Response of treatment-naive brain metastases to stereotactic radiosurgery.

With improvements in survival for patients with metastatic cancer, long-term local control of brain metastases has become an increasingly important clinical priority. While consensus guidelines recommend surgery followed by stereotactic radiosurgery (SRS) for lesions >3 cm, smaller lesions (≤3 cm) treated with SRS alone elicit variable responses. To determine factors influencing this variable response to SRS, we analyzed outcomes of brain metastases ≤3 cm diameter in patients with no prior systemic therapy treated with frame-based single-fraction SRS. Following SRS, 259 out of 1733 (15%) treated lesions demonstrated MRI findings concerning for local treatment failure (LTF), of which 202 /1733 (12%) demonstrated LTF and 54/1733 (3%) had an adverse radiation effect. Multivariate analysis demonstrated tumor size (>1.5 cm) and melanoma histology were associated with higher LTF rates. Our results demonstrate that brain metastases ≤3 cm are not uniformly responsive to SRS and suggest that prospective studies to evaluate the effect of SRS alone or in combination with surgery on brain metastases ≤3 cm matched by tumor size and histology are warranted. These studies will help establish multi-disciplinary treatment guidelines that improve local control while minimizing radiation necrosis during treatment of brain metastasis ≤3 cm.

The history of neurosurgery at Baylor College of Medicine.

The development of neurosurgery at Baylor College of Medicine began with the medical school's relocation to the new Texas Medical Center in Houston in 1943. An academic service was organized in 1949 as a section of neurosurgery within Baylor's Department of Surgery. Soon the practice, led by Dr. George Ehni, evolved to include clinical services at Methodist, Jefferson Davis (forerunner of Ben Taub), Texas Children's, the Veterans Affairs, and the University of Texas MD Anderson Cancer Center hospitals. A neurosurgery residency program was established in 1954. As the clinical practice expanded, neurosurgery was upgraded from a section to a division and then to a department. It has been led by four chiefs/chairs over the past 60 years-Dr. George Ehni (1959-1979), Dr. Robert Grossman (1980-2004), Dr. Raymond Sawaya (2005-2014), and Dr. Daniel Yoshor (2015-2020). Since the 1950s, the department has drawn strength from its robust residency program, its research base in the medical school, and its five major hospital affiliates, which have largely remained unchanged (with the exception of Baylor St. Luke's Medical Center replacing Methodist in 2004). The recent expansion of the residency program to 25 accredited positions and the growing strength of relationships with the "Baylor five" hospitals affiliated with Baylor College of Medicine portend a bright future.

Stereotactic radiosurgery for metastatic brain tumors: a comprehensive review of complications.

OBJECT: Stereotactic radiosurgery (SRS) is commonly used to treat brain metastases. Complications associated with this treatment are underreported. The authors reviewed a large series of patients who underwent SRS for brain metastases to identify complications and factors predicting their occurrence. METHODS: Prospectively collected clinical data from 273 patients undergoing SRS for 1 or 2 brain metastases at The University of Texas M. D. Anderson Cancer Center between June 1993 and December 2004 were reviewed. Patients who had received prior treatment for their tumor, including whole-brain radiation, SRS, or surgery, were excluded from the study. Data on adverse neurological and nonneurological outcomes following treatment were collected. RESULTS: Three hundred sixteen lesions were treated. Complications were associated with 127 (40%) of 316 treated lesions. New neurological complications were associated with 101 (32%) of 316 lesions. The onset of seizure was the most common complication, occurring in 41 (13%) of 316 SRS cases. On multivariate analysis, progressing primary cancer (hazard ratio [HR]=2.4, 95% CI 1.6-3.6, p<0.001), tumor location in eloquent cortex (HR=2.3, 95% CI 1.6-3.4, p<0.001), and lower (<15 Gy) SRS dose (HR=2.1, 95% CI 1.1-4.2, p=0.04) were significantly associated with new complications. On multivariate analysis, a tumor location in the eloquent cortex (HR=2.5, 95% CI 1.6-3.8, p<0.001) and progressing primary cancer (HR=1.6, 95% CI 1.1-2.5, p=0.03) were significantly associated with new neurological complications. CONCLUSIONS: The authors showed that new neurological and nonneurological complications were associated with 40% of SRS treatments for brain metastases. Patients with lesions in functional brain regions have a significantly increased risk of treatment-related complications.

Incidence proportions of brain metastases in patients diagnosed (1973 to 2001) in the Metropolitan Detroit Cancer Surveillance System.

PURPOSE: Population-based estimates of the incidence of brain metastases are not generally available. The purpose of this study was to calculate population-based incidence proportions (IPs) of brain metastases from single primary lung, melanoma, breast, renal, or colorectal cancer. PATIENTS AND METHODS: Patients diagnosed with single primary lung, melanoma, breast, renal, or colorectal cancer (1973 to 2001) in the Metropolitan Detroit Cancer Surveillance System (MDCSS) were used for analysis. IP of brain metastases by primary site and variable of interest (race, sex, age at diagnosis of primary cancer, and Surveillance, Epidemiology, and End Results [SEER] stage of primary cancer) was calculated with 95% CIs. RESULTS: Total IP percentage (IP%) of brain metastases was 9.6% for all primary sites combined, and highest for lung (19.9%), followed by melanoma (6.9%), renal (6.5%), breast (5.1%), and colorectal (1.8%) cancers. Racial differences were seen with African Americans demonstrating higher IP% of brain metastases compared with other racial groups for most primary sites. IP% was significantly higher for female patients with lung cancer, and significantly higher for male patients with melanoma. The highest IP% of brain metastases occurred at different ages at diagnoses: age 40 to 49 years for primary lung cancer; age 50 to 59 years for primary melanoma, renal, or colorectal cancers; and age 20 to 39 for primary breast cancer. IP% significantly increased as SEER stage of primary cancer advanced for all primary sites. CONCLUSION: Total IP% of brain metastases was lower than previously reported, and it varied by primary site, race, sex, age at diagnosis of primary cancer, and SEER stage of primary cancer.

Hypofractionated radiotherapy for elderly or younger low-performance status glioblastoma patients: outcome and prognostic factors.

PURPOSE: To evaluate the outcome for elderly or younger poor prognosis glioblastoma patients treated with hypofractionated radiotherapy (HypoRT). METHODS AND MATERIALS: Retrospective review at The University of Texas M. D. Anderson Cancer Center identified 59 glioblastoma patients (median age 65 years) treated with HypoRT between 1988 and 2001 with 50 Gy given at 2.5 Gy/fraction/day in 20 fractions within 4 weeks. Classification was according to the Radiation Therapy Oncology Group recursive partitioning analysis and was Class IV in 11, V in 29, and VI in 19. Surgery consisted of gross total resection (n = 16), subtotal resection (n = 28), and biopsy only (n = 13). Two patients were treated presumptively on the basis of radiographic findings. Chemotherapy was given either as part of the initial treatment (n = 15) or for progression (n = 9). RESULTS: The median survival time for the entire study population was 7 months, and the median progression-free survival was 3.9 months. The median survival time for patients with Class IV, V, and VI was 11, 7, and 5 months, respectively. Concordance was found with Radiation Therapy Oncology Group-established recursive partitioning analysis class survival. Steroid requirements were not increased during RT compared with preoperatively and immediately postoperatively. Late complications of HypoRT were limited to 3 cases of radiation necrosis suggested by MRI, 2 of which were pathologically confirmed. CONCLUSION: HypoRT consisting of 50 Gy in 4 weeks can be used for selected GBM patients to reduce the overall treatment time of conventional RT by 33-39% without apparent increased toxicity or decrement in survival.

Extent of resection of glioblastoma revisited: personalized survival modeling facilitates more accurate survival prediction and supports a maximum-safe-resection approach to surgery.

PURPOSE: Approximately 12,000 glioblastomas are diagnosed annually in the United States. The median survival rate for this disease is 12 months, but individual survival rates can vary with patient-specific factors, including extent of surgical resection (EOR). The goal of our investigation is to develop a reliable strategy for personalized survival prediction and for quantifying the relationship between survival, EOR, and adjuvant chemoradiotherapy. PATIENTS AND METHODS: We used accelerated failure time (AFT) modeling using data from 721 newly diagnosed patients with glioblastoma (from 1993 to 2010) to model the factors affecting individualized survival after surgical resection, and we used the model to construct probabilistic, patient-specific tools for survival prediction. We validated this model with independent data from 109 patients from a second institution. RESULTS: AFT modeling using age, Karnofsky performance score, EOR, and adjuvant chemoradiotherapy produced a continuous, nonlinear, multivariable survival model for glioblastoma. The median personalized predictive error was 4.37 months, representing a more than 20% improvement over current methods. Subsequent model-based calculations yield patient-specific predictions of the incremental effects of EOR and adjuvant therapy on survival. CONCLUSION: Nonlinear, multivariable AFT modeling outperforms current methods for estimating individual survival after glioblastoma resection. The model produces personalized survival curves and quantifies the relationship between variables modulating patient-specific survival. This approach provides comprehensive, personalized, probabilistic, and clinically relevant information regarding the anticipated course of disease, the overall prognosis, and the patient-specific influence of EOR and adjuvant chemoradiotherapy. The continuous, nonlinear relationship identified between expected median survival and EOR argues against a surgical management strategy based on rigid EOR thresholds and instead provides the first explicit evidence supporting a maximum safe resection approach to glioblastoma surgery.

Neurosurgical rotations or clerkships in US medical schools.

OBJECT: Medical student exposure to neurosurgery is limited. To improve the educational interactions between neurosurgeons and medical students as well as neurosurgical medical student rotations or clerkships (NSCs) we must first understand the current status. METHODS: Two questionnaires were sent, one to every neurosurgery course coordinator or director at each US neurosurgery residency program (99 questionnaires) and one to the associated parent medical school dean's office (91 questionnaires), to assess the current status of NSCs and the involvement of neurosurgeons at their respective institutions. RESULTS: We received responses from 86 (87%) of 99 neurosurgery course coordinators or directors and 64 (70%) of 91 medical school deans' offices. Most NSCs do not have didactic lectures (53 [62%] of 86 NSCs), provide their medical students with a syllabus or educational handouts (53 [62%] of 86), or have a recommended/required textbook (77 [90%] of 86). The most common method of evaluating students in NSCs is a subjective performance evaluation. Of 64 medical school deans, 38 (59%) felt that neurosurgery should not be a required rotation. Neurosurgical rotations or clerkships are primarily offered to students in their 4th year of medical school, which may be too late for appropriate timing of residency applications. Only 21 (33%) of 64 NSCs offer neurosurgery rotations to 3rd-year students. CONCLUSIONS: There is significant room for improvement in the neurosurgeon-to-medical student interactions in both the NSCs and during the didactic years of medical school.