One of the impediments to the treatment of brain tumors (e.g., gliomas) has been the degree to which they expand, infiltrate surrounding tissue, and migrate widely into normal brain, usually rendering them “elusive” to effective resection, irradiation, chemotherapy, or gene therapy. We demonstrate that neural stem cells (NSCs), when implanted into experimental intracranial gliomas in vivo in adult rodents, distribute themselves quickly and extensively throughout the tumor bed and migrate uniquely in juxtaposition to widely expanding and aggressively advancing tumor cells, while continuing to stably express a foreign gene. The NSCs “surround” the invading tumor border while “chasing down” infiltrating tumor cells. When implanted intracranially at distant sites from the tumor (e.g., into normal tissue, into the contralateral hemisphere, or into the cerebral ventricles), the donor cells migrate through normal tissue targeting the tumor cells (including human glioblastomas). When implanted outside the CNS intravascularly, NSCs will target an intracranial tumor. NSCs can deliver a therapeutically relevant molecule—cytosine deaminase—such that quantifiable reduction in tumor burden results. These data suggest the adjunctive use of inherently migratory NSCs as a delivery vehicle for targeting therapeutic genes and vectors to refractory, migratory, invasive brain tumors. More broadly, they suggest that NSC migration can be extensive, even in the adult brain and along nonstereotypical routes, if pathology (as modeled here by tumor) is present.
This is the first controlled trial evaluating an entirely novel cancer treatment modality delivering electric fields rather than chemotherapy. No improvement in overall survival was demonstrated, however efficacy and activity with this chemotherapy-free treatment device appears comparable to chemotherapy regimens that are commonly used for recurrent glioblastoma. Toxicity and quality of life clearly favoured TTF.
Previous uncontrolled clinical trials have shown the in vivo retrovirus (RV)-mediated transduction of glioblastoma cells with the herpes simplex virus thymidine kinase (HSV-tk) gene and subsequent systemic treatment with ganciclovir to be feasible and well tolerated. However, because of continued tumor progression in most patients, the antitumor effect could not be determined using historical controls. Here, we describe a phase III, multicenter, randomized, open-label, parallel-group, controlled trial of the technique in the treatment of 248 patients with newly diagnosed, previously untreated glioblastoma multiforme (GBM). Patients received, in equal numbers, either standard therapy (surgical resection and radiotherapy) or standard therapy plus adjuvant gene therapy during surgery. Progression-free median survival in the gene therapy group was 180 days compared with 183 days in control subjects. Median survival was 365 versus 354 days, and 12-month survival rates were 50 versus 55% in the gene therapy and control groups, respectively. These differences were not significant. Therefore, the adjuvant treatment improved neither time to tumor progression nor overall survival time, although the feasibility and good biosafety profile of this gene therapy strategy were further supported. The failure of this specific protocol may be due mainly to the presumably poor rate of delivery of the HSV-tk gene to tumor cells. In addition, the current mode of manual injection of vector-producing cells with a nonmigratory fibroblast phenotype limits the distribution of these cells and the released replication-deficient RV vectors to the immediate vicinity of the needle track. Further evaluation of the RV-mediated gene therapy strategy must incorporate refinements such as improved delivery of vectors and transgenes to the tumor cells, noninvasive in vivo assessment of transduction rates, and improved delivery of the prodrug across the blood-brain and blood-tumor barrier to the transduced tumor cells.
The abdominal intraperitoneal cerebrospinal fluid pseudocyst is an infrequent but important complication in patients with ventriculoperitoneal shunts. Since 1954, 115 cases of paediatric pseudocysts have been reported in the literature. One additional report deals with an adult patient. We report on 14 cases of sonographically diagnosed abdominal pseudocysts. Their aetiology, diagnosis, clinical signs and symptoms and surgical management are investigated. In our hydrocephalus series we have an incidence of pseudocyst formation of 4.5%. The most common presentation of the paediatric patients is with symptoms of elevated intracranial pressure and abdominal pain, whereas the adults have predominantly local abdominal signs. Diagnosis is readily made with ultrasonography. Predisposing factors for pseudocyst formation are multiple shunt revisions and infection. Microscopically, the pseudocysts consist of fibrous tissue without epithelial lining. The treatment involves surgical removal of the catheter with or without excision of the pseudocyst wall and placement of a new catheter intraperitoneally in a different quadrant or an intra-atrial shunt. Recurrences are rare, especially under appropriate medical treatment of infection. In our series, microbiologically proven infection was present in 30% of the cases.
The remarkable migratory and tumor-tropic capacities of neural stem cells (NSCs and/or neuroprogenitor cells) represent a potentially powerful approach to the treatment of invasive brain tumors, such as malignant gliomas. We have previously shown that whether implanted directly into or at distant sites from an experimental intracranial glioma, NSCs distributed efficiently throughout the main tumor mass and also tracked advancing tumor cells, while stably expressing a reporter transgene. As therapeutic proof-of-concept, NSCs genetically modified to produce the prodrug activating enzyme cytosine deaminase (CD), effected an 80% reduction in the resultant tumor mass, when tumor animals were treated with the systemic prodrug, 5-fluorocytosine. We now extend our findings of the tumor-tropic properties of NSCs (using a well-characterized, clonal NSC line C17.2), by investigating their capacity to target both intracranial and extracranial tumors, when administered into the peripheral vasculature. We furthermore demonstrate their capacity to target extracranial non-neural tumors such as prostate cancer and malignant melanoma. Well-characterized NSC lines (lacZ and/or CD-positive) were injected into the tail vein of adult nude mice with established experimental intracranial and/or subcutaneous flank tumors of neural and non-neural origin. The time course and distribution of NSCs within the tumor and internal organs was assessed in various models. Resulting data suggest that NSCs can localize to various tumor sites when injected via the peripheral vasculature, with little accumulation in normal tissues. Our findings suggest the novel use of intravascularly administered NSCs as an effective delivery vehicle to target and disseminate therapeutic agents to invasive tumors of neural and nonneural origin, both within and outside of the brain.
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