CT Head/Brain - CAM 742HB
Description
Computed tomography (CT) is an imaging technique used to view the structures of the brain and is useful in evaluating pathologies in the brain. It provides more detailed information on head trauma, brain tumors, stroke, and other pathologies in the brain than regular radiographs.
CT scan for headache — Generally, magnetic resonance imaging is the preferred imaging technique for evaluating the brain parenchyma, and CT is preferable for evaluating subarachnoid hemorrhage. CT is faster and more readily available than MRI and is often used in urgent clinical situations. Neurologic imaging is warranted in individuals with headache disorders along with abnormal neurologic examination results or predisposing factors for brain pathology.
Headache time frames and other characteristics — Generally, acute headaches are present from hours to days, subacute from days to weeks, and chronic headaches for more than 3 months. Acute severe headaches are more likely to be pathological (e.g., SAH, cerebral venous thrombosis) than non-acute (e.g., migraine, tension-type). Headaches can also be categorized as new onset or chronic/recurrent. Non-acute, new onset headaches do not require imaging unless there is a red flag as delineated above. Incidental findings lead to additional medical procedures and expense that do not improve individual well-being. Primary headache syndromes, such as migraine and tension headaches, are often episodic with persistent or progressive headache not responding to treatment, requiring further investigation (e.g., new daily persistent headache). Imaging is indicated in chronic headaches if there is a change in the headache frequency (number of headaches episodes/month), duration of each episode, severity of the headaches or new characteristics, such as changing aura or associated symptoms.1,6,104,105,106
Migraine with aura6,7,107— The headache phase of a migraine is preceded and/or accompanied by transient neurological symptoms, referred to as aura, in at least a third of migraine attacks. The most common aura consists of positive and/or negative visual phenomena, present in up to 99% of the individuals. Somatosensory is the secondary most common type of aura (mostly paresthesia in an upper limb and/or hemiface). Language/speech (mainly paraphasia and anomic aphasia) can also be affected. These neurological symptoms typically evolve over a period of minutes and may last up to 20 minutes or more. The gradual evolution of symptoms is thought to reflect spreading of a neurological event across the visual and somatosensory cortices. Characteristically, the aura usually precedes and terminates prior to headache, usually within 60 minutes. In others, it may persist or begin during the headache phase. ICHD-3 definition of the aura of migraine with typical aura consists of visual and/or sensory and/or speech/language symptoms, but no motor, brainstem, or retinal symptoms and is characterized by gradual development, duration of each symptom no longer than one hour, a mix of positive and negative features and complete reversibility. Atypical or complex aura includes motor brain stem, monocular visual disturbances, or ocular cranial nerve involvement (hemiplegic migraine, basilar migraine/brainstem aura, retinal migraine, ophthalmoplegic migraine) and secondary causes need to be excluded. Additional features of an aura that raise concern for an underlying vascular etiology include late age of onset, short duration, evolution of the focal symptoms, negative rather than positive visual phenomenon, and history of vascular risk factors.
Neurological deficits — Examples of abnormal reflexes related to upper motor neuron lesion/central pathology include hyperreflexia, clonus, Hoffman sign and Babinski, snout, palmar grasp, and rooting reflexes.
Visual loss has many possible etiologies, and MRI or CT is only indicated in suspected neurological causes of visual loss based on history and exam. Visual field defects, such as bitemporal hemianopsia, homonymous hemianopsia, or quadranopsia, require imaging as well as does suspected optic nerve pathology. Subjective symptoms such as blurred vision or double vision with no clear correlate on neurological examination requires a comprehensive eye evaluation to exclude more common causes, such as cataracts, refractive errors, retinopathy, glaucoma, or macular degeneration. Transient visual loss with history consistent with TIA but normal exam at time of examination also should be imaged. Positive visual phenomena, such as photopsias or scintillations that march across the visual field, suggest migraine whereas negative phenomenon, such as shaded or blurred, is more characteristic of ischemia.
Imaging for stroke — Individuals presenting with symptoms of acute stroke should receive prompt imaging to determine whether they are candidates for treatment with tissue plasminogen activator. Non-contrast CT can evaluate for hemorrhage that would exclude the individual from reperfusion therapy. Functional imaging can be used to select individuals for thrombolytic therapy by measuring the mismatch between “infarct core” and “ischemic penumbra” and may define ischemic areas of the brain with the potential to respond positively to reperfusion therapy. Contrast-enhanced CT angiography (CTA) may follow the non-contrast CT imaging to identify areas of large vessel stenosis or occlusion which may be a target for therapy.
Recent stroke or transient ischemic attack — A stroke or central nervous system infarction is defined as “brain, spinal cord, or retinal cell death attributable to ischemia, based on neuropathological, neuroimaging, and/or clinical evidence of permanent injury. … Ischemic stroke specifically refers to central nervous system infarction accompanied by overt symptoms, whereas silent infarction causes no known symptoms.”108 If imaging or pathology is not available, a clinical stroke is diagnosed by symptoms persisting for more than 24 hours. Ischemic stroke can be further classified by the type and location of ischemia and the presumed etiology of the brain injury. These include large-artery atherosclerotic occlusion (extracranial or intracranial), cardiac embolism, small-vessel disease and less commonly dissection, hypercoagulable states, sickle cell disease and undetermined causes.109 TIAs in contrast, “are a brief episode of neurological dysfunction caused by focal brain or retinal ischemia, with clinical symptoms typically lasting less than one hour, and without evidence of acute infarction on imaging.”110 On average, the annual risk of future ischemic stroke after a TIA or initial ischemic stroke is 3% – 4%, with an incidence as high as 11% over the next 7 days and 24% – 29% over the following 5 years. This has significantly decreased in the last half century due to advances in secondary prevention.111
Therefore, when revascularization therapy is not indicated or available in individuals with an ischemic stroke or TIA, the focus of the work-up is on secondary prevention. This includes noninvasive vascular imaging to identify the underlying etiology and to assess immediate complications and risk of future stroke. The majority of stoke evaluations take place in the inpatient setting. Admitting TIA individuals is reasonable if they present within 72 hours and have an ABCD (2) score ≥ 3, indicating high risk of early recurrence, or the evaluation cannot be rapidly completed on an outpatient basis.110 Minimally, both stroke and TIA should have an evaluation for high-risk modifiable factors, such as carotid stenosis atrial fibrillation, as the cause of ischemic symptoms.109 Diagnostic recommendations include neuroimaging evaluation as soon as possible, preferably with MRI, including DWI; noninvasive imaging of the extracranial vessels should be performed; and noninvasive imaging of intracranial vessels is reasonable.112
Individuals with a history of stroke and recent workup with new signs or symptoms indicating progression or complications of the initial CVA should have repeat brain imaging as an initial study. Individuals with remote or silent strokes discovered on imaging should be evaluated for high-risk modifiable risk factors based on the location and type of the presumed etiology of the brain injury.
CT and central venous thrombosis — A CTV or MRV is indicated for the definite evaluation of a central venous thrombosis/dural sinus thrombosis. The most frequent presentations are isolated headache, intracranial hypertension syndrome (headache, nausea/vomiting, transient visual obscurations, pulsatile tinnitus, CN VI palsy, papilledema),113 seizures, focal neurological deficits, and encephalopathy. Risk factors are hypercoagulable states inducing genetic prothrombotic conditions, antiphospholipid syndrome and other acquired prothrombotic diseases (such as cancer), oral contraceptives, pregnancy, puerperium (6 weeks postpartum), infections, and trauma. Since venous thrombosis can cause SAH, infarctions, and hemorrhage, parenchymal imaging with MRI/CT is also appropriate.16,114,115
CT scan for head trauma — Most types of head injury are minor injuries; clinical signs and symptoms help predict the need for brain CT following injury. CT has advantages in evaluating head injury due to its sensitivity for demonstrating mass effect, ventricular size and configuration, bone injuries, and acute hemorrhage. An individual who presents with certain clinical risk factors may be more likely to benefit from CT imaging. Some of the clinical risk factors that may be used as a guide to predict the probability of abnormal CT following minor head injury are vomiting, skull fracture, and age greater than 60 years. Individuals with a Glasgow Coma Scale of 15 or less who also have been vomiting or have a suspected skull fracture are likely to show abnormal results on CT scan. CT is also useful in detecting delayed hematoma, hypoxic-ischemic lesions, or cerebral edema in the first 72 hours after head injury.
CT and tumors — MRI is the ideal modality to follow-up meningioma, pituitary tumors, low grade tumors, neurocutaneous syndromes, and staging/surveillance for non-CNS cancers. CT should only be used when MRI is contraindicated or is unable to be obtained. Surveillance timelines should follow NCCN guidelines. Imaging is also warranted if the individual is symptomatic or there are new/changing signs or symptoms or complicating factors.
MMSE — The Mini Mental State Examination (MMSE) is a tool that can systematically and thoroughly assess mental status. It is an 11-question measure that tests five areas of cognitive function: orientation, registration, attention and calculation, recall, and language. The MMSE has been the most commonly used measure of cognitive function in dementia research, but researchers have recognized that it is relatively insensitive and variable in mildly impaired individuals. The maximum score is 30. A score of 23 or lower is indicative of cognitive impairment. The MMSE takes only 5 – 10 minutes to administer and is, therefore, practical to use repeatedly and routinely.
MoCA — The Montreal Cognitive Assessment (MoCA) was designed as a rapid screening instrument for mild cognitive dysfunction. It assesses different cognitive domains: attention and concentration, executive functions, memory, language, visuoconstructional skills, conceptual thinking, calculations, and orientation. MoCA differs from the MMSE mainly by including tests of executive function and abstraction, and by putting less weight on orientation to time and place. Ten of the MMSE's 30 points are scored solely on the time-place orientation test, whereas the MoCA assigns it a maximum of six points. The MoCA also puts more weight on recall and attention-calculation performance, while de- emphasizing language skill. Time to administer the MoCA is approximately 10 minutes. The total possible score is 30 points; a score of 26 or above is considered normal.
CT for evaluation of the cranial nerves — Magnetic resonance imaging (MRI) is considered the gold standard in the study and evaluation of the cranial nerves. Computed tomography (CT) allows, usually, an indirect view of the nerve and is useful to demonstrate the intraosseous segments of cranial nerves, the foramina through which they exit skull base, and their pathologic changes. In optic neuritis, CT has limited utility. Contrast-enhanced CT scanning of the orbits may help exclude other orbital pathology. CT scanning of the brain, regardless of whether intravenous contrast material is administered or not, does not yield prognostic and treatment-altering information. In Bell’s Palsy temporal bone CT is useful in the evaluation of the caliber and the course of the IAC and bony facial nerve canal in the temporal bone. When using CT to evaluate the facial nerve, pathology often can only be inferred by visualization of erosion or destruction of the adjacent bony facial nerve canal. In contrast, MRI visualizes soft tissues well and so is better suited for evaluating soft tissue facial nerve abnormalities.
Anosmia — There is no relevant literature to support the use of CT head in the evaluation of the olfactory nerve.
CT scan for congenital abnormalities — While MRI is preferred to CT for evaluation of most congenital CNS abnormalities, in some clinical situations CT is preferred (craniosynostosis) or equivalent to MRI. CT is appropriate in the follow-up of hydrocephalus or VP shunt function where the etiology of hydrocephalus has been previously determined or in individuals for which MRI evaluation would require general anesthesia.
CT for macrocephaly — Consider ultrasound in infants with macrocephaly and a normal neurological examination, no evidence of increased ICP, and an open anterior fontanelle. If head US is normal, the infant should be monitored closely.116 The anterior fontanelle generally closes between 10 and 24 months of age, with 3% closing between 5 – 9 months and 11% after 24 months.117
CT and normal pressure hydrocephalus (NPH) — Although diagnosis can be made based on CT findings alone, MRI is more accurate for disclosing associated pathologies (such as cerebrovascular disease), excluding other potential etiologies, and for detecting NPH typical signs of prognostic value. A CT scan can exclude NPH and is appropriate for screening purposes and in individuals who cannot undergo MRI.
CT and vertigo — The most common causes of vertigo seen are benign paroxysmal positional vertigo (BPPV), vestibular neuronitis (VN) and Ménière’s disease. These peripheral causes of vertigo are benign, and treatment involves reassurance and management of symptoms. Central causes of vertigo, such as cerebrovascular accidents (CVAs), tumors and multiple sclerosis (MS), need to be considered if the individual presents with associated neurological symptoms, such as weakness, diplopia, sensory changes, ataxia or confusion. Magnetic resonance imaging is appropriate in the evaluation of individuals with vertigo who have neurologic signs and symptoms, progressive unilateral hearing loss or risk factors for cerebrovascular disease. MRI is more appropriate than CT for diagnosing vertigo due to its superiority in visualizing the posterior portion of the brain, where most central nervous system disease that causes vertigo is found. A full neurologic and otologic evaluation including provocative maneuvers, vestibular function testing and audiogram can help evaluate vertigo of unclear etiology and differentiate between central and peripheral vertigo.
CT and developmental delay — Significant developmental delay is defined as significant delay (more than two standard deviations below the mean) in one or more developmental domains: gross/fine motor, speech/language, cognition, social/personal, and activities of daily living. Isolated delay in social/language development is characteristic of autism spectrum disorders or hearing loss. Isolated delay in motor development is characteristic of cerebral palsy (a static encephalopathy) or myopathy.
Global developmental delay (GDD) is a subset of developmental delay defined as significant delay (by at least 2 SD’s) in two or more developmental categories. Note that the term “GDD” is usually reserved for children < 5 years old, whereas in older children > 5 years, disability is quantifiable with IQ testing.
CT scan and meningitis — In suspected bacterial meningitis, CT with contrast may be performed before lumbar puncture (LP) to show preliminary meningeal enhancement. It is important to evaluate for a mass lesion or cause of elevated ICP that would contraindicate an LP. CT may be used to define the pathology of the base of the skull and that may require therapeutic intervention and surgical consultation. Some causes of an intracranial infection include fractures of the paranasal sinus and inner ear infection.
Leptomeningeal carcinomatosis118,119,120,121 — Leptomeningeal metastasis is an uncommon and typically late complication of cancer with poor prognosis and limited treatment options. Diagnosis is often challenging with nonspecific presenting symptoms ranging from headache and confusion to focal neurologic deficits such as cranial nerve palsies. Standard diagnostic evaluation involves a neurologic examination, MRI of the brain and spine with gadolinium, and cytologic evaluation of the cerebral spinal fluid (CSF). Hematologic malignancies (leukemia and lymphoma), primary brain tumors as well as solid malignancies can spread to the leptomeninges. The most common solid tumors giving rise to LM are breast cancer (12% – 35 %), small and non-small cell lung cancer (10% – 26%), melanoma (5% – 25%), gastrointestinal malignancies (4% – 14%), and cancers of unknown primary (1% – 7%).
Drop metastases — Drop metastases are intradural extramedullary spinal metastases that arise from intracranial lesions. Common examples of intracranial neoplasms that result in drop metastases include pineal tumors, ependymomas, medulloblastomas, germinomas, primitive neuroectodermal tumors (PNET), glioblastomas multiform, anaplastic astrocytomas, oligodendrogliomas and less commonly choroid plexus neoplasms and teratomas.122
General Information
It is an expectation that all patients receive care/services from a licensed clinician. All appropriate supporting documentation, including recent pertinent office visit notes, laboratory data, and results of any special testing must be provided. If applicable: All prior relevant imaging results and the reason that alternative imaging cannot be performed must be included in the documentation submitted.
Where a specific clinical indication is not directly addressed in this guideline, medical necessity determination will be made based on widely accepted standard of care criteria. These criteria are supported by evidence-based or peer-reviewed sources such as medical literature, societal guidelines and state/national recommendations.
Policy
REDUCING RADIATION EXPOSURE
Brain CT/brain CTA are not approvable simultaneously unless they meet the criteria described below in the Indications for brain CT/brain CTA combination studies section. If there is a combination request* for an overlapping body part, either requested at the same time or sequentially (within the past 3 months) the results of the prior study should be:
- Inconclusive or show a need for additional or follow up imaging evaluation OR
- The office notes should clearly document an indication why overlapping imaging is needed and how it will change management for the patient.
*Unless approvable in the combination section as noted in the guidelines
Important Note: Brain MRI is preferred to brain CT in most circumstances where the patient can tolerate MRI and sufficient time is available to schedule the MRI examination. Assessment of subarachnoid hemorrhage, acute trauma, or bone abnormalities of the calvarium (fracture, etc.) may be better imaged with CT. CT is also appropriate in an urgent situation where MRI is not readily available (stroke, increased ICP, CNS infection).
‡‡Designates CT is indicated only when MRI is contraindicated or cannot be performed
INDICATIONS
Headache
Evaluation of Headache
- Chronic headache with a change in character/pattern (e.g., more frequent, increased severity, or duration) (1)
- Cluster headaches or other trigeminal-autonomic cephalgias, i.e., paroxysmal hemicrania, hemicrania continua, short-lasting unilateral neuralgiform headache attacks (SUNCT/SUNA) imaging is indicated once to eliminate secondary causes (1,2)
- Acute headache, sudden onset:
- With a personal or family history (brother, sister, parent, or child) of brain aneurysm or AVM (arteriovenous malformation) OR
- < 48 hours of “worst headache in my life” or “thunderclap” headache (Sudden onset new headache reaching maximum intensity within 2-3 minutes, lasting more than 5 minutes).
- Prior history of stroke or intracranial bleed
- Known coagulopathy or on anticoagulation
- New onset of headache with any of the following (1,3,4):
- Acute, new, or fluctuating neurologic deficits, such as sensory deficits, limb weakness, abnormal reflexes (pathological, asymmetric, hyperreflexia), speech difficulties, visual loss, lack of coordination, or mental status changes or with signs of increased intracranial pressure (papilledema). (See background)
- History of cancer or significantly immunocompromised
- Fever
- Subacute head trauma
- Age > 50 (1,3)
- Severe unilateral headache with radiation to or from the neck, associated with suspicion of carotid or vertebral artery dissection
- Related to activity or event (sexual activity, exertion, Valsalva, position), new or progressively worsening (1,5,6,7)
- Persistent or progressively worsening during a course of physician-directed treatment (1)
Note: Neuroimaging warranted for atypical/complex migraine aura, but not for a typical migraine aura (1) (see background)
Special Considerations in the Pediatric Population with Persistent Headache (8,9)
- Occipital location
- Age < 6 years
- Symptoms indicative of increased intracranial pressure, such as recurring headaches after waking with or without associated nausea/vomiting
- Documented absence of family history of headache
- Severe headache in a child with an underlying disease that predisposes to intracranial pathology (e.g., immune deficiency, sickle cell disease, neurofibromatosis, history of neoplasm, coagulopathy, hypertension, congenital heart disease)
Neurological Symptoms or Deficits
Acute, new, or fluctuating neurologic symptoms or deficits such as, sensory deficits, limb weakness, abnormal reflexes (pathological, asymmetric, hyperreflexia), speech difficulties, visual loss, lack of coordination, or mental status changes (see background).
Stroke and Vascular Disease
Evaluation of Known or Suspected Stroke (15,16)
- Known or suspected stroke with any acute, new, or fluctuating symptoms or deficits such as sensory deficits, limb weakness, speech difficulties, visual loss, lack of coordination, or mental status changes (see background)
- Suspected stroke with a personal or first-degree family history (brother, sister, parent, or child) of aneurysm or known coagulopathy or on anticoagulation
- Symptoms of transient ischemic attack (TIA) (episodic neurologic symptoms such as sensory deficits, limb weakness, speech difficulties, visual loss, lack of coordination, or mental status changes)
- Evaluation of neurological signs or symptoms in sickle cell disease (17,18)
- High stroke risk in sickle cell patients (2 - 16 years of age) with a transcranial doppler velocity >200 (19)
Evaluation of Known or Suspected Vascular Disease
- Evaluation of suspected acute subarachnoid hemorrhage (SAH)
- Suspected central venous thrombosis- see background (20,21)
- Known Moyamoya disease or reversible cerebral vasoconstriction with any new or changing neurological signs or symptoms
- Follow-up for known hemorrhage, hematoma, or vascular abnormalities
Head Trauma
Evaluation of Known or Suspected Trauma (22,23,24)
- Known or suspected trauma or injury to the head with documentation of one or more of the following acute, new, or fluctuating:
- Focal neurologic findings
- Motor changes
- Mental status changes
- Amnesia
- Vomiting
- Seizures
- Headache
- Signs of increased intracranial pressure
- Known coagulopathy or on anticoagulation
- Known or suspected skull fracture by physical exam and/or prior imaging
- Repeat scan 24 hours post head trauma for anticoagulated patients with suspected diagnosis of delayed subdural hematoma
- Post concussive syndrome if persistent or disabling symptoms and imaging has not been performed
- Subacute or chronic traumatic brain injury with new cognitive and/or neurologic deficit
Brain Tumor, Mass, or Metastasis
Evaluation of Suspected Tumor/Mass/Cyst (1,25)
- Suspected brain tumor with any acute, new, or fluctuating neurologic symptoms or deficits such as sensory deficits, limb weakness, abnormal reflexes (pathological, asymmetric, hyperreflexia), speech difficulties, visual loss, lack of coordination, or mental status changes (see background)
- Lesion with atypical features for further evaluation or follow up
- Histiocytic Neoplasms for screening and/or with neurological signs or symptoms
- Erdheim-Chester Disease
- Langerhans Cell Histiocytosis
- Rosai-Dorfman Disease
Note: Suspected Pituitary Tumors (Brain MRI is the study of choice if indicated) or Sella CT if MRI is contraindicated or cannot be performed
Note: Screening for hereditary cancers syndromes (Brain MRI is the study of choice if indicated)
Evaluation of Known Brain Lesion/Cyst
- Bone tumor or abnormality of the skull (26)
- Histiocytic Neoplasms to assess treatment response and surveillance of known brain/skull lesions (27,28)
- Erdheim-Chester Disease
- Langerhans Cell Histiocytosis
- Rosai-Dorfman Disease
Note: Known pituitary tumors (Brain MRI is the study of choice if indicated) or Sella CT if MRI is contraindicated or cannot be performed
CT for Known Cancer
MRI is the ideal modality to follow-up meningioma, pituitary tumors, low grade tumors, neurocutaneous syndromes, and screening/restaging/surveillance for non-CNS cancers. CT should only be used when MRI is contraindicated or is unable to be obtained.
MRI is appropriate for any malignancy when there are signs or symptoms of brain metastases (e.g., headache, sensory deficits, memory problems). There does not need to be a neuro deficit on exam or other workup done first for a patient with cancer.
Combination Studies for Initial Staging, Active Monitoring, or Evaluation of Suspected Metastases (25)
< 5 concurrent studies to include CT or MRI of any of the following areas as appropriate depending on the cancer: Neck, Abdomen, Pelvis, Chest, Brain, Cervical Spine, Thoracic Spine or Lumbar Spine
Seizure Disorders
For Evaluation of Known or Suspected Seizure Disorder (29,30,31)
- New onset of seizures or newly identified change in seizure activity/pattern # (Brain MRI is the study of choice if indicated)
Infectious or Inflammatory Disease
Evaluation of Known or Suspected Infection or Inflammatory Disease
- Suspected intracranial abscess or brain infection with acute altered mental status or with positive lab findings (such as elevated WBCs) OR follow-up assessment during or after treatment completed.
- Meningitis with positive signs and symptoms (such as fever, headache, mental status changes, stiff neck) OR with positive lab findings (such as elevated white blood cells or abnormal lumbar puncture fluid exam) (32)
- Suspected encephalitis with headache and altered mental status or follow-up as clinically warranted
- Endocarditis with suspected septic emboli
- Central Nervous System (CNS) involvement in patients with known or suspected vasculitis or autoimmune disease with abnormal inflammatory markers or autoimmune antibodies
- Suspected primary CNS vasculitis based on neurological signs and symptoms with completed infectious/inflammatory lab work-up (33)
- Immunocompromised patient (e.g., transplant recipients, HIV with CD4<200, primary immunodeficiency syndromes, hematologic malignancies) with focal neurologic symptoms, headaches, behavioral, cognitive or personality changes
Cognitive Impairment
Evaluation of Cognitive Impairment (34,35)
- Mental status score of either MMSE or MoCA of less than 26 or other similar mental status instruments*/formal neuropsychological testing showing at least mild cognitive impairment AND a completed basic metabolic workup (such as thyroid function testing, liver function testing, complete blood count, electrolytes, and B12)
- *Other examples include Mini-Cog, Memory Impairment Screen, Saint Louis University Mental Status Examination (SLUMS), Brief Alzheimer's Screen (BAS), Blessed Dementia Scale (BDS), Clinical Dementia Rating (CDR) (36,37)
Movement Disorders
Evaluation of Movement Disorders (11,38)
- For evaluation of acute onset of a movement disorder with concern for stroke or hemorrhage
- For evaluation of suspected Parkinson’s with atypical feature or unresponsive to levodopa
- Note: Atypical parkinsonian syndromes include progressive supranuclear palsy (PSP), multiple system atrophy (MSA), corticobasal degeneration (CBD), and dementia with Lewy bodies.
- For the evaluation of other movement disorder to exclude a structural lesion (i.e., suspected Huntington disease, chorea, hemiballismus, atypical dystonia)
Note: CT has limited utility in the chronic phases of disease. Brain MRI is the study of choice if indicated. Imaging is not indicated in essential tremor, Tourette’ syndrome or isolated focal dystonia (e.g., blepharospasm, cervical dystonia, laryngeal dystonia, oromandibular dystonia, writer’s dystonia) (38,39).
Cranial Nerve and Vision Abnormalities
Vision Abnormalities
- Abnormal eye findings on physical or neurologic examination (papilledema, pathologic nystagmus, optic atrophy, ocular nerve palsies, new onset anisocoria, visual field deficit, etc.) Note: See background
- Binocular diplopia with concern for intracranial pathology after comprehensive eye evaluation (40)
- Childhood strabismus with development delay or abnormal fundoscopic exam to rule out intracranial abnormalities (41)
- Horner’s syndrome with symptoms localizing the lesion to the central nervous system (42)
Other Cranial Neuropathies
- Evaluation of cranial nerve palsy/neuropathy/neuralgia when thought to be due to tumor, stroke, or bony abnormalities of the skull base or when MRI is contraindicated or cannot be performed
- Bulbar symptoms, i.e., difficulty in chewing, weakness of the facial muscles, dysarthria, palatal weakness, dysphagia, and dysphonia and/or signs, i.e., atrophy and fasciculations of the tongue and absent gag reflex (43)
- Pseudobulbar symptoms, i.e., dysphagia, dysarthria, facial weakness, sudden, stereotyped emotional outbursts that are not reflective of mood and/or signs, i.e., spastic tongue and exaggerated gag/jaw jerk (44)
Congenital Abnormalities
Evaluation of Known or Suspected Congenital Abnormalities
- Known or suspected congenital abnormality with any acute, new, or fluctuating neurologic, motor, or mental status changes
- Evaluation of macrocephaly in an infant/child <18 with previously abnormal US, abnormal neurodevelopmental examination, signs of increased ICP or closed anterior fontanelle (45)
- Evaluation of microcephaly in an infant/child < 18 (46)
- Evaluation of craniosynostosis and other skull deformities. (47,48)
- Evaluation of the corticomedullary junction in Achondroplasia (49)
- Cerebral palsy if etiology has not been established in the neonatal period, there is change in the expected clinical or developmental profile or concern for progressive neurological disorder (50)
- Prior treatment OR treatment planned for congenital abnormality
Note: For evaluation of known or suspected hydrocephalus please see section on CSF abnormalities.
Cerebrospinal Fluid Abnormalities
Evaluation of Known or Suspected CSF Abnormalities
- Evaluation of suspected hydrocephalus with any acute, new, or fluctuating neurologic, motor, or mental status changes
- Known hydrocephalus*
- For initial evaluation of a suspected Arnold Chiari malformation (51)
- Follow-up imaging of a known type II or type III Arnold Chiari malformation. For Arnold Chiari type I, follow-up imaging only if new or changing signs/symptoms (52)
- Initial evaluation for a known syrinx or syringomyelia*
- Known or suspected normal pressure hydrocephalus (NPH) (53)
- With symptoms of gait difficulty, cognitive disturbance, and urinary incontinence
- Follow-up shunt evaluation(54,55,56)
- Post operativity if indicated based on underlying disease or pre-operative radiographic findings and/or
- 6-12 months after placement and/or
- With neurologic symptoms that suggest shunt malfunction
- Evaluation of known or suspected cerebrospinal fluid (CSF) leakage (57)
- Cisternography for intermittent and complex CSF rhinorrhea/otorrhea. CSF fluid should always be confirmed with laboratory testing (Beta-2 transferrin assay) (57,58)
- Suspected spontaneous intra-cranial hypotension with distinct postural headache (other symptoms include nausea, vomiting, dizziness, tinnitus, diplopia neck pain or imbalance) (1,59)
*Often congenital, but can present later in life; or less commonly acquired secondary to tumor, stroke, trauma, infection, etc.
Procedural Evaluations
Preoperative/Procedural Evaluation
- Pre-operative evaluation for a planned surgery or procedure
Postoperative/Procedural Evaluation
- A follow-up study may be needed to help evaluate a patient’s progress after treatment, procedure, intervention, or surgery. Documentation requires a medical reason that clearly indicates why additional imaging is needed for the type and area(s) requested.
Prior Imaging
Further Evaluation of Indeterminate Findings on Prior Imaging
Unless follow up is otherwise specified within the guideline:
- For initial evaluation of an inconclusive finding on a prior imaging report that requires further clarification.
- One follow-up exam of a prior indeterminate MR/CT finding to ensure no suspicious interval change has occurred. (No further surveillance unless specified as highly suspicious or change was found on last follow-up exam)
Other Indications
- Vertigo associated with any of the following (10)
- Signs or symptoms suggestive of a CNS lesion (ataxia, visual loss, double vision, weakness, or a change in sensation)
- Progressive unilateral hearing loss
- Risk factors for cerebrovascular disease with concern for stroke
- After full neurologic examination and vestibular testing with concern for central vertigo (i.e., skew deviation, vertical nystagmus, head thrust test, videonystagmography (VNG)/ electronystagmography (ENG))
- Diagnosis of central sleep apnea on polysomnogram
- Children > 1 year (60)
- Adults in the absence of heart failure, chronic opioid use, high altitude, or treatment emergent central sleep apnea AND concern for a central neurological cause (Chiari malformation, tumor, infectious/inflammatory disease) OR with an abnormal neurological exam
- Syncope with clinical concern for seizure or associated neurological signs or symptoms (61,62)
- Cyclical vomiting syndrome or abdominal migraine with any localizing neurological symptoms (63,64)
- Soft tissue mass of the head with nondiagnostic initial evaluation (ultrasound and/or radiograph) (65,66,67)
- Psychological changes with neurological deficits on exam or after completion of a full neurological assessment that suggests a possible neurologic cause (68)
- Global developmental delay or developmental delay with abnormal neurological examination in a child < 18 years (69,70)
- Unexplained event (BRUE) formerly apparent life-threatening event (ALTE) in infants
< 1 year with concern for neurological cause based on history and exam (71)
- Imaging is not indicated in low risk patients
- Prior to lumbar puncture in patients with suspected increased intracranial pressure or at risk for herniation
Combination Studies
Note:
These body regions might be evaluated separately or in combination as documented in the clinical notes by physical examination findings (e.g., localization to a particular segment of the neuroaxis), patient history, and other available information, including prior imaging.
Exception: Approved indications as noted above and being performed in a child under 8 years of age who will need anesthesia for the procedure and there is a suspicion of concurrent intracranial pathology
Brain CT and Brain CTA
- Recent ischemic stroke or transient ischemic attack (TIA) when MRI is contraindicated or cannot be performed (72,73)
- Acute, sudden onset of headache with personal history of a vascular abnormality or first-degree family history of aneurysm (74,75)
- Thunderclap headache >6 hours after onset in an acute setting with high suspicion of SAH (75)
- Headache associated with exercise, exertion, Valsalva or sexual activity when MRI is contraindicated or cannot be performed (76)
- Suspected venous thrombosis (dural sinus thrombosis) and MRI is contraindicated or cannot be performed (73) – CT/CTV**
- Neurological signs or symptoms in sickle cell patients when MRI is contraindicated or cannot be performed (17)
- High stroke risk in sickle cell patients (2 - 16 years of age) with a transcranial doppler velocity > 200 when MRI is contraindicated or cannot be performed (17)
- Known Moyamoya disease (77,78) or reversible cerebral vasoconstriction with any new or changing neurological signs or symptoms (75,79)
- Suspected secondary CNS vasculitis based on neurological signs or symptoms in the setting of an underlying systemic disease with abnormal inflammatory markers or autoimmune antibodies when MRI is contraindicated or cannot be performed (74)
- Suspected primary CNS vasculitis based on neurological signs and symptoms with completed infectious/inflammatory lab work-up when MRI is contraindicated or cannot be performed (74,80,81)
Brain CT and/or Brain CTA and/or Neck CTA
- Recent stroke or transient ischemic attack (TIA)
- Suspected or known carotid or vertebral artery dissection with focal or lateralizing neurological deficits
- *Note: MRA and CTA are generally comparable noninvasive imaging alternatives each with their own advantages and disadvantages. Brain MRI can alternatively be combined with Brain CTA/Neck CTA.
Brain CT/Cervical Spine CT/Thoracic Spine CT/Lumbar Spine CT (any combination)
- For initial evaluation of a suspected Arnold Chiari malformation
- Follow-up imaging of a known type II or type III Arnold Chiari malformation. For Arnold Chiari type I, follow-up imaging only if new or changing signs/symptoms
(82,83,84,85)
- Oncological Applications (e.g., primary nervous system, metastatic)
- Drop metastasis from brain or spine (CT spine imaging in this scenario is usually CT myelogram) see background
- Suspected leptomeningeal carcinomatosis (see background) (86)
- Tumor evaluation and monitoring in neurocutaneous syndromes
- CSF leak highly suspected and supported by patient history and/or physical exam findings (known or suspected spontaneous (idiopathic) intracranial hypotension (SIH), post lumbar puncture headache, post spinal surgery headache, orthostatic headache, rhinorrhea or otorrhea, or cerebrospinal-venous fistula - CT spine imaging in this scenario is usually CT myelogram)
Brain CT and Orbit CT
- Optic neuropathy or unilateral optic disk swelling of unclear etiology to distinguish between a compressive lesion of the optic nerve, optic neuritis, ischemic optic neuropathy (arteritic or non-arteritic), central retinal vein occlusion, or optic nerve infiltrative disorders(87)
- Bilateral optic disk swelling (papilledema) with vision loss(88)
- Approved indications as noted above and being performed in high-risk populations and will need anesthesia for the procedure and there is a suspicion of concurrent intracranial pathology(88)
Combination Studies for Malignancy for Initial Staging or Restaging
Unless otherwise specified in this guideline, indication for combination studies for malignancy for initial staging or restaging:
- Concurrent studies to include CT or MRI of any of the following areas as appropriate depending on the cancer: Abdomen, Brain, Chest, Neck, Pelvis, Cervical Spine, Thoracic Spine or Lumbar Spine
BACKGROUND
Contraindications and Preferred Studies
- Contraindications and reasons why a CT/CTA cannot be performed may include: impaired renal function, significant allergy to IV contrast, pregnancy (depending on trimester).
- Contraindications and reasons why and MRI/MRA cannot be performed may include: impaired renal function, claustrophobia, non-MRI compatible devices (such as non- compatible defibrillator or pacemaker), metallic fragments in a high-risk location, patient exceeds weight limit/dimensions of MRI machine.
Headache and Migraine
Headache timeframes and other characteristics – Headaches can be classified as acute, subacute or chronic. Acute headaches are present from hours to days, subacute from days to weeks and chronic headaches for more than 3 months. Acute severe headaches are more likely to be pathological (e.g., SAH, cerebral venous thrombosis) than non-acute (e.g., migraine, tension-type). Headaches can also be categorized as new onset or chronic/recurrent. Non-acute new onset headaches do not require imaging unless there is a red flag as delineated above. Incidental findings lead to additional medical procedures and expense that do not improve patient well-being. Primary headache syndromes, such as migraine and tension headaches, are often episodic with persistent or progressive headache not responding to treatment requiring further investigation (e.g., new daily persistent headache). Imaging is indicated in chronic headaches if there is a change in the headache frequency (number of headaches episodes/month), duration of each episode, severity of the headaches or new characteristics, such as changing aura or associated symptoms.
(1,2,89,90,91,92,93,94,95)
Migraine with aura (2,3,96) – The headache phase of a migraine is preceded and/or accompanied by transient neurological symptoms referred to as aura in at least a third of migraine attacks. Migraine with typical aura consists of visual and/or sensory and/or speech/language symptoms, but no motor, brainstem or retinal symptoms and is characterized by gradual development, duration of each symptom no longer than one hour, a mix of positive and negative features and complete reversibility. Atypical or complex aura includes motor, brainstem, monocular visual disturbances, or ocular cranial nerve involvement (hemiplegic migraine, basilar migraine/brainstem aura, retinal migraine, ophthalmoplegic migraine) and secondary causes need to be excluded. Additional features of an aura that raise concern for an underlying vascular etiology include late age of onset, short duration, evolution of the focal symptoms, negative rather than positive visual phenomenon, and history of vascular risk factors.
Individuals presenting with a new migraine with aura (especially an atypical or complex aura) can mimic a transient ischemic attack or an acute stroke. If there is a new neurologic deficit, imaging should be guided by concern for cerebrovascular disease, not that the individual has a headache. (97,98)
Definitions
MoCA – The Montreal Cognitive Assessment (MoCA) was designed as a rapid screening instrument for mild cognitive dysfunction. It assesses different cognitive domains: attention and concentration, executive functions, memory, language, visuoconstructional skills, conceptual thinking, calculations, and orientation. MoCA differs from the MMSE mainly by including tests of executive function and abstraction, and by putting less weight on orientation to time and place. Ten of the MMSE's 30 points are scored solely on the time- place orientation test, whereas the MoCA assigns it a maximum of six points. The MoCA also puts more weight on recall and attention-calculation performance, while de-emphasizing language skill. Time to administer the MoCA is approximately 10 minutes. The total possible score is 30 points; a score of 26 or above is considered normal.
CT and developmental delay – Significant developmental delay is defined as significant delay (more than two standard deviations below the mean) in one or more developmental domains: gross/fine motor, speech/language, cognition, social/personal, and activities of daily living. Isolated delay in social/language development is characteristic of autism spectrum disorders or hearing loss. Isolated delay in motor development is characteristic of cerebral palsy (a static encephalopathy) or myopathy. Global developmental delay (GDD) is a subset of developmental delay defined as significant delay (by at least 2 SD’s) in two or more developmental categories. Note that the term “GDD” is usually reserved for children < 5 years old, whereas in older children > 5 years, disability is quantifiable with IQ testing.
Leptomeningeal Carcinomatosis
Leptomeningeal Carcinomatosis (86,99,100,101) – Leptomeningeal metastasis is an uncommon and typically late complication of cancer with poor prognosis and limited treatment options. Diagnosis is often challenging with nonspecific presenting symptoms ranging from headache and confusion to focal neurologic deficits such as cranial nerve palsies. Standard diagnostic evaluation involves a neurologic examination, MRI of the brain and spine with gadolinium, and cytologic evaluation of the cerebral spinal fluid (CSF).
Hematologic malignancies (leukemia and lymphoma), primary brain tumors as well as solid malignancies can spread to the leptomeninges. The most common solid tumors giving rise to LM are breast cancer (12 - 35%), small and non-small cell lung cancer (10-26%), melanoma (5 -25%), gastrointestinal malignancies (4-14 %), and cancers of unknown primary (1-7%).
Drop Metastases
Drop Metastases – Drop metastases are intradural extramedullary spinal metastases that arise from intracranial lesions. Common examples of intracranial neoplasms that result in drop metastases include pineal tumors, ependymomas, medulloblastomas, germinomas, primitive neuroectodermal tumors (PNET), glioblastomas multiform, anaplastic astrocytomas, oligodendrogliomas and less commonly choroid plexus neoplasms and teratomas. (102)
Meningitis
CT scan and Meningitis – In suspected bacterial meningitis, CT with contrast may be performed before lumbar puncture (LP) to show preliminary meningeal enhancement. It is important to evaluate for a mass lesion or cause of elevated ICP that would contraindicate an LP. CT may be used to define the pathology of the base of the skull and that may require therapeutic intervention and surgical consultation. Some causes of an intracranial infection include fractures of the paranasal sinus and inner ear infection.
Normal Pressure Hydrocephalus
CT and Normal Pressure Hydrocephalus (NPH) – Although diagnosis can be made based on CT findings alone, MRI is more accurate for disclosing associated pathologies (such as cerebrovascular disease), excluding other potential etiologies, and for detecting NPH typical signs of prognostic value. A CT scan can exclude NPH and is appropriate for screening purposes and in individuals who cannot undergo MRI.
Macrocephaly
CT for Macrocephaly – Consider ultrasound in infants with macrocephaly and a normal neurological examination, no evidence of increased ICP and an open anterior fontanelle. If head US is normal, the infant should be monitored closely. (103) The anterior fontanelle generally closes between 10 and 24 months of age, with 3% closing between 5-9 months and 11% after 24 months. (104)
Congenital Abnormalities
CT scan for congenital abnormalities – While MRI is preferred to CT for evaluation of most congenital CNS abnormalities, in some clinical situations CT is preferred (craniosynostosis) or equivalent to MRI. CT is appropriate in the follow-up of hydrocephalus or VP shunt function where the etiology of hydrocephalus has been previously determined or in individuals for which MRI evaluation would require general anesthesia.
Anosmia
Anosmia – There is no relevant literature to support the use of CT head in the evaluation of the olfactory nerve.
Cranial Nerves
CT for evaluation of the cranial nerves – Magnetic resonance imaging (MRI) is considered the gold standard in the study and evaluation of the cranial nerves. Computed tomography (CT) allows, usually, an indirect view of the nerve and is useful to demonstrate the intraosseous segments of cranial nerves, the foramina through which they exit skull base, and their pathologic changes. In optic neuritis, CT has limited utility. Contrast-enhanced CT scanning of the orbits may help exclude other orbital pathology. CT scanning of the brain, regardless of whether intravenous contrast material is administered or not, does not yield prognostic and treatment-altering information. In Bell’s Palsy temporal bone CT is useful in the evaluation of the caliber and the course of the IAC and bony facial nerve canal in the temporal bone. When using CT to evaluate the facial nerve, pathology often can only be inferred by visualization of erosion or destruction of the adjacent bony facial nerve canal. In contrast, MRI visualizes soft tissues well and so is better suited for evaluating soft tissue facial nerve abnormalities.
Tumors
CT and tumors – MRI is the ideal modality to follow-up meningioma, pituitary tumors, low grade tumors, neurocutaneous syndromes, and staging/surveillance for non-CNS cancers. CT should only be used when MRI is contraindicated or is unable to be obtained.
Surveillance timelines should follow NCCN guidelines. Imaging is also warranted if the individual is symptomatic or there are new/changing signs or symptoms or complicating factors.
Head Trauma
CT scan for Head Trauma – Most types of head injury are minor injuries; clinical signs and symptoms help predict the need for brain CT following injury. CT has advantages in evaluating head injury due to its sensitivity for demonstrating mass effect, ventricular size and configuration, bone injuries, and acute hemorrhage. An individual who presents with certain clinical risk factors may be more likely to benefit from CT imaging. Some of the clinical risk factors that may be used as a guide to predict the probability of abnormal CT following minor head injury are vomiting, skull fracture, and age greater than 60 years.
Individuals with a Glasgow Coma Scale of 15 or less who also have been vomiting or have a suspected skull fracture are likely to show abnormal results on CT scan. CT is also useful in detecting delayed hematoma, hypoxic-ischemic lesions, or cerebral edema in the first 72 hours after head injury.
Central Venous Thrombosis
CT and Central Venous Thrombosis – A CTV or MRV is indicated for the definite evaluation of a central venous thrombosis/dural sinus thrombosis. The most frequent presentations are isolated headache, intracranial hypertension syndrome (headache, nausea/vomiting, transient visual obscurations, pulsatile tinnitus, CN VI palsy, papilledema),
(105) seizures, focal neurological deficits, and encephalopathy. Risk factors are hypercoagulable states inducing genetic prothrombotic conditions, antiphospholipid syndrome and other acquired prothrombotic diseases (such as cancer), oral contraceptives, pregnancy, puerperium (6-weeks postpartum), infections, and trauma. COVID-19 infection is associated with hypercoagulability, a thromboinflammatory response, and an increased incidence of venous thromboembolic events (VTE) (106,107). Since venous thrombosis can cause SAH, infarctions, and hemorrhage, parenchymal imaging with MRI/CT is also appropriate (21,108,109).
Stroke/TIA
Imaging for Stroke – Individuals presenting with symptoms of acute stroke should receive prompt imaging to determine whether they are candidates for treatment with tissue plasminogen activator. Non-contrast CT can evaluate for hemorrhage that would exclude the individual from reperfusion therapy. Functional imaging can be used to select individuals for thrombolytic therapy by measuring the mismatch between “infarct core” and “ischemic penumbra” and may define ischemic areas of the brain with the potential to respond positively to reperfusion therapy. Contrast-enhanced CT angiography (CTA) may follow the non-contrast CT imaging to identify areas of large vessel stenosis or occlusion which may be a target for therapy.
Recent stroke or transient ischemic attack – When revascularization therapy is not indicated or available in patients with an ischemic stroke or TIA, the focus of the work-up is on secondary prevention. Both stroke and TIA should have an evaluation for high-risk modifiable factors such as carotid stenosis atrial fibrillation as the cause of ischemic symptoms (110). Diagnostic recommendations include neuroimaging evaluation as soon as possible, preferably with magnetic resonance imaging, including DWI; noninvasive imaging of the extracranial vessels should be performed, and noninvasive imaging of intracranial vessels is reasonable. (111)
Patients with a history of stroke and recent work-up with new signs or symptoms indicating progression or complications of the initial CVA should have repeat brain imaging as an initial study. Patients with remote or silent strokes discovered on imaging should be evaluated for high-risk modifiable risk factors based on the location and type of the presumed etiology of the brain injury.
Neurological Deficits
Neurological Deficits – Examples of abnormal reflexes related to upper motor neuron lesion/central pathology include hyperreflexia, clonus, Hoffman sign and Babinski, snout, palmar grasp, and rooting reflexes.
Visual loss has many possible etiologies, and MRI or CT is only indicated in suspected neurological causes of visual loss based on history and exam. Visual field defects, such as bitemporal hemianopsia, homonymous hemianopsia, or quadranopsia, require imaging as well as does suspected optic nerve pathology. Subjective symptoms such as blurred vision or double vision with no clear correlate on neurological examination requires a comprehensive eye evaluation to exclude more common causes, such as cataracts, refractive errors, retinopathy, glaucoma, or macular degeneration. Transient visual loss with history consistent with TIA but normal exam at time of examination also should be imaged. Positive visual phenomena, such as photopsias or scintillations that march across the visual field, suggest migraine whereas negative phenomenon, such as shaded or blurred, is more characteristic of ischemia.
References
- American College of Radiology.ACR Appropriateness Criteria® Headache. 2022; 2023:
- Headache Classification Committee of the International Headache Society (IHS) The International Classification of Headache Disorders, 3rd edition. Cephalalgia. Jan 2018; 38: 1-211. 10.1177/0333102417738202.
- Micieli A, Kingston W. An Approach to Identifying Headache Patients That Require Neuroimaging. Front Public Health. 2019; 7: 52. 10.3389/fpubh.2019.00052.
- Mitsikostas D D, Ashina M, Craven A, Diener H C, Goadsby P J et al. European Headache Federation consensus on technical investigation for primary headache disorders. J Headache Pain. 2016; 17: 5. 10.1186/s10194-016-0596-y.
- González-Quintanilla V, Madera J, Pascual J. Update on headaches associated with physical exertion. Cephalalgia. 2023; 43: true. 10.1177/03331024221146989.
- Ray J,Hutton E. Imaging in headache disorders. Australian prescriber. 2022; 45: 88-92.
- Togha M, Karimitafti M, Ghorbani Z, Farham F, Naderi-Behdani F et al. Characteristics and comorbidities of headache in patients over 50 years of age: a cross-sectional study. BMC Geriatrics. 2022; 22: true. 10.1186/s12877-022-03027-1.
- Hayes L, Palasis S, Bartel T, Booth T, Iyer R et al. ACR Appropriateness Criteria - Child. Journal of the American College of Radiology. 2018; 15: S78 - S90. 10.1016/j.jacr.2018.03.017.
- Trofimova A, Vey B, Mullins M, Wolf D, Kadom N. Imaging of Children with Nontraumatic Headaches. AJR Am J Roentgenol. Jan 2018; 210: 8-17. 10.2214/ajr.17.18561.
- American College of Radiology. American College of Radiology Appropriateness Criteria: Dizziness and Ataxia. 2023.
- Harvey H, Watson L, Subramaniam R, Burns J, Bykowski J et al. ACR Appropriateness Criteria Movement Disorders and Neurodegenerative Diseases. Journal of the American College of Radiology. 2020; 17: S175 - S187. 10.1016/j.jacr.2020.01.042.
- Kennedy T, Corey A, Policeni B, Agarwal V, Burns J et al. ACR Appropriateness Criteria; Orbits Vision and Visual Loss. Journal of the American College of Radiology. 2018; 15: S116 - S131. 10.1016/j.jacr.2018.03.023.
- Sharma A, Kirsch C, Aulino J, Chakraborty S, Choudhri A et al. ACR Appropriateness Criteria Hearing Loss and/or Vertigo. Journal of the American College of Radiology. 2018; 15: S321 - S331. 10.1016/j.jacr.2018.09.020.
- American College of Radiology. American College of Radiology Appropriateness Criteria: Altered Mental Status, Coma, Delirium and Psychosis. 2024.
- American College of Radiology. American College of Radiology Appropriateness Criteria: Cerebrovascular Disease - Stroke and Stroke-Related Conditions. 2023.
- American College of Radiology. ACR Appropriateness Criteria® Cerebrovascular Disease-Child. 2019; 2023:
- Thust S, Burke C, Siddiqui A. Neuroimaging findings in sickle cell disease. Br J Radiol. Aug 2014; 87: 20130699. 10.1259/bjr.20130699.
- DeBaun M, Jordan L, King A, Schatz J, Vichinsky E et al. American Society of Hematology 2020 guidelines for sickle cell disease: prevention, diagnosis, and treatment of cerebrovascular disease in children and adults. Blood Adv. 2020; 4: 1554 - 1588. 10.1182/bloodadvances.2019001142.
- DeBaun M, Jordan L, King A, Schatz J, Vichinsky E et al. American Society of Hematology 2020 guidelines for sickle cell disease: prevention, diagnosis, and treatment of cerebrovascular disease in children and adults. Blood Adv. Apr 28, 2020; 4: 1554-1588. 10.1182/bloodadvances.2019001142.
- Ledbetter L, Burns J, Shih R, Ajam A, Brown M et al. ACR Appropriateness Criteria Cerebrovascular Diseases-Aneurysm, Vascular Malformation, and Subarachnoid Hemorrhage. Journal of the American College of Radiology. 2021; 18: S283 - S304. 10.1016/j.jacr.2021.08.012.
- Ferro J, Canhão P, Aguiar de Sousa D. Cerebral venous thrombosis. Presse Med. Dec 2016; 45: e429-e450. 10.1016/j.lpm.2016.10.007.
- American College of Radiology. ACR Appropriateness Criteria® Head Trauma.2020; 2023:
- Polinder S, Cnossen M, Real R, Covic A, Gorbunova A et al. A Multidimensional Approach to Post-concussion Symptoms in Mild Traumatic Brain Injury. Front Neurol. 2018; 9: 1113. 10.3389/fneur.2018.01113.
- Alrajhi K, Perry J, Forster A. Intracranial bleeds after minor and minimal head injury in patients on warfarin. J Emerg Med. Feb 2015; 48: 137-42. 10.1016/j.jemermed.2014.08.016.
- NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines): Central Nervous System Cancers Version 2.2022. September 29, 2022; 2023:
- Gomez C, Schiffman S, Bhatt A. Radiological review of skull lesions. Insights Imaging. Oct 2018; 9: 857-882. 10.1007/s13244-018-0643-0.
- Go R, Jacobsen E, Baiocchi R, Buhtoiarov I, Butler E et al. Histiocytic Neoplasms, Version 2.2021, NCCN Clinical Practice Guidelines in Oncology. J Natl Compr Canc Netw. Nov 2021; 19: 1277-1303. 10.6004/jnccn.2021.0053.
- Goyal G, Young J, Koster M, Tobin W, Vassallo R et al. The Mayo Clinic Histiocytosis Working Group Consensus Statement for the Diagnosis and Evaluation of Adult Patients with Histiocytic Neoplasms: Erdheim-Chester Disease, Langerhans Cell Histiocytosis, and Rosai-Dorfman Disease. Mayo Clin Proc. Oct 2019; 94: 2054-2071. 10.1016/j.mayocp.2019.02.023.
- Cendes F, Theodore W, Brinkmann B, Sulc V, Cascino G. Neuroimaging of epilepsy. Handb Clin Neurol. 2016; 136: 985-1014. 10.1016/b978-0-444-53486-6.00051-x.
- American College of Radiology. ACR Appropriateness Criteria®Seizures and Epilepsy. 2019; 2023:
- Trofimova A, Milla S, Ryan M, Pruthi S, Blount J et al. ACR Appropriateness Criteria Seizures- Child. Journal of the American College of Radiology. 2021; 18: S199 - S211. 10.1016/j.jacr.2021.02.020.
- Saberi A, Roudbary S, Ghayeghran A, Kazemi S, Hosseininezhad M. Diagnosis of Meningitis Caused by Pathogenic Microorganisms Using Magnetic Resonance Imaging: A Systematic Review. BCN. 2018; 9: 73 - 86. 10.29252/nirp.bcn.9.2.73.
- Godasi R, Pang G, Chauhan S, Bollu P. Primary Central Nervous System Vasculitis. StatPearls. October 12, 2022; 2023:
- Health Quality Ontario. The appropriate use of neuroimaging in the diagnostic work-up of dementia: an evidence-based analysis. Ont Health Technol Assess Ser. 2014; 14: 1-64.
- Narayanan L, Murray A. What can imaging tell us about cognitive impairment and dementia? World J Radiol. Mar 28, 2016; 8: 240-54. 10.4329/wjr.v8.i3.240.
- Carpenter C, Bassett E, Fischer G, Shirshekan J, Galvin J. Four sensitive screening tools to detect cognitive dysfunction in geriatric emergency department patients: brief Alzheimer’s Screen, Short Blessed Test, Ottawa 3DY, and the caregiver-completed AD8. Acad Emerg Med. Apr 2011; 18: 374-84. 10.1111/j.1553-2712.2011.01040.x.
- McDougall G. A review of screening instruments for assessing cognition and mental status in older adults. Nurse Pract. Nov 1990; 15: 18-28.
- Sharifi S, Nederveen A, Booij J, van Rootselaar A. Neuroimaging essentials in essential tremor: a systematic review. Neuroimage Clin. 2014; 5: 217-31. 10.1016/j.nicl.2014.05.003.
- Comella CL, National Organization forRare Disorders. Cervical Dystonia. 2019; 2023:
- Iliescu D, Timaru C, Alexe N, Gosav E, De Simone A et al. Management of diplopia. Rom J Ophthalmol. Jul-Sep 2017; 61: 166-170. 10.22336/rjo.2017.31.
- Yoon L, Kim H, Kwak M, Park K, Bae M et al. Utility of Magnetic Resonance Imaging (MRI) in Children with Strabismus. J Child Neurol. Sep 2019; 34: 574-581. 10.1177/0883073819846807.
- Sadaka A, Schockman S, Golnik K. Evaluation of Horner Syndrome in the MRI Era. Journal of Neuro-Ophthalmology. 2017; 37:
- American College of Radiology.ACR Appropriateness Criteria® Cranial Neuropathy. 2022; 2023:
- King R, Reiss J. The epidemiology and pathophysiology of pseudobulbar affect and its association with neurodegeneration. Degener Neurol Neuromuscul Dis. 2013; 3: 23-31. 10.2147/dnnd.S34160.
- Tan A, Mankad K, Gonçalves F, Talenti G, Alexia E. Macrocephaly: Solving the Diagnostic Dilemma. Top Magn Reson Imaging. Aug 2018; 27: 197-217. 10.1097/rmr.0000000000000170.
- Hanzlik E, Gigante J. Microcephaly. 2017; 4: 10.3390/children4060047.
- Rossi A, Argyropoulou M, Zlatareva D, Boulouis G, Pizzini F et al. European recommendations on practices in pediatric neuroradiology: consensus document from the European Society of Neuroradiology (ESNR), European Society of Paediatric Radiology (ESPR) and European Union of Medical Specialists Division of Neuroradiology (UEMS). Pediatric Radiology. 2023; 53: 159 - 168. 10.1007/s00247-022-05479-4.
- Kim H, Roh H, Lee I. Craniosynostosis: Updates in Radiologic Diagnosis. Journal of Korean Neurosurgical Society. 2016; 59: 219-26.
- Kubota T, Adachi M, Kitaoka T, Hasegawa K, Ohata Y et al. Clinical Practice Guidelines for Achondroplasia. Clin Pediatr Endocrinol. 2020; 29: 25-42. 10.1297/cpe.29.25.
- Cerebral palsy in under 25s: assessment and management. January 25, 2017; 2023:
- National Organization for Rare Disorders. Chiari Malformations. 2014; 2023:
- Whitson W, Lane J, Bauer D, Durham S. A prospective natural history study of nonoperatively managed Chiari I malformation: does follow-up MRI surveillance alter surgical decision making? J Neurosurg Pediatr. Aug 2015; 16: 159-66. 10.3171/2014.12.Peds14301.
- Damasceno B. Neuroimaging in normal pressure hydrocephalus. Dement Neuropsychol. Oct-Dec 2015; 9: 350-355. 10.1590/1980-57642015dn94000350.
- Kamenova M, Rychen J, Guzman R, Mariani L, Soleman J. Yield of early postoperative computed tomography after frontal ventriculoperitoneal shunt placement. PLoS One. 2018; 13: e0198752. 10.1371/journal.pone.0198752.
- Wetzel J, Heaner D, Gabel B, Tubbs R, Chern J. Clinical evaluation and surveillance imaging of children with myelomeningocele and shunted hydrocephalus: a follow-up study. J Neurosurg Pediatr. Oct 19, 2018; 23: 153-158. 10.3171/2018.7.Peds1826.
- Khalatbari H, Parisi M. Management of Hydrocephalus in Children: Anatomic Imaging Appearances of CSF Shunts and Their Complications. American Journal of Roentgenology. 2020; 216: 187 - 199. 10.2214/AJR.20.22888.
- Severson M,Strecker-McGraw M. Cerebrospinal Fluid Leak. StatPearls. August 8, 2022; 2023:
- Hiremath S, Gautam A, Sasindran V, Therakathu J, Benjamin G. Cerebrospinal fluid rhinorrhea and otorrhea: A multimodality imaging approach. Diagn Interv Imaging. Jan 2019; 100: 3-15. 10.1016/j.diii.2018.05.003.
- Deline C, Schievink WI, National Organization for Rare Disorders. Spontaneous Intracranial Hypotension. September 1, 2020; 2023:
- Garde A, Gibson N, Samuels M, Evans H. Recent advances in paediatric sleep disordered breathing. Breathe. 2022; 18: true. 10.1183/20734735.0151-2022.
- Brignole M, Moya A, de Lange F, Deharo J, Elliott P et al. 2018 ESC Guidelines for the diagnosis and management of syncope. Eur Heart J. 2018; 39: 1883 - 1948. 10.1093/eurheartj/ehy037.
- Hatharasinghe A, Etebar K, Wolsky R, Akhondi H, Ayutyanont N. An Assessment of the Diagnostic Value in Syncope Workup: A Retrospective Study. HCA healthcare journal of medicine. 2021; 2: 423-431.
- Venkatesan T, Levinthal D, Tarbell S, Jaradeh S, Hasler W et al. Guidelines on management of cyclic vomiting syndrome in adults by the American Neurogastroenterology and Motility Society and the Cyclic Vomiting Syndrome Association. Neurogastroenterol Motil. Jun 2019; 31 Suppl 2: e13604. 10.1111/nmo.13604.
- Raucci U, Borrelli O, Di Nardo G, Tambucci R, Pavone P et al. Cyclic Vomiting Syndrome in Children. Frontiers in Neurology. 2020; 11:
- Garner H, Wessell D, Lenchik L, Ahlawat S, Baker J et al. ACR Appropriateness Criteria Soft Tissue Masses: 2022 Update. Journal of the American College of Radiology. 2023; 20: S234 - S245. 10.1016/j.jacr.2023.02.009.
- Zhang J, Li Y, Zhao Y, Qiao J. CT and MRI of superficial solid tumors. Quant Imaging Med Surg. Mar 2018; 8: 232-251. 10.21037/qims.2018.03.03.
- Kim H, An J, Woo J, Yoon R. Superficially Palpable Masses of the Scalp and Face: A Pictorial Essay. Journal of the Korean Society of Radiology. 2019; 80: 283-293.
- American College of Radiology. ACR Appropriateness Criteria® Acute Mental Status Change, Delirium, and New Onset Psychosis. 2018; 2023:
- Randhawa H, Bagale S, Umap R, Randhawa J. Brain Magnetic Resonance Imaging-Based Evaluation of Pediatric Patients With. Cureus. 2022; 14: e24051.
- Ali A, Syed N, Murthy G, Nori M, Abkari A et al. Magnetic resonance imaging (MRI) evaluation of developmental delay in pediatric patients. J Clin Diagn Res. Jan 2015; 9: Tc21-4. 10.7860/jcdr/2015/11921.5478.
- Tieder J, Bonkowsky J, Etzel R, Franklin W, Gremse D et al. Brief Resolved Unexplained Events (Formerly Apparent Life-Threatening Events) and Evaluation of Lower-Risk Infants: Executive Summary. Pediatrics. May 2016; 137: 10.1542/peds.2016-0591.
- Kleindorfer D, Towfighi A, Chaturvedi S, Cockroft K, Gutierrez J et al. 2021 Guideline for the Prevention of Stroke in Patients with Stroke and Transient Ischemic Attack: A Guideline from the American Heart Association/American Stroke Association. Stroke. 2021; 52: e364-e467. 10.1161/STR.0000000000000375.
- Pannell J, Corey A, Shih R, Austin M, Chu S et al. ACR Appropriateness Criteria® Cerebrovascular Diseases-Stroke and Stroke-Related Conditions. J Am Coll Radiol. 2023.
- Ledbetter L, Burns J, Shih R, Ajam A, Brown M et al. ACR Appropriateness Criteria® Cerebrovascular Diseases-Aneurysm, Vascular Malformation, and Subarachnoid Hemorrhage. J Am Coll Radiol. 2021; 18: S283-S304. https://doi.org/10.1016/j.jacr.2021.08.012.
- Utukuri P, Shih R, Ajam A, Callahan K, Chen D et al. ACR Appropriateness Criteria® Headache: 2022 Update. J Am Coll Radiol. 2023; 20: S70-S93. 10.1016/j.jacr.2023.02.018.
- International Headache Society. Headache Classification Committee of the International Headache Society (IHS) The International Classification of Headache Disorders, 3rd edition. Cephalalgia. 2018; 38: 1-211. 10.1177/0333102417738202.
- Robertson R, Palasis S, Rivkin M, Pruthi S, Bartel T et al. ACR Appropriateness Criteria® Cerebrovascular Disease-Child. J Am Coll Radiol. May 2020; 17: S36-s54. 10.1016/j.jacr.2020.01.036.
- Gonzalez N, Amin-Hanjani S, Bang O, Coffey C, Du R et al. Adult Moyamoya Disease and Syndrome: Current Perspectives and Future Directions: A Scientific Statement from the American Heart Association/American Stroke Association. Stroke. 2023; 54: e465-e479. 10.1161/STR.0000000000000443.
- Burton T, Bushnell C. Reversible Cerebral VasoconstrictionSyndrome. Stroke. 2019; 50: 2253-
2258. 10.1161/STROKEAHA.119.024416.
- Zuccoli G, Pipitone N, Haldipur A, Brown R J, Hunder G. Imaging findings in primary central nervous system vasculitis. Clin Exp Rheumatol. Jan-Feb 2011; 29: S104-9.
- Godasi R, Pang G, Chauhan S, Bollu P. Primary Central Nervous System Vasculitis [Updated 2023]. StatPearls Publishing. 2023.
- Radic J, Cochrane D. Choosing Wisely Canada: Pediatric Neurosurgery Recommendations. Paediatr Child Health. Sep 2018; 23: 383-387. 10.1093/pch/pxy012.
- Hidalgo J, Tork C, Varacallo M. Arnold-Chiari Malformation. StatPearls. 2024.
- Hatgaonkar A, Mahajan S, Hatgoankar K, Bandre G. MRI Insights in Chiari Malformation Type 1 and Variations With. Cureus. 2024; 16: e55676.
- Mohammad S, Osman N, Ahmed K. The value of CSF flow studies in the management of CSF disorders in children: a pictorial review. Insights Imaging. Jan 28, 2019; 10: 3. 10.1186/s13244-019- 0686-x.
- Wang N, Bertalan M, Brastianos P. Leptomeningeal metastasis from systemic cancer: Review and update on management. Cancer. Jan 1, 2018; 124: 21-35. 10.1002/cncr.30911.
- Behbehani R. Clinical approach to opticneuropathies. Clin Ophthalmol. Sep 2007; 1: 233-46.
- Margolin E. The swollen optic nerve: an approach to diagnosis and management. Pract Neurol. Aug 2019; 19: 302-309. 10.1136/practneurol-2018-002057.
- Holle D, Obermann M. The role of neuroimaging in the diagnosis of headache disorders. Ther Adv Neurol Disord. Nov 2013; 6: 369-74. 10.1177/1756285613489765.
- Quinones-Hinojosa A, Gulati M, Singh V, Lawton M. Spontaneous intracerebral hemorrhage due to coagulation disorders. Neurosurg Focus. Oct 15, 2003; 15: E3. 10.3171/foc.2003.15.4.3.
- Schaefer P, Miller J, Singhal A, Thrall J, Lee S. Headache: when is neurologic imaging indicated? J Am Coll Radiol. Aug 2007; 4: 566-9. 10.1016/j.jacr.2006.10.001.
- Wilbrink L, Ferrari M, Kruit M, Haan J. Neuroimaging in trigeminal autonomic cephalgias: when, how, and of what? Curr Opin Neurol. Jun 2009; 22: 247-53. 10.1097/wco.0b013e32832b4bb3.
- Jang Y, Cho E, Choi H, Kim S, Park H. Diagnostic Neuroimaging in Headache Patients: A Systematic Review and Meta-Analysis. Psychiatry Investig. Jun 2019; 16: 407-417. 10.30773/pi.2019.04.11.
- Spierings E. Acute, subacute, and chronic headache. Otolaryngol Clin North Am. Dec 2003; 36: 1095-107, vi. 10.1016/s0030-6665(03)00128-2.
- Tyagi A. New daily persistent headache. Ann Indian Acad Neurol. Aug 2012; 15: S62-5. 10.4103/0972-2327.100011.
- Hadjikhani N, Vincent M. Neuroimaging clues of migraine aura. J Headache Pain. Apr 3, 2019; 20: 32. 10.1186/s10194-019-0983-2.
- Nahas S. New Guidelines on Headache Imaging. January 8, 2020; 2023:
- Whitehead M, Cardenas A, Corey A, Policeni B, Burns J et al. ACR Appropriateness Criteria® Headache. J Am Coll Radiol. Nov 2019; 16: S364-s377. 10.1016/j.jacr.2019.05.030.
- Andersen B, Miranda C, Hatzoglou V, DeAngelis L, Miller A. Leptomeningeal metastases in glioma: The Memorial Sloan Kettering Cancer Center experience. Neurology. May 21, 2019; 92: e2483-e2491. 10.1212/wnl.0000000000007529.
- Clarke J, Perez H, Jacks L, Panageas K, Deangelis L. Leptomeningeal metastases in the MRI era. Neurology. May 4, 2010; 74: 1449-54. 10.1212/WNL.0b013e3181dc1a69.
- Maillie L, Salgado L, Lazarev S. A systematic review of craniospinal irradiation for leptomeningeal disease: past, present, and future. Clin Transl Oncol. Oct 2021; 23: 2109-2119. 10.1007/s12094-021-02615-8.
- Ahmed A. MRI features of disseminated drop metastases S Afr Med J. Jul 2008; 98: 522-3.
- Smith R, Leonidas J, Maytal J. The value of head ultrasound in infants with macrocephaly. Pediatr Radiol. Mar 1998; 28: 143-6. 10.1007/s002470050315.
- Pindrik J, Ye X, Ji B, Pendleton C, Ahn E. Anterior fontanelle closure and size in full-term children based on head computed tomography. Clin Pediatr (Phila). Oct 2014; 53: 1149-57. 10.1177/0009922814538492.
- Jensen R, Radojicic A, Yri H. The diagnosis and management of idiopathic intracranial hypertension and the associated headache. Ther Adv Neurol Disord. Jul 2016; 9: 317-26. 10.1177/1756285616635987.
- Connors J, Levy J. Thromboinflammation and the hypercoagulability of COVID-19. J Thromb Haemost. Jul 2020; 18: 1559-1561. 10.1111/jth.14849.
- Tu T, Goh C, Tan Y, Leow A, Pang Y et al. Cerebral Venous Thrombosis in Patients with COVID-19 Infection: A Case Series and Systematic Review. J Stroke Cerebrovasc Dis. Dec 2020; 29: 105379. 10.1016/j.jstrokecerebrovasdis.2020.105379.
- Bushnell C, Saposnik G. Evaluation and management of cerebral venous thrombosis. Continuum (Minneap Minn). Apr 2014; 20: 335-51. 10.1212/01.CON.0000446105.67173.a8.
- Coutinho J. Cerebral venous thrombosis. J Thromb Haemost. Jun 2015; 13 Suppl 1: S238-44. 10.1111/jth.12945.
- Kernan W, Ovbiagele B, Black H, Bravata D, Chimowitz M et al. Guidelines for the prevention of stroke in patients with stroke and transient ischemic attack: a guideline for healthcare professionals from the American Heart Association/American Stroke Association. Stroke. 2014; 45: 2160-236. 10.1161/STR.0000000000000024.
- Wintermark M, Sanelli P, Albers G, Bello J, Derdeyn C et al. Imaging recommendations for acute stroke and transient ischemic attack patients: A joint statement by the American Society of Neuroradiology, the American College of Radiology, and the Society of NeuroInterventional Surgery. AJNR Am J Neuroradiol. 2013; 34: E117-27. 10.3174/ajnr.A3690.
Coding Section
Code | Number | Description |
CPT | 70450 | Computed tomography, head or brain; without contrast material |
70460 | Computed tomography, head or brain; with contrast material(s) | |
70470 | Computed tomography, head or brain; without contrast material, followed by contrast material(s) and further sections |
Procedure and diagnosis codes on Medical Policy documents are included only as a general reference tool for each policy. They may not be all-inclusive.
This medical policy was developed through consideration of peer-reviewed medical literature generally recognized by the relevant medical community, U.S. FDA approval status, nationally accepted standards of medical practice and accepted standards of medical practice in this community, Blue Cross Blue Shield Association technology assessment program (TEC) and other nonaffiliated technology evaluation centers, reference to federal regulations, other plan medical policies, and accredited national guidelines.
"Current Procedural Terminology © American Medical Association. All Rights Reserved"
History From 2024 Forward