephalitis, meningitis, PRES	MG, myositis, GBS, neuropathy	Myocarditis overlap, cranial neuropathies
CAR-T cells	ICANS, seizures, cerebral edema	—	Aphasia, tremor
Radiation	Edema, pseudoprogression, radiation necrosis, leukoencephalopathy, cognitive decline	Brachial/lumbosacral plexopathy (late)	Radiation-induced tumors, vasculopathy
Anti-VEGF agents	PRES, intracranial hemorrhage	—	Stroke, wound healing impairment
Proteasome inhibitors	PRES (rare)	Painful small-fiber neuropathy	Herpes zoster reactivation

References

Hershman DL, Lacchetti C, Dworkin RH, et al. Prevention and management of chemotherapy-induced peripheral neuropathy in survivors of adult cancers: American Society of Clinical Oncology clinical practice guideline. J Clin Oncol. 2014;32(18):1941-1967.
Smith EML, Pang H, Cirrincione C, et al. Effect of duloxetine on pain, function, and quality of life among patients with chemotherapy-induced painful peripheral neuropathy: a randomized clinical trial. JAMA. 2013;309(13):1359-1367.
Brahmer JR, Lacchetti C, Schneider BJ, et al. Management of immune-related adverse events in patients treated with immune checkpoint inhibitor therapy: American Society of Clinical Oncology clinical practice guideline. J Clin Oncol. 2018;36(17):1714-1768.
Cuzzubbo S, Javeri F, Tissier M, et al. Neurological adverse events associated with immune checkpoint inhibitors: review of the literature. Eur J Cancer. 2017;73:1-8.
Lee DW, Santomasso BD, Locke FL, et al. ASTCT consensus grading for cytokine release syndrome and neurologic toxicity associated with immune effector cells. Biol Blood Marrow Transplant. 2019;25(4):625-638.
Neelapu SS, Tummala S, Kebriaei P, et al. Chimeric antigen receptor T-cell therapy — assessment and management of toxicities. Nat Rev Clin Oncol. 2018;15(1):47-62.
Chamberlain MC. Neurotoxicity of intrathecal methotrexate. In: Newton HB, ed. Handbook of Brain Tumor Chemotherapy, Molecular Therapeutics, and Immunotherapy. 2nd ed. Elsevier; 2018:529-538.
Ruben JD, Dally M, Bailey M, et al. Cerebral radiation necrosis: incidence, outcomes, and risk factors with emphasis on radiation parameters and chemotherapy. Int J Radiat Oncol Biol Phys. 2006;65(2):499-508.
Levin VA, Bidaut L, Hou P, et al. Randomized double-blind placebo-controlled trial of bevacizumab therapy for radiation necrosis of the central nervous system. Int J Radiat Oncol Biol Phys. 2011;79(5):1487-1495.
Fugate JE, Rabinstein AA. Posterior reversible encephalopathy syndrome: clinical and radiological manifestations, pathophysiology, and outstanding questions. Lancet Neurol. 2015;14(9):914-925.
Cavaliere R, Schiff D. Neurologic toxicities of cancer therapies. Curr Neurol Neurosci Rep. 2006;6(3):218-226.
Giglio P, Gilbert MR. Neurologic complications of cancer and its treatment. Curr Oncol Rep. 2010;12(1):50-59.
Pelgrims J, De Vos F, Van den Brande J, et al. Methylene blue in the treatment and prevention of ifosfamide-induced encephalopathy: report of 12 cases and a review of the literature. Br J Cancer. 2000;82(2):291-294.
Verstappen CC, Heimans JJ, Hoekman K, Postma TJ. Neurotoxic complications of chemotherapy in patients with cancer: clinical signs and optimal management. Drugs. 2003;63(15):1549-1563.
Santomasso BD, Park JH, Salloum D, et al. Clinical and biological correlates of neurotoxicity associated with CAR T-cell therapy in patients with B-cell acute lymphoblastic leukemia. Cancer Discov. 2018;8(8):958-971.