Closed-loop sonothermogenetic control of CAR T cells for metronomic brain cancer therapy.

Achieving durable CAR T cell responses against primary brain tumors and metastases requires strategies that enable intracranial control of therapy to overcome the barriers of solid tumor treatment without compromising safety. Here, we show that closed-loop sonothermogenetics enables remote regulation of CAR T cell therapeutic activity through the intact skull. Using MR-guided focused ultrasound with closed-loop temperature feedback, we modulate CAR T cells engineered with a genetically encoded thermal bioswitch to achieve metronomic activation in the brain without lasting adverse effects on healthy brain tissue. In murine models of brain cancer, metronomic production of NKG2D T cell engagers by intratumoral CAR T cells overcomes antigen heterogeneity in breast cancer brain metastasis and myeloid-derived immunosuppression in glioblastoma to drive antitumor responses. Our findings support the use of closed-loop sonothermogenetics for spatial and temporal control of CAR T cell therapies targeting solid brain tumors.

Introduction

Purpose Transcranial ultrasound stimulation

Study Objective To demonstrate that MR-guided closed-loop sonothermogenetics can remotely, safely, and temporally control engineered CAR T cell activity through the intact skull to improve antitumor responses in brain tumors.

Animal model / Human subject Mus musculus (mouse); strain not specified; age not specified; sex not specified

Disease model Brain cancer (glioblastoma and breast cancer brain metastasis)

MRI or image guidance method MR-guided focused ultrasound with closed-loop temperature feedback

Targeted brain region(s) Brain

Cargo name and characteristics Engineered CAR T cells (cell therapy): T cells modified to include a genetically encoded thermal bioswitch that enables heat-inducible activation; delivered intratumorally and remotely activated via MR‑guided focused ultrasound (closed‑loop temperature feedback) to drive metronomic production of NKG2D T cell engagers (secreted protein biologics) for intracranial antitumor activity.

Route of administration Intratumoral (direct injection into the brain tumor)

Outcomes and Safety

Summary of Outcomes MR-guided closed-loop focused ultrasound remotely and repeatedly activates thermally switchable CAR T cells through the intact skull, driving intratumoral NKG2D engager production that overcomes antigen heterogeneity and myeloid immunosuppression to produce antitumor responses in murine brain tumor models without lasting damage to healthy brain tissue.

Duration of biological effect not specified

Safety-related matter The authors state that closed-loop sonothermogenetics enables metronomic intracranial CAR T cell activation without lasting adverse effects on healthy brain tissue and without compromising safety.

Brain Region

Ultrasound Parameters

Ultrasound instrument MR-guided focused ultrasound with closed-loop temperature feedback (no specific system model, manufacturer, or transducer aperture/diameter reported)

FUS Frequency Not specified in provided text

FUS Intensity Not reported in provided text

FUS Pressure Not reported in provided text

FUS Mode pulsed

Pulse duration not reported

Duration of a single FUS session Not specified in the provided text

Focal Characteristics Not specified

Treatment frequency multiple sessions

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