Translate this page to:
Choose Language…
In JoVE (1)
Other Publications (8)
Articles by Rintaro Hashizume in JoVE
JoVE Neuroscience
Systemic and Local Drug Delivery for Treating Diseases of the Central Nervous System in Rodent Models
Department of Neurological Surgery, University of California, San Francisco - UCSF
Thorough preclinical testing of drugs that act in the central nervous system often involves assessing and comparing drug biodistribution in association with specific routes of administration. Here, three commonly used methods of systemic delivery (intravenous, intraperitoneal, and oral) as well as a method for local delivery (convection-enhanced delivery) are demonstrated in mice.
Other articles by Rintaro Hashizume on PubMed
[Breast Cancer]
In Japan the mortality and incidence rates of breast cancer have been increasing. In 2000, the number of breast cancer deaths in female was 9,171. In 1996, the aged adjusted incidence rate of breast cancer was 38.9, top among all of female cancers and the estimated number of female breast cancer patients was 29,448 in Japan. Therefore, efficient breast cancer screening system is urgently needed. In April 2000, breast screening using biennial mammography in combination with clinical breast examination instead of annual clinical breast examination alone was introduced for women aged 50 and over in Japan. However, the compliance of screening using mammography was less than 1% in the fiscal 2000 year. On the other hand, the compliance of screening with clinical breast examination alone was 6.5% in same period. These compliances were significantly lower than that of about 65% in the USA. Given the importance of the control of quality in screening mammography, a central committee for the quality control of mammographic screening has been established in order to educate doctors and radiographers and to assess image apparatus in each facility. As of April 2002, 1,409 out of 1,978 doctors that participated in the training program had obtained either grade A (instructor level) or grade B (adequate level). Gøtzche and Olsen reassessed previous meta-analyses of screening mammography and concluded that screening for breast cancer with mammography was unjustified. Subsequently, reviews by U. S. Preventive Services Task Forces and the WHO reconfirmed the effectiveness of screening mammography in reducing breast cancer mortality. These controversies show the importance of assessment of screening mammography effectiveness in Japan.
New Therapeutic Approach for Brain Tumors: Intranasal Delivery of Telomerase Inhibitor GRN163
The blood-brain barrier is a substantial obstacle for delivering anticancer agents to brain tumors, and new strategies for bypassing it are greatly needed for brain-tumor therapy. Intranasal delivery provides a practical, noninvasive method for delivering therapeutic agents to the brain and could provide an alternative to intravenous injection and convection-enhanced delivery. We treated rats bearing intracerebral human tumor xenografts intranasally with GRN163, an oligonucleotide N3'-->P5'thio-phosphoramidate telomerase inhibitor. 3'-Fuorescein isothiocyanate (FITC)-labeled GRN163 was administered intranasally every 2 min as 6 microl drops into alternating sides of the nasal cavity over 22 min. FITC-labeled GRN163 was present in tumor cells at all time points studied, and accumulation of GRN163 peaked at 4 h after delivery. Moreover, GRN163 delivered intranasally, daily for 12 days, significantly prolonged the median survival from 35 days in the control group to 75.5 days in the GRN163-treated group. Thus, intranasal delivery of GRN163 readily bypassed the blood-brain barrier, exhibited favorable tumor uptake, and inhibited tumor growth, leading to a prolonged lifespan for treated rats compared to controls. This delivery approach appears to kill tumor cells selectively, and no toxic effects were noted in normal brain tissue. These data support further development of intranasal delivery of tumor-specific therapeutic agents for brain tumor patients.
A Human Brainstem Glioma Xenograft Model Enabled for Bioluminescence Imaging
Despite the use of radiation and chemotherapy, the prognosis for children with diffuse brainstem gliomas is extremely poor. There is a need for relevant brainstem tumor models that can be used to test new therapeutic agents and delivery systems in pre-clinical studies. We report the development of a brainstem-tumor model in rats and the application of bioluminescence imaging (BLI) for monitoring tumor growth and response to therapy as part of this model. Luciferase-modified human glioblastoma cells from five different tumor cell sources (either cell lines or serially-passaged xenografts) were implanted into the pontine tegmentum of athymic rats using an implantable guide-screw system. Tumor growth was monitored by BLI and tumor volume was calculated by three-dimensional measurements from serial histopathologic sections. To evaluate if this model would allow detection of therapeutic response, rats bearing brainstem U-87 MG or GS2 glioblastoma xenografts were treated with the DNA methylating agent temozolomide (TMZ). For each of the tumor cell sources tested, BLI monitoring revealed progressive tumor growth in all animals, and symptoms caused by tumor burden were evident 26-29 days after implantation of U-87 MG, U-251 MG, GBM6, and GBM14 cells, and 37-47 days after implantation of GS2 cells. Histopathologic analysis revealed tumor growth within the pons in all rats and BLI correlated quantitatively with tumor volume. Variable infiltration was evident among the different tumors, with GS2 tumor cells exhibiting the greatest degree of infiltration. TMZ treatment groups were included for experiments involving U-87 MG and GS2 cells, and in each case TMZ delayed tumor growth, as indicated by BLI monitoring, and significantly extended survival of animal subjects. Our results demonstrate the development of a brainstem tumor model in athymic rats, in which tumor growth and response to therapy can be accurately monitored by BLI. This model is well suited for pre-clinical testing of therapeutics that are being considered for treatment of patients with brainstem tumors.
Morphologic and Molecular Characterization of ATRT Xenografts Adapted for Orthotopic Therapeutic Testing
Atypical teratoid rhabdoid tumor (ATRT) is a malignant tumor of the central nervous system that most commonly arises in young children. The aggressive growth and propensity for early dissemination throughout the neuraxis confers a dismal prognosis. Large clinical trials that could test new therapeutic agents are difficult to conduct due to the low incidence of this cancer. For this reason, high throughput preclinical testing with suitable animal models for ATRT would serve a critical need for identifying the most efficacious treatments. In response to this need, we have adapted ATRT cell lines for bioluminescence imaging (BLI) of intracranial (orthotopic) xenografts established in athymic mice. Our results indicate that following supratentorial or infratentorial injection in athymic mice, ATRT cells produce rapidly growing tumors, often with intraventricular spread or neuraxis dissemination. When established as orthotopic xenografts, the tumors predominantly display cells with a rhabdoid-like cellular morphology that show a spectrum of immunophenotypes similar to primary ATRT tumors. To demonstrate the feasibility of this orthotopic ATRT xenograft model for therapeutic testing with correlation to biomarker analysis, we examined the responses of luciferase-modified ATRT cells to temozolomide (TMZ). These xenografts, which highly express MGMT, are resistant to TMZ treatment when compared with an orthotopic glioblastoma xenograft that is MGMT deficient and responsive to TMZ. These data suggest that an orthotopic ATRT xenograft model, in which BLI is used for monitoring tumor growth and response to therapy, should contribute to the identification of effective therapeutics and regimens for treating this highly aggressive pediatric brain tumor.
Telomerase Inhibitors for the Treatment of Brain Tumors and the Potential of Intranasal Delivery
A fundamental limitation in the treatment of brain tumors is that < 1% of most therapeutic agents administered systemically are able to cross the blood-brain barrier (BBB). The development of new strategies that circumvent the BBB should increase the likelihood of tumor response to selected therapeutic agents. Intranasal delivery (IND) is a practical, noninvasive method of bypassing the BBB to deliver therapeutic agents to the brain. This technique has demonstrated promising results in the treatment of neurological disorders. Telomerase is a reverse transcriptase that is expressed in the vast majority of malignant gliomas, although not in the healthy brain. Telomerase inhibition can therefore be used as a therapeutic strategy for selectively targeting malignant gliomas. The first successful IND of a telomerase inhibitor as a therapy for brain tumors was GRN-163, an oligonucleotide N3'-->5' thiophosphoramidate telomerase inhibitor, which was successfully administered into intracerebral tumors in rats with no apparent toxicity. GRN-163 exhibited favorable tumor uptake and inhibited tumor growth, leading to prolonged lifespan in treated animals. The IND of telomerase inhibitors represents a new therapeutic approach that appears to selectively kill tumor cells, without inducing toxic effects in the surrounding healthy brain tissue.
Identification of Internalizing Human Single-chain Antibodies Targeting Brain Tumor Sphere Cells
Glioblastoma multiforme (GBM) is the most common and aggressive form of primary brain tumor for which there is no curative treatment to date. Resistance to conventional therapies and tumor recurrence pose major challenges to treatment and management of this disease, and therefore new therapeutic strategies need to be developed. Previous studies by other investigators have shown that a subpopulation of GBM cells can grow as neurosphere-like cells when cultured in restrictive medium and exhibits enhanced tumor-initiating ability and resistance to therapy. We report here the identification of internalizing human single-chain antibodies (scFv) targeting GBM tumor sphere cells. We selected a large naive phage antibody display library on the glycosylation-dependent CD133 epitope-positive subpopulation of GBM cells grown as tumor spheres and identified internalizing scFvs that target tumor sphere cells broadly, as well as scFvs that target the CD133-positive subpopulation. These scFvs were found to be efficiently internalized by GBM tumor sphere cells. One scFv GC4 inhibited self-renewal of GBM tumor sphere cells in vitro. We have further developed a full-length human IgG1 based on this scFv, and found that it potently inhibits proliferation of GBM tumor sphere cells and GBM cells grown in regular nonselective medium. Taken together, these results show that internalizing human scFvs targeting brain tumor sphere cells can be readily identified from a phage antibody display library, which could be useful for further development of novel therapies that target subpopulations of GBM cells to combat recurrence and resistance to treatment.
Targeted Therapy for BRAFV600E Malignant Astrocytoma
Malignant astrocytomas (MA) are aggressive central nervous system tumors with poor prognosis. Activating mutation of BRAF (BRAF(V600E)) has been reported in a subset of these tumors, especially in children. We have investigated the incidence of BRAF(V600E) in additional pediatric patient cohorts and examined the effects of BRAF blockade in preclinical models of BRAF(V600E) and wild-type BRAF MA.
An Experimental Xenograft Mouse Model of Diffuse Pontine Glioma Designed for Therapeutic Testing
The prognosis for diffuse infiltrating pontine gliomas (DIPG) remains extremely poor, with the majority of patients surviving less than 2 years. Here, we have adapted standard xenograft techniques to study glioma growth in the mouse brainstem, and have utilized the mouse model for studying a relevant therapeutic for treating DIPGs. bioluminescence imaging monitoring revealed a progressive increase in signal following the injection of either of two tumor cell types into the brainstem. Mice with orthotopic GS2 tumors, and receiving a single 100 mg/kg dose of temozolomide showed a lengthy period of decreased tumor luminescence, with substantially increased survival relative to untreated mice (P < 0.001). A small molecule inhibitor that targets cdk4/6 was used to test AM-38 brainstem xenograft response to treatment. Drug treatment resulted in delayed tumor growth, and significantly extended survival. Our results demonstrate the feasibility of using an orthotopic brainstem tumor model in athymic mice, and for application to testing therapeutic agents in treating DIPG.
