Convection Enhanced Delivery: A Comparison of infusion characteristics in ex vivo and in vivo non-human primate brain tissue

Miranpuri, Gurwattan S.; Hinchman, Angelica; Wang, Anyi; Schomberg, Dominic; Kubota, Kazuhiko; Brady, Martin; Raghavan, Raghu; Bruner, Kevin; Brodsky, Ethan K.; Block, Walter F.; Grabow, Ben; Raschke, Jim; Alexander, Andrew L.; Ross, Chris; Simmons, Heather A.; Sillay, Karl

doi:10.5214/ans.0972.7531.200306

Cited by 12 publications

(9 citation statements)

References 28 publications

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“…The data are presented as mean ± SEM. show promise for targeted delivery of therapies into the brain [25][26][27][28], can be developed and refined for improving the effectiveness of therapies administered into the spinal cord [25,29].…”

Section: Discussionmentioning

confidence: 99%

Comparative Morphometry of the Wisconsin Miniature Swine<sup>TM</sup> Thoracic Spine for Modeling Human Spine in Translational Spinal Cord Injury Research

et al. 2018

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Background/Aims: Spine and spinal cord pathologies and associated neuropathic pain are among the most complex medical disorders to treat. While rodent models are widely used in spine and spinal cord research and have provided valuable insight into pathophysiological mechanisms, these models offer limited translatability. Thus, studies in rodent models have not led to the development of clinically effective therapies. More recently, swine has become a favored model for spine research because of the high congruency of the species to humans with respect to spine and spinal cord anatomy, vasculature, and immune responses. However, conventional breeds of swine commonly used in these studies present practical and translational hurdles due to their rapid growth toward weights well above those of humans. Methods: In the current study, we evaluated the suitability of a human-sized breed of swine developed at the University of Wisconsin-Madison, the Wisconsin Miniature Swine^TM (WMS^TM), in the context of thoracic spine morphometry for use in research to overcome limitations of conventional swine breeds. The morphometry of thoracic vertebrae (T1–T15) of 5–6 months-old WMS was analyzed and compared to published values of human and conventional swine spines. Results: The key finding of this study is that WMS spine more closely models the human spine for many of the measured vertebrae parameters, while being similar to conventional swine in respect to the other parameters. Conclusion: WMS provides an improvement over conventional swine for use in translational spinal cord injury studies, particularly long-term ones, because of its slower rate of growth and its maximum growth being limited to human weight and size.

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Section: Discussionmentioning

confidence: 99%

Comparative Morphometry of the Wisconsin Miniature Swine<sup>TM</sup> Thoracic Spine for Modeling Human Spine in Translational Spinal Cord Injury Research

et al. 2018

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“…For intracranial delivery, local brain molar concentrations were approximated from whole brain total drug mass using CED parameters reported in the literature. A volume distribution (V d ) to volume injected (V i ) ratio of 5.23±1.67 32 was used to calculate the molar concentration of resveratrol at infusion site. This V d /V i ratio is an experimentally-derived value for CED using a 1 μl/min flow rate into non-human primate brain 32 .…”

Section: Methodsmentioning

confidence: 99%

Resveratrol targeting of AKT and p53 in glioblastoma and glioblastoma stem-like cells to suppress growth and infiltration

Clark¹,

Bhattacharya

Elmayan³

et al. 2017

Journal of Neurosurgery

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Object Glioblastoma multiforme (GBM) is an aggressive brain cancer with median survival of less than two years with current treatment. GBM exhibits extensive intra-tumor and inter-patient heterogeneity, suggesting that successful therapies should exert broad anti-cancer activities. Therefore, the natural non-toxic pleiotropic agent, resveratrol, was studied for anti-tumorigenic effects against GBM. Methods Resveratrol’s effects on cell proliferation, sphere-forming ability, and invasion were tested using multiple patient-derived GBM stem-like cell (GSC) lines and established U87 glioma cells, and changes in oncogenic AKT and tumor suppressive p53 were analyzed. Resveratrol was also tested in vivo against U87 glioma flank xenografts using multiple delivery methods, including direct tumor injection. Finally, resveratrol was delivered directly to brain tissue to determine toxicity and achievable drug concentrations in the brain parenchyma. Results Resveratrol significantly inhibited proliferation in U87 glioma and multiple patient-derived GSC lines, demonstrating similar inhibitory concentrations across these phenotypically heterogeneous lines. Resveratrol also inhibited the sphere-forming ability of GSCs, suggesting anti-stem cell effects. Additionally, resveratrol blocked U87 glioma and GSC invasion in an in vitro Matrigel transwell assay at doses similar to those mediating anti-proliferative effects. In U87 glioma cells and GSCs, resveratrol reduced AKT phosphorylation and induced p53 expression and activation that led to transcription of downstream p53 target genes. Resveratrol administration via oral gavage or ad libitum in the water supply significantly suppressed GBM xenograft growth; intra-tumor or peri-tumor resveratrol injection further suppressed growth and approximating tumor regression. Intracranial resveratrol injection resulted in 100-fold higher local drug concentration compared to intravenous delivery, and with no apparent toxicity. Conclusions Resveratrol potently inhibited GBM and GBM stem-like cell growth and infiltration, acting partially via AKT deactivation and p53 induction, and suppressed glioblastoma growth in vivo. The ability of resveratrol to modulate AKT and p53, as well as reportedly many other anti-tumorigenic pathways, is attractive for therapy against a genetically heterogeneous tumor such as GBM. Although resveratrol exhibits low bioavailability when administered orally or intravenously, novel delivery methods such as direct injection (i.e. convection enhanced delivery) could potentially be used to achieve and maintain therapeutic doses in brain. Resveratrol’s non-toxic nature and broad anti-GBM effects make it a compelling candidate to supplement current GBM therapies.

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“…Currently, the pressure that occurs during clinical or experimental CED is measured in the infusion line rather than in the brain tissue or agarose gel at the tip of the catheter. [70][71][72][73] In comparison to the infusion-line Figure 7. Fluid velocity distributions for a cannula distance of 36 mm for each flow rate (1 and 4 mL/min) and two relative ventricle pressures (0 and 100 Pa).…”

Section: Discussionmentioning

confidence: 99%

Three-dimensional nonlinear finite element model to estimate backflow during flow-controlled infusions into the brain

Orozco

Smith

García

2020

Proc Inst Mech Eng H

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Convection-enhanced delivery is a technique to bypass the blood–brain barrier and deliver therapeutic drugs into the brain tissue. However, animal investigations and preliminary clinical trials have reported reduced efficacy to transport the infused drug in specific zones, attributed mainly to backflow, in which an annular gap is formed outside the catheter and the fluid preferentially flows toward the surface of the brain rather than through the tissue in front of the cannula tip. In this study, a three-dimensional human brain finite element model of backflow was developed to study the influence of anatomical structures during flow-controlled infusions. Predictions of backflow length were compared under the influence of ventricular pressure and the distance between the cannula and the ventricles. Simulations with zero relative ventricle pressure displayed similar backflow length predictions for larger cannula-ventricle distances. In addition, infusions near the ventricles revealed smaller backflow length and the liquid was observed to escape to the longitudinal fissure and ventricular cavities. Simulations with larger cannula-ventricle distances and nonzero relative ventricular pressure showed an increase of fluid flow through the tissue and away from the ventricles. These results reveal the importance of considering both the subject-specific anatomical details and the nonlinear effects in models focused on analyzing current and potential treatment options associated with convection-enhanced delivery optimization for future clinical trials.

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Convection Enhanced Delivery: A Comparison of infusion characteristics in ex vivo and in vivo non-human primate brain tissue

Cited by 12 publications

References 28 publications

Comparative Morphometry of the Wisconsin Miniature Swine<sup>TM</sup> Thoracic Spine for Modeling Human Spine in Translational Spinal Cord Injury Research

Comparative Morphometry of the Wisconsin Miniature Swine<sup>TM</sup> Thoracic Spine for Modeling Human Spine in Translational Spinal Cord Injury Research

Resveratrol targeting of AKT and p53 in glioblastoma and glioblastoma stem-like cells to suppress growth and infiltration

Three-dimensional nonlinear finite element model to estimate backflow during flow-controlled infusions into the brain

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