Tay-Sachs Disease (TSD) is an inherited neurological disorder caused by deficiency of hexosaminidase A (HexA). Preclinical work demonstrated safety and efficacy of CNS gene therapy using AAVrh8-HEXA/HEXB. Here we describe an expanded access trial in two patients with infantile TSD (IND 18225).Case TSD-001 demonstrated neurodevelopmental regression by 8 months of age and severe seizures by 1 year was treated at 30 months. An equimolar mix of AAVrh8-HEXA and AAVrh8-HEXB (now AXO-AAV-GM2) was administered intrathecally (IT), with 75% of the dose (1x10 14 vg) delivered to the cisterna magna and 25% at the thoraco-lumbar junction. The second patient (TSD-002) was treated at 7 months of age with 4•2x10 13 vg by a combination of bilateral thalamic (0•18 mL; 1•5x10 12 vg per thalamus), and IT infusion (3•9x10 13 vg). Both patients underwent immunosuppression with sirolimus, corticosteroids, and rituximab.Injection procedures were well tolerated and have shown no vector-related adverse events to date. CSF HexA activity nearly doubled from baseline and remained stable. In TSD-002 (now 16 months of age), MRI showed stabilization of disease by 3 months post-injection; there now appeared to temporarily deviate from the natural history of infantile TSD but declined again 6 months post-treatment. TSD-001 (now 4.5 years of age remains seizure-free on the same anticonvulsant therapy as pre-therapy, but TSD-002 developed seizures between 13 and 17 months post-treatment (by 2 years of age).Administration of AXO-AAV-GM2 by IT and thalamic injections was safe, HexA activity increased in CSF and ongoing myelination was apparent in the younger patient treated at an early symptomatic stage. This study provides early safety and proof-of-concept in humans for treatment of TSD patients by AAV gene therapy.
Quantifying the extent and evolution of cerebral edema developing after stroke is an important but challenging goal. Lesional net water uptake (NWU) is a promising CT-based biomarker of edema, but its measurement requires manually delineating infarcted tissue and mirrored regions in the contralateral hemisphere. We implement an imaging pipeline capable of automatically segmenting the infarct region and calculating NWU from both baseline and follow-up CTs of large-vessel occlusion (LVO) patients. Infarct core is extracted from CT perfusion images using a deconvolution algorithm while infarcts on follow-up CTs were segmented from non-contrast CT (NCCT) using a deep-learning algorithm. These infarct masks were flipped along the brain midline to generate mirrored regions in the contralateral hemisphere of NCCT; NWU was calculated as one minus the ratio of densities between regions, removing voxels segmented as CSF and with HU outside thresholds of 20–80 (normal hemisphere and baseline CT) and 0–40 (infarct region on follow-up). Automated results were compared with those obtained using manually-drawn infarcts and an ASPECTS region-of-interest based method that samples densities within the infarct and normal hemisphere, using intraclass correlation coefficient (ρ). This was tested on serial CTs from 55 patients with anterior circulation LVO (including 66 follow-up CTs). Baseline NWU using automated core was 4.3% (IQR 2.6–7.3) and correlated with manual measurement (ρ = 0.80, p < 0.0001) and ASPECTS (r = −0.60, p = 0.0001). Automatically segmented infarct volumes (median 110-ml) correlated to manually-drawn volumes (ρ = 0.96, p < 0.0001) with median Dice similarity coefficient of 0.83 (IQR 0.72–0.90). Automated NWU was 24.6% (IQR 20–27) and highly correlated to NWU from manually-drawn infarcts (ρ = 0.98) and the sampling-based method (ρ = 0.68, both p < 0.0001). We conclude that this automated imaging pipeline is able to accurately quantify region of infarction and NWU from serial CTs and could be leveraged to study the evolution and impact of edema in large cohorts of stroke patients.
BackgroundHigh-frequency optical coherence tomography (HF-OCT) is an intra-vascular imaging technique capable of assessing device-vessel interactions at spatial resolution approaching 10 µm. We tested the hypothesis that adequately deployed Woven EndoBridge (WEB) devices as visualized by HF-OCT lead to higher aneurysm occlusion rates.MethodsIn a leporine model, elastase-induced aneurysms (n=24) were treated with the WEB device. HF-OCT and digital subtraction angiography (DSA) were performed following WEB deployment and repeated at 4, 8, and 12 weeks. Protrusion (0-present, 1-absent) and malapposition (0-malapposed, 1-neck apposition >50%) were binary coded. A device was considered ‘adequately deployed’ by HF-OCT and DSA if apposed and non-protruding. Aneurysm healing on DSA was reported using the 4-point WEB occlusion score: A or B grades were considered positive outcome. Neointimal coverage was quantified on HF-OCT images at 12 weeks and compared with scanning electron microscopy (SEM).ResultsAdequate deployment on HF-OCT correlated with positive outcome (P=0.007), but no statistically significant relationship was found between good outcome and adequate deployment on DSA (P=0.289). Absence of protrusion on HF-OCT correlated with a positive outcome (P=0.006); however, malapposition alone had no significant relationship (P=0.19). HF-OCT showed a strong correlation with SEM for the assessment of areas of neointimal tissue (R²=0.96; P<0.001). More neointimal coverage of 78%±32% was found on ‘adequate deployment’ cases versus 31%±24% for the ‘inadequate deployment’ cases (P=0.001).ConclusionHF-OCT visualizes features that can determine adequate device deployment to prognosticate early aneurysm occlusion following WEB implantation and can be used to longitudinally monitor aneurysm healing progression.
In 2015, multiple randomized clinical trials showed an unparalleled treatment benefit of stent-retriever thrombectomy as compared to standard medical therapy for the treatment of a large artery occlusion causing acute ischemic stroke. A short time later, the HERMES collaborators presented the patient-level pooled analysis of five randomized clinical trials, establishing class 1, level of evidence A for stent-retriever thrombectomy, in combination with intravenous thrombolysis when indicated to treat ischemic stroke. In the years following, evidence continues to mount for expanded use of this therapy for a broader category of patients. The enabling technology that changed the tide to support endovascular treatment of acute ischemic stroke is the stent-retriever. This review summarizes the history of intra-arterial treatment of stroke, introduces the biomechanics of embolus extraction with stent-retrievers, describes technical aspects of the intervention, provides a description of hemodynamic implications of stent-retriever embolectomy, and proposes future directions for a more comprehensive, multi-modal endovascular approach for the treatment of acute ischemic stroke.
Tay-Sachs Disease (TSD) is an inherited neurological disorder caused by deficiency of hexosaminidase A (HexA). Preclinical work demonstrated safety and efficacy of CNS gene therapy using AAVrh8-HEXA/HEXB. Here we describe an expanded access trial in two patients with infantile TSD (IND 18225). Case TSD-001 demonstrated neurodevelopmental regression by 8 months of age and severe seizures by 1 year was treated at 30 months. An equimolar mix of AAVrh8-HEXA and AAVrh8-HEXB (now AXO-AAV-GM2) was administered intrathecally (IT), with 75% of the dose (1x1014vg) delivered to the cisterna magna and 25% at the thoraco-lumbar junction. The second patient (TSD-002) was treated at 7 months of age with 4.2x1013 vg by a combination of bilateral thalamic (0.18 mL; 1.5x1012vg per thalamus), and IT infusion (3.9x1013vg). Both patients underwent immunosuppression with sirolimus, corticosteroids, and rituximab. Injection procedures were well tolerated and have shown no vector-related adverse events to date. CSF HexA activity nearly doubled from baseline and remained stable. In TSD-002 (now 16 months of age), MRI showed stabilization of disease by 3 months post-injection and appeared to temporarily deviate from the natural history of infantile TSD but declined again 6 months post-treatment. TSD-001 (now 4.5 years of age remains seizure-free on the same anti-convulsant therapy as pre-therapy, but TSD-002 developed seizures between 13 and 17 months posttreatment (by 2 years of age). Administration of AXO-AAV-GM2 by IT and thalamic injections was safe, HexA activity increased in CSF and ongoing myelination was apparent in the younger patient treated at an early symptomatic stage. This study provides early safety and proof-of-concept in humans for treatment of TSD patients by AAV gene therapy.
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