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Review
. 2025 Sep 30.
doi: 10.1038/s41573-025-01291-5. Online ahead of print.

In vivo chimeric antigen receptor (CAR)-T cell therapy

Adrian Bot  1 Andrew Scharenberg  2 Kevin Friedman  3 Lin Guey  4 Robert Hofmeister  5 James I Andorko  6 Michael Klichinsky  7 Frank Neumann  8 Jagesh V Shah  9   10 Andrew J Swayer  11 Kyle Trudeau  9 Drew Weissman  12 Matthias T Stephan  13 Christian J Buchholz  14   15 Carl H June  12
Affiliations
Review

In vivo chimeric antigen receptor (CAR)-T cell therapy

Adrian Bot et al. Nat Rev Drug Discov. .

Abstract

Chimeric antigen receptor (CAR)-T cell therapy has transformed the outcomes of patients with haematological malignancies, yet its use is limited by labour-intensive manufacturing, constrained production capacity and variable clinical performance. In vivo CAR-T cell engineering, in which CAR-T cells are generated directly inside the patient's body, seeks to overcome these challenges by eliminating the need for ex vivo cell processing and complex logistics, as well as improve clinical performance. Recent advances in virology, RNA medicines and nanotechnology have catalysed a radical overhaul of this approach, which uses targeted delivery systems such as lentiviral vectors and lipid nanoparticles to introduce CAR-encoding genetic material into endogenous T cells. Early clinical studies have shown efficient transduction, sustained CAR expression and initial signs of antitumour activity, establishing proof of concept. This Review explores the underlying technologies - including RNA delivered by lipid nanoparticles and engineered viral vectors - and discusses how they are being adapted to develop more broadly applicable, scalable, safe and effective CAR-T cell therapies. By removing the need for ex vivo manipulation and chemotherapeutic conditioning, this strategy could enable the wider application of CAR-T cell therapies not just to blood cancers but to autoimmune diseases for which ex vivo CAR-T cell therapies have shown strong promise, such as systemic lupus erythematosus.

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Conflict of interest statement

Competing interests: J.I.A. is a paid employee of Interius BioTherapeutics, Inc., holds equity in the company, and is an inventor on patents issued and/or pending related to this work. A.B. is a shareholder and employee of Capstan Therapeutics, a company developing in vivo chimeric antigen receptor (CAR) therapies, and inventor or co-inventor on multiple relevant patents in the CAR and related fields. C.J.B. is a co-inventor on patents covering T cell-targeted lentiviral vectors. K.F. is a shareholder and member of the Board of Directors of Kelonia Therapeutics, and is also an inventor on patent applications assigned to Kelonia. L.G. is a shareholder and employee of Moderna, and a shareholder of Tessera. A.S. is a shareholder and employee of Umoja Therapeutics, a company developing in vivo CAR therapies. R.H. is a shareholder and employee of Myeloid Therapeutics, a company developing in vivo CAR therapies. C.H.J. is an inventor of multiple CAR patents and shareholder of several companies developing CAR products. M.K. is a founder, employee and shareholder of Carisma Therapeutics; a founder, shareholder and board director of Chymal Therapeutics; and an inventor of multiple patents related to CAR macrophages and monocytes (CAR-M) that have been licensed by Carisma Therapeutics. F.N. is a shareholder and employee of Orna Therapeutics, a company developing in vivo CAR therapies. A.J.S. is a shareholder and current employee of Sanofi. J.V.S. is an employee and shareholder in Mirai Bio, and a consultant and shareholder in Sana Biotechnology. M.T.S. is co-founder of and has received stock options from Persistence Therapeutics (Jupiter Bioventures); and has IP Licensing with Sanofi, Juno Therapeutics (now Bristol Myers Squibb) and Jupiter Bioventures. K.T. is a shareholder and employee of Sana Therapeutics, a company developing in vivo CAR and cell gene therapies. D.W. has filed patent applications based on some aspects of this work; those interests were fully disclosed to the University of Pennsylvania, with an approved plan in place for managing any potential conflicts arising from licensing of these patents.

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