Brain metastases

Question 1

What is the most common intracranial tumor?

Answer 1

Brain met is the most common intracranial tumor (outnumber primary brain tumors 8:1).

Question 2

What is the annual incidence of brain mets in the United States?

Answer 2

170,000–200,000 cases/yr of brain mets in the United States, with development in up to 30% of pts with systemic cancer.

Question 3

Why is the incidence of brain mets increasing?

Answer 3

The incidence is increasing due to advancements in systemic therapy (improved extracranial control) with limited penetration of the blood–brain barrier in conjunction with increased utilization of MRI/surveillance imaging.

Question 4

What cancers are associated with hemorrhagic brain mets?

Answer 4

Hemorrhagic brain mets are most commonly associated with melanoma, RCC, and choriocarcinoma.

Question 5

What do the terms solitary and single brain met connote?

Answer 5

A solitary brain met is only 1 brain lesion and no other sites of Dz progression.
A single brain met is only 1 brain lesion in addition to other sites of met Dz.

Question 6

What cancers are most likely to metastasize to the brain?

Answer 6

Cancers associated with brain mets: lung (40%–50%), breast (15%), melanoma (10%)

Question 7

In what % of pts are brain mets the 1st manifestation of Dz?

Answer 7

5%–20% of pts present with brain mets from an unknown primary. Pts presenting with brain mets without a prior Dx of cancer most often have a
lung primary.

Question 8

Should Bx or resection be recommended if a new Dx of brain mets is suspected?

Answer 8

Yes. Bx should be considered in pts with a new Dx of brain mets as 11% of pts (6/54) enrolled in the 1st Patchell trial were found to have a primary brain tumor (3 pts) or inflammatory/infectious process (3 pts) despite MRI or CT
findings consistent with metastatic Dz. (Patchell R et al., NEJM 1990)

Question 9

What is the more common type of brain mets: single or multiple?

Answer 9

Most pts have multiple brain mets rather than a single lesion, with increased detection of small, multifocal lesions on MRI typically not appreciated on
CT.

Question 10

How do pts with brain mets present?

Answer 10

Presentation of pts with brain mets: Sx of ↑ ICP (HA, n/v), weakness, change in sensation, mental status changes, and seizure

Question 11

What is carcinomatous meningitis?

Answer 11

Carcinomatous meningitis is a clinical syndrome caused by leptomeningeal met with widespread involvement of the cerebral cortex. The Dx is associated with a poor prognosis.

Question 12

Where do most brain mets occur?

Answer 12

Most brain mets arise in the gray/white matter junction due to hematogenous dissemination with narrowing of blood vessels. (Delattre J et al., Arch Neurol 1988)

Question 13

Are most brain mets infra- or supratentorial?

Answer 13

The majority of brain mets are supratentorial.

Question 14

What is the distribution of brain mets within the brain?

Answer 14

The distribution of brain mets correlates with relative weight and blood flow:
Cerebral hemispheres: 80%
Cerebellum: 15%
Brainstem: 5%

Question 15

What is the overall median time from initial cancer Dx to development of brain mets?

Answer 15

The median overall time from initial cancer Dx to development of brain mets is 1 yr.

Question 16

Do most pts with brain mets die from their CNS Dz?

Answer 16

No. ∼30%–50% of pts with brain mets die from their CNS Dz.

Question 17

Describe the workup of a brain met.

Answer 17

Brain met workup: H&P focus on characterization of any neurologic Sx, evaluation for infectious causes (fever, CBC), careful neurologic exam, MRI brain +/– gadolinium, assessment for status of extracranial Dz, determination
of KPS, and neurosurgery consult

Question 18

What is the DDx for a new lesion in the brain?

Answer 18

Brain lesion DDx: mets, infection/abscess, hemorrhage, primary brain tumor, infarct, tumefactive demyelinating lesion, and RT necrosis

Question 19

What imaging features are suggestive of brain mets?

Answer 19

Imaging features suggestive of brain mets include lesions at gray/white matter junction, multiple lesions, ring-enhancing lesions, and significant vasogenic edema

Question 20

What is triple-dose gadolinium, and why is it used?

Answer 20

Triple-dose gadolinium: 0.3 mmol/kg. It is used to increase the sensitivity of MRI.

Question 21

Describe the RTOG recursive partitioning analysis (RPA) classes for brain mets. (Gaspar L et al., IJROBP 1997)

Answer 21

1: ≥70 <65, Primary controlled, and no extracranial
mets
2: ≥70 Either age >65, Or primary uncontrolled
3: <70

Question 22

What is the MS time for RTOG RPA classes I, II, and III?

Answer 22

Class I: 7.2 mos
Class II: 4.2 mos
Class III: 2.3 mos

Question 23

What is the Sperduto Index?

Answer 23

The Sperduto Index is a graded prognostic assessment based on age, KPS, #of brain mets, and the presence or absence of extracranial mets developed from an analysis of 1,960 pts in the RTOG database. Criteria is based on a point system:
0 points: age >60 yrs, KPS <70, >3 brain mets, presence of extracranial mets
0.5 points: age 50–59 yrs, KPS 70–80, 2 CNS mets
1 point: age <50 yrs, KPS 90–100, 1 CNS met, no extracranial mets

The sum of points predicts MS in mos:
0–1 point: 2.6 mos
1.5–2.5 points: 3.8 mos
3 points: 6.9 mos
3.5–4 points: 11 mos

Question 24

What is the Diagnosis Specific Graded Prognostic Assessment (DS-GPA)?

Answer 24

The DS-GPA is a graded prognostic assessment developed from a retrospective database of 4,259 eligible pts from 11 institutions with determination of significant prognostic factors based on the primary
histology. (Sperduto P et al., IJROBP 2010)

Question 25

What are the significant prognostic factors?

Answer 25

Non-small cell lung cancer (NSCLC)/small cell lung
cancer: age, KPS, presence of extracranial mets and number of brain mets
Renal cell/melanoma: KPS and the number of brain mets
Breast/GI: KPS

Question 26

In pts with untreated brain mets, what is the MS?

Answer 26

MS of untreated brain mets is 1 mo.

Question 27

What Tx may be used for brain mets?

Answer 27

Brain met Tx: steroids, Sg, fractionated RT (WBRT), and SRS

Question 28

In pts with brain mets treated with steroids alone, what is the MS?

Answer 28

MS in pts with brain mets treated with steroids alone is 2 mos.

Question 29

What randomized data investigated pt survival or QOL with the addition of WBRT to best supportive care?

Answer 29

The completed MRC Quartz trial was a randomized, noninferiority phase III trial investigating the role of optimal supportive care (OSC) + WBRT (4 Gy
× 5 fx) vs. OSC alone in pts with inoperable brain mets from NSCLC. The primary outcome measure was quality-adjusted life yrs (QALY). The trial did
not show a difference in QALY with the addition of WBRT to OSC—though conclusions related to the specific population examined in the trial. (Mulvenna P et al., Lancet 2016)

Question 30

What are some criticisms of the QUARTZ trial?

Answer 30

Potential bias toward enrollment of pts with poor PS (40% with KPS <70), and perceived shorter life expectancy, as MS was ∼2 mos compared to
historical WBRT trials of ∼4 months. Additionally, the WBRT dose/fractionation scheme is not routinely used in pts with perceived longer life expectancy, also suggesting there may have been a bias toward pts with
shorter life expectancy/poor PS.

Question 31

Why are steroids used for brain mets and how are they typically prescribed?

Answer 31

In pts with symptomatic brain mets, steroids reduce leakage from tumor vessels, therefore decreasing edema and mass effect. Steroid dose for newly
diagnosed brain mets: 4 mg dexamethasone q6hrs; may give initial loading dose of 10 mg. Other dosing regimens, such as dexamethasone 8 mg BID, are occasionally used to simplify dose scheduling. Moving the last dose to early afternoon or evening can sometimes help mitigate the insomnia side effect.

Question 32

What pharmacologic Tx should always accompany steroid Tx?

Answer 32

When prescribing steroids, also provide GI prophylaxis with a proton pump inhibitor or H2 blocker.

Question 33

Should anticonvulsants be used prophylactically?

Answer 33

No. In accordance with guidelines from the American Academy of Neurology, pts with newly diagnosed brain tumors should not be started on prophylactic anticonvulsants. (Glantz M et al., Neurology 2000) The 2010 guidelines from the American Association of Neurological Surgeons/Congress of Neurological Surgeons do not recommend routine prophylactic use of anticonvulsants. (Mikkelsen T et al., J Neurooncol 2010)

Question 34

Are there any randomized data on the dose for WBRT?

Answer 34

Yes. The RTOG conducted several RCTs from 1970–1995 of WBRT alone, assessing different fractionation schemes. The 1st 2 trials (RTOG 6901 and 7361) included >1,800 pts randomized to 40 Gy/20, 40 Gy/15, 30
Gy/15, 30 Gy/10, or 20 Gy/5. No significant difference was found in response rates, length of response, or OS. The MS in the 1st study was 4.1 mos and 3.4 mos in the 2nd. (Borgelt B et al., IJROBP 1980)

2 ultrarapid fractionation schemes were also tested on these studies and reported separately; 10 Gy/1 (RTOG 6901) and 12 Gy/2 (RTOG 7361) in 26 and 33 pts, respectively. These schedules were associated with worse toxicity and time to neurologic progression than the standard fractionation. (Borgelt B et al., IJROBP 1981)

2 studies showed no MS advantage to giving a higher total dose. RTOG 7606 randomized 255 pts to 30 Gy/10 vs. 50 Gy/20. MS was 4.1 and 3.9 mos, respectively. (Kurtz J et al., IJROBP 1981) RTOG 9104 randomized
429 pts to 30 Gy/10 vs. 54.4/1.6 Gy bid. MS was 4.5 mos in both arms. (Murray K et al., IJROBP 1997)

Question 35

What dose and fractionation schemes are considered standard for WBRT?

Answer 35

The most commonly utilized WBRT dose is 30 Gy/10. Pts with a good KPS and longer life expectancy may be treated to 37.5 Gy/15, 40 Gy/20, or 50 Gy/20. An alternative is 20 Gy/5 fx, particularly for pts with short prognosis.

Question 36

What % of brain met pts have Sx improvement with WBRT?

Answer 36

WBRT improves Sx from brain mets in ∼60% of cases.

Question 37

What is the rate of CR to WBRT for brain mets?

Answer 37

∼25% of pts have a CR to WBRT for brain mets.

Question 38

What data support Sg + RT rather than Bx + RT for brain mets?

Answer 38

The 1st Patchell study for brain mets randomized 48 pts with 1 brain met and KPS ≥70 to Sg + WBRT vs. Bx + WBRT. WBRT in both arms was 36 Gy in 3 Gy/fx. Pts treated with Sg had a longer MS (40 wks vs. 15 wks, p <0.01), longer functional independence (38 wks vs. 8 wks), and ↓LR (20% vs. 52%, p <0.02). (Patchell R et al., NEJM 1990)

Question 39

Did the Netherlands trial of WBRT +/- Sg support or refute the Patchell study?

Answer 39

The Noordijk study supported the findings of the 1st Patchell study. It randomized 63 pts to WBRT alone or Sg + WBRT. WBRT was 40 Gy in 2 Gy bid fx. Pts treated with Sg had improved MS (10 mos vs. 6 mos, p = 0.04)
and longer functional independence (7.5 mos vs. 3.5 mos, p = 0.06). (Noordijk E et al., IJROBP 1994)

Question 40

Does adj WBRT after surgical resection of a brain met improve OS?

Answer 40

No. Postop WBRT following resection of a brain met does not improve survival. In the 2nd Patchell study for brain mets, 95 pts following surgical resection of a single met were randomized to no further Tx or WBRT (50.4 Gy in 1.8 Gy/fx). WBRT decreased LR (10% vs. 46%), decreased the rate of any brain failure (18% vs. 70%), and decreased the rate of neurologic death
(14% vs. 44%) but did not significantly change MS (48 wks vs. 43 wks). (Patchell R et al., JAMA 1998)

Question 41

Why did the investigators in the Patchell study choose a nonstandard WBRT dose?

Answer 41

The dose and fractionation schedule were chosen to achieve 90% microscopic Dz control probability.

Question 42

What are the indications for surgical resection?

Answer 42

Single lesion amenable to resection, controlled or absent extracranial Dz, KPS >70, age <60 yo, life expectancy >2 mos, need for immediate relief of
neurologic Sx secondary to mass effect, need to establish a tissue Dx.

Question 43

Are there any current randomized studies that support the role of adj WBRT?

Answer 43

Yes. EORTC 22952 enrolled 359 pts with 1–3 brain mets s/p Sg or SRS randomized to no further Tx vs. WBRT (30 Gy in 3 Gy/fx). Adj WBRT reduced the 2-yr relapse rate both at initial sites (Sg: 59% to 27%; SRS: 31% to 19%) and new sites (Sg: 42% to 23%; SRS: 48% to 33%) with decreased rates of death secondary to intracranial progression (44% vs. 28%) without improvement in the duration of functional independence or OS. Pts
randomized to observation were more likely to require salvage therapy (51% vs. 16%). (Kocher M et al., JCO 2010)

Question 44

What is the rationale for SRS in the Tx of brain mets?

Answer 44

Spherical/pseudospherical target, generally noninfiltrative lesions (<3–4 cm) located along the gray–white junction (noneloquent regions), ability to deliver a higher dose than can be achieved with WBRT alone (improved LC),
Tx of unresectable lesions; also, reduced risk of neurocognitive decline depending on location of lesion(s).

Question 45

What was the 1st RCT study of WBRT +/- an SRS boost?

Answer 45

The 1st RCT of WBRT +/– an SRS boost was conducted at the University of Pittsburgh. 27 pts with KPS ≥70 and 2–4 mets ≤2.5 cm that were at least 5 mm from the chiasm were randomized to WBRT (30 Gy/12 fx) +/– a 16-Gy boost. The trial closed early b/c of significant difference in brain control. The SRS arm had a longer time to LF (36 mos vs. 6 mos, p = 0.0005) and longer
time to any brain failure (34 mos vs. 5 mos, p = 0.002) but no difference in OS (11 mos vs. 7.5 mos, p = 0.11). (Kondziolka D et al., IJROBP 1999)

Question 46

According to RTOG 9508, which pts had a survival advantage with the addition of an SRS boost to WBRT?

Answer 46

RTOG 9508 randomized 331 pts with 1–3 brain mets to WBRT + SRS boost vs. WBRT alone. WBRT on both arms was 37.5 Gy in 2.5 Gy/fx. The SRS boost dose was dependent on size in accordance with RTOG 9005. On
univariate analysis, the addition of SRS improved the MS for pts with a single brain met (6.5 mos vs. 4.9 mos, p = 0.39). On subgroup MVA, RPA class I pts had improved survival with the SRS boost, as did pts with a lung
cancer primary. (Andrews D et al., Lancet 2004)

Question 47

What is the main determinant in selecting the Rx dose for SRS Tx of a brain mets?

Answer 47

The SRS Rx dose for a brain met is determined by size in accordance with the results of RTOG 9005, a dose escalation study: 24 Gy if <2-cm diameter, 18 Gy if 2–3 cm, and 15 Gy if 3–4 cm. (Shaw H et al., IJROBP 1996)

Question 48

In the RTOG SRS dose escalation study, did pts rcv WBRT?

Answer 48

Yes. In RTOG 9005, an SRS dose escalation study, 64% of pts had recurrent brain mets (median prior dose of fractionated RT 30 Gy) while 36% of pts had recurrent primary brain tumors (median initial dose of 60 Gy).

Question 49

What retrospective data support the omission of upfront WBRT in pts treated with SRS for brain mets?

Answer 49

Sneed et al. compiled a database from 10 U.S. institutions to assess the effect of omitting upfront WBRT in pts treated with SRS for brain mets. 983 pts
were analyzed and excluded pts treated with Sg (159 pts) and pts with a >1- mo interval b/t WBRT and SRS (179 pts). Of 569 evaluable pts, 268 had SRS
alone and 301 had upfront WBRT + SRS. When adjusted for RPA class,there was no difference in survival. 37% of pts Tx with SRS alone rcvd salvage therapy (median 5.7 mos) vs. 7% of pts Tx with SRS + WBRT (median 8.0 mos). No LC data were provided. (IJROBP 2002)

Question 50

What data argue against omission of WBRT following SRS alone?

Answer 50

Regine et al. retrospectively analyzed 36 pts Tx with planned observation following SRS alone (median dose 20 Gy). With an MS of 9 mos, brain tumor recurrence occurred in 47% (17/16 pts) with 71% symptomatic at the
time of recurrence and 59% with a neurologic deficit. (IJROBP 2002)

Question 51

According to randomized data, what is the effect of delaying WBRT after SRS for pts with 1–4 brain mets?

Answer 51

JROSG99–1 showed that the omission of WBRT after SRS for 1–4 brain mets does not affect survival but increases the risk of intracranial relapse
(46% with SRS + WBRT vs. 76.4% with SRS alone) and thus increases the need for salvage Tx. (Aoyama H et al., JAMA 2006)

Question 52

What was the 1st randomized trial to assess the effect of delaying WBRT after SRS?

Answer 52

The 1st trial to assess the effect of delaying WBRT after SRS was JROSG99–1. 132 pts with 1–4 mets were randomized to SRS or WBRT + SRS. The SRS dose was based on size (lesions ≤2 cm to 22–25 Gy; lesions
>2 cm to 18–20 Gy) and randomization (30% SRS dose reduction for pts on the WBRT arm). The WBRT dose was 30 Gy in 10 fx. (Aoyama H et al., JAMA 2006)

Question 53

What prospective data support the omission of WBRT in pts treated with SRS alone?

Answer 53

Chang EL et al. randomized 58 pts with 1–3 brain mets (57% single) with KPS ≥70 to SRS alone vs. SRS + WBRT (30 Gy in 2.5 Gy/fx). SRS + WBRT resulted in a significant decline in 4-mo recall (24% vs. 52%) and median OS
(15 mos vs. 6 mos) as compared to SRS alone. Pts treated with SRS + WBRT experience improved 1-yr LC (100% vs. 67%) and 1-yr distant brain control (73% vs. 44%) with SRS alone pts requiring more frequent salvage therapy. (Lancet 2009)

Question 54

What are some criticisms of the Chang EL et al. trial?

Answer 54

Utilization of a single neurocognitive metric to assess learning and memory (HTLV-R) at a single time point (4 mos post-Tx); decreased survival in the SRS + WBRT group despite 100% 1-yr LC and improved neurologic DFS (73% vs. 27%); incomplete accrual (stopped early due to worse cognitive outcomes in the WBRT + SRS arm).

Question 55

What were the results of the NCCTG (Alliance) N0574 study investigating SRS +/- WBRT?

Answer 55

N0574 reported on 213 pts randomized to SRS alone vs. SRS + WBRT (30 Gy in 2.5 Gy/fx), and also found improved LC at 3 mos with the addition of
WBRT to SRS (97% vs. 75.3%). However, they also found no significant difference in OS b/t the 2 groups (10.4 mos with SRS alone vs. 7.4 mos), and additionally demonstrated improved QOL and less cognitive decline in the SRS alone group. This supports the recommendation for initial Tx of 1–3 newly diagnosed brain mets with SRS alone f/b close observation in order to preserve cognitive function. (Brown PD et al., JAMA 2016)

Question 56

Are there any data on SRS dosing with planned WBRT?

Answer 56

Yes. Retrospective data from the University of Kentucky showed that optimal control of brain mets ≤2 cm was achieved with SRS of 20 Gy + WBRT. Pts treated with >20 Gy SRS + WBRT had higher rates of grade 3–4
neurotoxicity. (Shehata M et al., IJROBP 2004)

Question 57

Are there any data comparing Sg + WBRT with SRS alone?

Answer 57

Yes. Retrospective data from Germany comparing RPA class I–II pts with 1–2 brain mets treated either with Sg + WBRT or SRS alone suggests that SRS is as effective. Of 206 pts treated from 1994–2006, 94 pts had SRS
alone (18–25 Gy), and 112 pts had resection + WBRT (30 Gy/10 or 40 Gy/20). At 12 mos, there was no difference in OS (∼50% in both groups), LC, or brain control. There was no difference according to the RPA group. (Rades D et al., Cancer 2007)

Question 58

What is the role for stereotactic body radiotherapy (SBRT)?

Answer 58

Large mets (>3 cm) and irregular shaped lesions correlate with inf outcomes and increased toxicity with SRS. Martens B et al. retrospectively analyzed
therapeutic results in 75 pts with 108 intracranial mets (48% rcvd primary SBRT while 52% were treated following prior WBRT) with a variety of dose
concepts (primary SBRT: 5 Gy × 6–7 fx and 6 Gy × 5 fx; recurrent SBRT 4 Gy × 7–10 fx and 5 Gy × 5–6 fx). A cumulative EQD2 (equivalent dose 2 Gy) of ≥35 Gy resulted in improved LC with acceptable toxicity. (Cancer
2012)

Question 59

Can pts treated with WBRT for brain mets be reirradiated?

Answer 59

Yes. Wong WW et al. reported on a series of 86 pts Tx with reirradiation (median dose 20 Gy) due to progressive brain mets (median initial dose 30
Gy). 70% experienced neurologic improvement (24% complete resolution; 47% partial resolution). (IJROBP 1996)

Question 60

What dose should be used for reirradiation after WBRT for brain mets?

Answer 60

The optimal dose for reirradiation after WBRT is unknown. 20 Gy in 10 fx is often used.

Question 61

How are the fields arranged for WBRT?

Answer 61

WBRT is delivered using opposed lat fields; a post gantry tilt of 3–5 degrees is used to avoid divergence into the eyes; and multileaf collimation or custom
blocks are used to ensure adequate coverage of the cribriform plate, temporal lobe, and brainstem while protecting the eyes, nasal cavity, and oral cavity.
The inf border is generally set at C1–2.

Question 62

Should Sg be used for recurrent tumors?

Answer 62

Yes. Retrospective data from MDACC have suggested that reoperation for recurrent brain mets can prolong survival and improve QOL. MVA revealed several negative prognostic factors: presence of systemic Dz, KPS <70, short time to recurrence (<4 mos), age ≥40 yrs, and breast and melanoma primaries. (Bindal R et al., J Neurosurg 1995)

Question 63

What is the advantage of tumor bed radiosurgery after brain met resection?

Answer 63

Retrospective data from the University of Sherbrooke in Canada have suggested that SRS to the tumor bed following resection for brain mets achieves LC rates that are comparable to WBRT but does not impact the
development of remote brain mets. 40 pts underwent resection → SRS at a median of 4 wks post resection. 73% achieved LC, and 54% developed new brain mets. (Mathieu D et al., Neurosurgery 2008)

Question 64

Are any prospective trials investigating the role of SRS vs. WBRT for resected metastatic brain Dz?

Answer 64

Yes, RTOG 1270 is an RCT open to accrual investigating the role of postop SRS boost to the surgical cavity vs. adj WBRT following surgical resection of intracranial mets. Interim analysis reported at the ASTRO 2016 annual meeting suggest equivalent survival with improved preservation of cognitive function with SRS, however greater long-term control of CNS mets with WBRT. The study is ongoing, and formal publication is awaited.

Question 65

Are professional guidelines available to provide Tx recommendations for pts with newly diagnosed brain mets?

Answer 65

Yes, ASTRO published an evidence-based guideline of Tx recommendations dependent on the goal of Tx (survival, LC, distant brain control, and neurocognitive function) and estimated prognosis. (PRO 2012)

Question 66

What is the recommended interval for surveillance imaging after Tx of brain mets?

Answer 66

MRI is generally recommended every 2–4 mos in pts with good PS and potential for salvage therapy if additional mets are identified.

Question 67

What are potential acute toxicities of WBRT?

Answer 67

Potential WBRT acute toxicities: alopecia, fatigue, HA, n/v, ototoxicity

Question 68

What are potential long-term toxicities of WBRT?

Answer 68

Potential WBRT chronic toxicities: thinned hair, decline in short-term memory, altered executive function, leukoencephalopathy, brain atrophy, normal pressure hydrocephalus, RT necrosis

Question 69

What is the relationship between WBRT-induced brain mets shrinkage and neurocognitive function?

Answer 69

WBRT-induced brain met shrinkage correlates with improved neurocognitive function. This was demonstrated in an analysis of 208 pts with brain mets randomized to WBRT alone on a phase III trial of WBRT +/– motexafin gadolinium. Pts with a good response to WBRT (>45% tumor volume reduction at 2 mos) had a longer time to decline in neurocognitive function.
(Li J et al., JCO 2007)

Question 70

What is the reported risk of severe dementia with WBRT?

Answer 70

DeAngelis L et al. reported an 11% (5 pts) risk of radiation-induced dementia in long-term brain mets survivors (>12 mos) based on a retrospective review
of 47 pts Tx with WBRT. 3 pts were treated with nonstandard fractionation, 1 pt rcvd concurrent Adr, and 1 pt rcvd 30 Gy in 3 Gy/fx with a radiosensitizer.
Of 15 pts Tx with <3 Gy/fx without systemic therapy, 0 developed severe dementia or neurocognitive Sx. (Neurosurgery 1989)

Question 71

What is the most important determinant of neurocognitive function?

Answer 71

The most important determinant is brain tumor control/delay of intracranial progression.

Question 72

What other factors contribute to neurocognitive decline?

Answer 72

Anticonvulsants, benzodiazepines, opioids, chemo, surgical intervention (craniotomy), and systemic progression of Dz

Question 73

What daily fx size in WBRT is associated with RT necrosis?

Answer 73

WBRT administered in fx sizes >3 Gy/day are associated with RT necrosis. (DeAngelis L et al., Neurology 1989)

Question 74

Name the potential acute toxicities of SRS for brain mets.

Answer 74

Potential acute toxicities of SRS for brain mets: HA, nausea, dizziness/vertigo, seizure

Question 75

What is the risk of symptomatic RT necrosis after SRS for brain mets?

Answer 75

There is an ∼5% risk of symptomatic RT necrosis secondary to SRS for brain mets. This is usually treated with steroids but may require Sg or bevacizumab
for refractory cases.

Question 76

What are the dose limits to critical structures with SRS?

Answer 76

Brainstem 12.5 Gy, optic chiasm or optic nerves 10 Gy, other cranial nerves 12 Gy