PURPOSE: Although conventional neuro-navigation is a useful tool for image-guided glioma surgery, there are some limitations, such as brain shift. We introduced our methods using an identifiable marker, a "tailed bullet", to overcome the limitation of conventional neuro-navigation. A tailed bullet is an identifiable tumor location marker that determines the extent of a resection and we have introduced our technique and reviewed the clinical results. MATERIALS AND METHODS: We have developed and used "tailed bullets" for brain tumor surgery. They were inserted into the brain parenchyma or the tumor itself to help identify the margin of tumor. We retrospectively reviewed surgically resected glioma cases using "tailed bullet". Total 110 gliomas included in this study and it contains WHO grade 2, 3, and 4 glioma was 14, 36, and 60 cases, respectively. RESULTS: Gross total resection (GTR) was achieved in 71 patients (64.5%), subtotal resection in 36 patients (32.7%), and partial resection in 3 patients (2.7%). The overall survival (OS) duration of grade 3 and 4 gliomas were 20.9 (range, 1.2-82.4) and 13.6 months (range, 1.4-173.4), respectively. Extent of resection (GTR), younger age, and higher initial Karnofsky Performance Status (KPS) score were related to longer OS for grade-4 gliomas. There was no significant adverse event directly related to the use of tailed bullets. CONCLUSION: Considering the limitations of conventional neuro-navigation methods, the tailed bullets could be helpful during glioma resection. We believe this simple method is an easily accessible technique and overcomes the limitation of the brain shift from the conventional neuro-navigation. Further studies are needed to verify the clinical benefits of using tailed bullets.
Adult ; Aged ; Brain/pathology ; Brain Neoplasms/pathology/*surgery ; Female ; Glioma/pathology/*surgery ; Humans ; Karnofsky Performance Status ; Magnetic Resonance Imaging, Interventional ; Male ; Middle Aged ; Neuronavigation/*methods ; Retrospective Studies ; Surgery, Computer-Assisted/*methods ; Survival Rate ; Time Factors ; Treatment Outcome

PURPOSE: To achieve maximal safe resection during brain tumor surgery, functional image-merged neuronavigation is widely used. We retrospectively reviewed our cases in which diffusion tensor image (DTI)-merged functional neuronavigation was performed during surgery. MATERIALS AND METHODS: Between November 2008 and May 2010, 123 patients underwent surgery utilizing DTI-merged neuronavigation. Anatomical magnetic resonance images (MRI) were obtained preoperatively and fused with DTI of major white matter tracts, such as the corticospinal tract, optic radiation, or arcuate fasciculus. We used this fused image for functional neuronavigation during brain tumor surgery of eloquent areas. We checked the DTI images together with postoperative MRI images and evaluated the integrity of white matter tracts. RESULTS: A single white matter tract was inspected in 78 patients, and two or more white matter tracts were checked in 45 patients. Among the 123 patients, a grossly total resection was achieved in 90 patients (73.2%), subtotal resection in 29 patients (23.6%), and partial resection in 4 patients (3.3%). Postoperative neurologic outcomes, compared with preoperative function, included the following: 100 patients (81.3%) displayed improvement of neurologic symptoms or no change, 7 patients (5.7%) experienced postoperative permanent neurologic deterioration (additional or aggravated neurologic symptoms), and 16 patients (13.0%) demonstrated transient worsening. CONCLUSION: DTI-merged functional neuronavigation could be a useful tool in brain tumor surgery for maximal safe resection. However, there are still limitations, including white matter tract shift, during surgery and in DTI itself. Further studies should be conducted to overcome these limitations.
Adolescent ; Adult ; Aged ; Brain Neoplasms/pathology/*surgery ; *Diffusion Tensor Imaging ; Female ; Humans ; Magnetic Resonance Imaging ; Male ; Middle Aged ; *Neuronavigation ; Neurosurgical Procedures/*methods ; Postoperative Period ; Preoperative Period ; Retrospective Studies

OBJECTIVETo evaluate the feasibility, reliability and accuracy of the automated magnetic resonance spectroscopy ((1)H-MRS) guided frameless brain biopsy with intraoperative magnetic resonance imaging (iMRI).

METHODSBetween July 2011 and July 2013, a consecutive series of 93 patients were prospectively enrolled. All the patients had intracranial lesions which need biopsy to confirm the diagnosis. Among them, 48 patients were male, 45 patients were female. Their age range from 7 years to 76 years, the median age was 47 years. All patients underwent MRS examination. With MRS automatic fusion technique, the metabolic images were integrated into a standard navigation system (Vario Guide) to guide frameless biopsy. High-field iMRI (1.5 T) was used for target inspection, brain shift correction, and intra-operative exclusion of intra-cerebral hemorrhage and other complications.

RESULTSFor all the 93 patients, (1)H-MRS based metabolic images could be automatically integrated into a standard navigation system and average fusion procedure could be taken 5 minutes 6 seconds. For (1)H-MRS guided stereotactic biopsy of intracranial lesions, the diagnosis yield rate was 94.6% (88/93). Four cases did not get a clear pathological diagnosis, while 1 case did not match the pathological diagnosis result which obtained by following craniotomy. Technical related complication rate was 2.2% (2 cases, intra-cerebral hemorrhage), which were intra-operatively depicted with iMRI, and managed properly. Among them, 1 case with small volume (5 ml) intracerebral hematoma fully recovered 10 days after surgery without second surgical intervention. One case with large volume intracerebral hematoma (32 ml) was depicted with iMRI, followed by craniotomy and hematoma evacuation in the same session. This case had no new or worsened neurologic deficit post-operatively.

CONCLUSIONS(1)H-MRS based metabolic imaging can be automatically integrated into a standard navigation system and used for frameless brain biopsy. The target can be selected according to the metabolic status of the lesion. Hence, the target can be more accurate. And the pathological diagnosis yield rate is higher. With iMRI, the method is safe, and has high clinical efficacy.

Adolescent ; Adult ; Aged ; Biopsy ; methods ; Brain ; pathology ; Brain Neoplasms ; pathology ; Child ; Female ; Humans ; Male ; Middle Aged ; Neuronavigation ; methods ; Prospective Studies ; Proton Magnetic Resonance Spectroscopy ; Stereotaxic Techniques ; Young Adult

OBJECTIVETo study the techniques and efficacy of neuronavigation-guided puncture and drainage in the treatment of brain abscesses.

METHODSFrom February 2006 to December 2012, 31 patients with brain abscesses treated by the technique of neuronavigation-guided puncture and drainage were retrospectively analyzed. There were 27 male and 4 female patients, age ranged from 10 months to 69 years, average (34 ± 19) years.Single brain abscesses were found in 26 patients, multiple abscesses in 5 patients. The abscesses were located in eloquent regions in 19 patients. The mean diameter of the abscess was 4.1 cm (2.5-6.7 cm). The first follow-up visit was on the first month after surgery, and if residual was observed on enhanced MRI, then the patient was followed up every 3 months until the abscess disappeared completely. After residual absorbed, the patient was followed up every year.

RESULTSIncisions of all patients were healed well and no infection. The length of hospital stay after surgery was 6-42 days, mean (14 ± 9) days. Bacterial culture of pus was performed regularly including aerobic, anaerobic and fungal culture after surgery. Thirteen patients had positive culture whereas the other 18 patients had negative culture. The duration of antibiotic use was 18-42 days, mean (22 ± 5) days. All the patients were followed up for 3 months to 3 years. Twenty-nine patients recovered well postoperatively, 1 case died 2 months after operation.One case was performed the second drainage after 10 days from the first surgery.Eighteen patients showed the improvement of neurological status within the first day following surgery, 4 patients got improvement in the next day, 1 patient with hemiplegia showed improvement in 10 days postoperatively, 1 patient with aphasia recovered gradually after 1 month, 1 patient with hemiplegia showed deterioration temporarily after surgery, and recovered gradually after 15 days.

CONCLUSIONThe technique of puncture and drainage guided by neuronavigation has many advantages to treat brain abscesses, such as small trauma, short operation time, high accuracy and safety, simple surgical procedures and good prognosis.

Adolescent ; Adult ; Aged ; Brain Abscess ; therapy ; Child ; Child, Preschool ; Drainage ; methods ; Female ; Humans ; Infant ; Male ; Middle Aged ; Neuronavigation ; Retrospective Studies ; Young Adult

The biggest challenge in neuro-oncology is the treatment of glioblastoma, which exhibits poor prognosis and is increasing in incidence in an increasing aging population. Diverse treatment strategies aim at maximum cytoreduction and ensuring good quality of life. We discuss multimodal neuronavigation, supra-maximum tumor resection, and the postoperative treatment gap. Multimodal neuronavigation allows the integration of preoperative anatomic and functional data with intraoperative information. This approach includes functional magnetic resonance imaging (MRI) and diffusion tensor imaging in preplanning and ultrasound, computed tomography (CT), MRI and direct (sub)cortical stimulation during surgery. The practice of awake craniotomy decreases postoperative neurologic deficits, and an extensive supra-maximum resection appears to be feasible, even in eloquent areas of the brain. Intraoperative MRI- and fluorescence-guided surgery assist in achieving this goal of supra-maximum resection and have been the subject of an increasing number of reports. Photodynamic therapy and local chemotherapy are properly positioned to bridge the gap between surgery and chemoradiotherapy. The photosensitizer used in fluorescence-guided surgery persists in the remaining peripheral tumor extensions. Additionally, blinded randomized clinical trials showed firm evidence of extra cytoreduction by local chemotherapy in the tumor cavity. The cutting-edge promise is gene therapy although both the delivery and efficacy of the numerous transgenes remain under investigation. Issues such as the choice of (cell) vector, the choice of therapeutic transgene, the optimal route of administration, and biosafety need to be addressed in a systematic way. In this selective review, we present various evidence and promises to improve survival of glioblastoma patients by supra-maximum cytoreduction via local procedures while minimizing the risk of new neurologic deficit.
Brain Mapping ; methods ; Brain Neoplasms ; diagnosis ; pathology ; surgery ; Conscious Sedation ; Diffusion Tensor Imaging ; Glioblastoma ; diagnosis ; pathology ; surgery ; Humans ; Magnetic Resonance Imaging ; Microsurgery ; Monitoring, Intraoperative ; Neuronavigation ; methods ; Neurosurgical Procedures ; methods ; Tomography, X-Ray Computed

BACKGROUNDImage-guided neurosurgery, endoscopic-assisted neurosurgery and the keyhole approach are three important parts of minimally invasive neurosurgery and have played a significant role in treating skull base lesions. This study aimed to investigate the potential usefulness of coupling of the endoscope with the far lateral keyhole approach and image guidance at the ventral craniocervical junction in a cadaver model.

METHODSWe simulated far lateral keyhole approach bilaterally in five cadaveric head specimens (10 cranial hemispheres). Computed tomography-based image guidance was used for intraoperative navigation and for quantitative measurements. Skull base structures were observed using both an operating microscope and a rigid endoscope. The jugular tubercle and one-third of the occipital condyle were then drilled, and all specimens were observed under the microscope again. We measured and compared the exposure of the petroclivus area provided by the endoscope and by the operating microscope. Statistical analysis was performed by analysis of variance followed by the Student-Newman-Keuls test.

RESULTSWith endoscope assistance and image guidance, it was possible to observe the deep ventral craniocervical junction structures through three nerve gaps (among facial-acoustical nerves and the lower cranial nerves) and structures normally obstructed by the jugular tubercle and occipital condyle in the far lateral keyhole approach. The surgical area exposed in the petroclival region was significantly improved using the 0° endoscope (1147.80 mm(2)) compared with the operating microscope ((756.28 ± 50.73) mm(2)). The far lateral retrocondylar keyhole approach, using both 0° and 30° endoscopes, provided an exposure area ((1147.80 ± 159.57) mm(2) and (1409.94 ± 155.18) mm(2), respectively) greater than that of the far lateral transcondylar transtubercular keyhole approach ((1066.26 ± 165.06) mm(2)) (P < 0.05).

CONCLUSIONSWith the aid of the endoscope and image guidance, it is possible to approach the ventral craniocervical junction with the far lateral keyhole approach. The use of an angled-lens endoscope can significantly improve the exposure of the petroclival region without drilling the jugular tubercle and occipital condyle.

Adult ; Endoscopes ; Humans ; Neuronavigation ; methods ; Skull Base ; anatomy & histology ; surgery ; Surgery, Computer-Assisted

OBJECTIVETo evaluate the efficacy of intraoperative magnetic resonance imaging (iMRI) and multimodal navigation in surgical resection of glioblastoma.

METHODSBetween February 2009 and July 2010, 76 glioblastoma patients underwent surgical resection guided by iMRI and multimodal navigation. The cohort consisted of 43 male and 33 female patients, with a mean age of 49 years (range: 14-79 years). Rates of gross total resection (GTR) and extent of resection (EoR) were calculated at first and final iMRI scans.Pearson χ(2) test was used to compare the rates of GTR.

RESULTSiMRI and multimodal navigation were successfully implemented in all cases. Rates of GTR were misestimated by neurosurgeons in 24 cases (31.6%), which were confirmed by first iMRI. Total tumor resection were achieved in 20 cases (26.3%) as a result of iMRI scan, increasing the rates of gross total resection from 52.6% to 78.9% (χ(2) = 11.692, P = 0.001). Extent of resection in 28 patients who underwent further tumor resection were increased from 81.5% to 98.1%, leading to the overall extent of resection improved from 92.3% to 98.4%. At 3-month follow-up, 3 cases (3.9%) developed permanent neurologic deficits. The mean clinical follow-up was 15.6 months (range 3.0-45.0 months). The 2-year overall survival rate was 19.7%. The median progression-free survival of gross total resection group was 12 months (95% CI: 10.1-13.9 months), compared with 9 months (95%CI: 7.9-10.1 months) of the subtotal resection group (χ(2) = 4.756, P = 0.029). The overall survival of gross total resection group was 16 months (95% CI: 13.7-18.3 months), compared with 12 months (95% CI: 9.7-14.3 months) of the subtotal resection group (χ(2) = 7.885, P = 0.005).

CONCLUSIONCombined with multimodal navigation, iMRI helps maximize surgical resection of glioblastoma, preserving neurological function while increasing progression-free survival and overall survival.

Adolescent ; Adult ; Aged ; Brain Neoplasms ; surgery ; Female ; Glioblastoma ; surgery ; Humans ; Magnetic Resonance Imaging ; Male ; Middle Aged ; Monitoring, Intraoperative ; methods ; Neuronavigation ; Young Adult

OBJECTIVESTo evaluate the efficacy of integration of metabolism images into multimodal neuronavigation for frameless stereotactic biopsy.

METHODSFrom January to December 2012, 32 patients with brain lesions underwent frameless stereotactic biopsy guided by positron emission tomograph (PET) and proton magnetic resonance spectroscopy ((1)H-MRS)-based multimodal neuronavigation and intraoperative magnetic resonance imaging (iMRI). The cohort consisted of 16 male and 16 female patients, with a mean age of 45 years (range: 7 - 62 years). Biopsy targets were identified according to PET and (1)H-MRS. Biopsy was performed with Varioguide frameless biopsy system. Diagnostic yield and complications were assessed.

RESULTSMetabolism images-based multimodal neuronavigation and iMRI were successfully implemented in all cases. iMRI confirmed accuracy of biopsy targets. All the specimens obtained pathological diagnosis, the diagnostic yield was 100%. In 1 patient, iMRI found small hematoma (< 5 ml), surgical evacuation wasn't needed with intraoperative complication rate 3.1%. With the help of multimodal neuronavigation, no patients had new or worsened neurologic deficits.

CONCLUSIONSIntegration of metabolism images into multimodal neuronavigation provide not only anatomical, but also metabolic and functional information for frameless stereotaxy, increasing diagnostic yield and avoiding postoperative neurologic deficits.

Adolescent ; Adult ; Biopsy ; methods ; Brain ; pathology ; Brain Neoplasms ; pathology ; Child ; Female ; Humans ; Magnetic Resonance Imaging ; Male ; Middle Aged ; Neuronavigation ; Positron-Emission Tomography ; Stereotaxic Techniques ; Young Adult

In order to increase the accuracy of image guided neurosurgery (IGNS), we developed a brain deformation corrective system (BDCS) based on linear elastic model. To investigate the fidelity of such a system, two cases of cerebral tumor resection were conducted in our paper. According to our experiments, the average shift error after craniotomy was reduced to (1.00 +/- 0.63)mm from (4. 97 +/- 3. 53)mm and the average prediction rate was (72.27 +/- 20.37)%. The results showed that the system was convenient and fast to operate and presented a promising pathway to compensating for brain deformation during neurosurgery.
Brain ; anatomy & histology ; surgery ; Brain Neoplasms ; surgery ; Humans ; Imaging, Three-Dimensional ; Magnetic Resonance Imaging ; Models, Neurological ; Neuronavigation ; Neurosurgery ; instrumentation ; methods ; Surgery, Computer-Assisted ; instrumentation ; methods

OBJECTIVETo review the history, development, and reality of neuronavigation surgery in China and to discuss the future of neuronavigation surgery.

DATA SOURCESPubMed, the China Knowledge Resource Integrated Database, and the VIP Database for Chinese Technical Periodicals were searched for papers published from 1995 to the present with the key words "neuronavigation," functional navigation," "image-guided," and "stereotaxy." Articles were reviewed for additional citations, and some information was gathered from Web searches.

STUDY SELECTIONArticles related to neuronavigation surgery in China were selected, with special attention to application to brain tumors.

RESULTSSince the introduction of neurosurgical navigation to China in 1997, this core technique in minimally invasive neurosurgery has seen rapid development. This development has ranged from brain structural localization to functional brain mapping, from static digital models of the brain to dynamic brain-shift compensation models, and from preoperative image-guided surgery to intraoperative real-time image-guided surgery, and from application of imported equipment and technology to use of equipment and technology that possess Chinese independent intellectual property rights.

CONCLUSIONSThe development and application of neuronavigation techniques have made neurological surgeries in China more safe, precise and effective, and less invasive, and promoted the quality of Chinese neurosurgical practice to the rank of the most advance and excellence in the world.

Animals ; Brain ; pathology ; China ; Humans ; Neuronavigation ; methods ; Neurosurgical Procedures ; methods