CD19-targeted therapies — Platform Heatmap
CD19-directed therapies across modalities (CAR-T, T-cell-engaging bispecifics, mAb/ADC) AND across domains — the heme-oncology workhorse (lymphoma/leukemia) now crossing into autoimmune disease (lupus, myasthenia, scleroderma, myositis), where CD19 CAR-T "resets" the B-cell compartment.
40 drugs target this family across 20 indications (161 drug–indication programs mapped). The most contested indication is Lupus (39 programs).
- Class maturity: 8 of 70 drugs map to an approved compound (11%); 62 are NME candidates — mix of label-extension and first-mover bets.
- Antigen concentration: CD19 (29 drugs, 41%) — dominant target.
- Indication concentration: Lupus (39 drugs, 56%) — primary deployment target.
- 37 platform drugs deployed in ≥3 indications (top: rapcabtagene autoleucel (YTB323) in 9 indications) — broad-applicability bets.
- Sponsor concentration: AstraZeneca runs 3 drugs (4%) — leading among 56 sponsors.
- 17 drugs have hot readouts in next 6 months — class-defining data imminent.
- 27 drugs have stale trials (overdue without status change) — possible operational issues or class deprioritization.
- 14 of 70 drugs have reached Ph3 (20%) — class maturity by progression.
Forward catalysts next 18 months⏰ 15 due ≤6 mo
primaryCompletionDate — a timing proxy, not a confirmed action date). Red = due within 6 months.Drug × Indication
Lupus | Hodgkin | ALL | DLBCL | Systemic Sclerosis | RA | NHL | Vasculitis | FL | CLL/SLL | Autoimmune Cytopenias | MS | Sjogren's | MG | Myositis | Membranous Nephropathy | MCL | Multi-tumor basket | MM | Amyloidosis | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| YTS109 cellChina Immunotech (Beijing)CD19 CAR-T (autoimmune) | ||||||||||||||||||||
| SurovatamigAstraZenecaCD19 × CD3 T-cell engager | ||||||||||||||||||||
| rapcabtagene autoleucel (YTB3…NovartisCD19 CAR-T | ||||||||||||||||||||
| GNC-038Sichuan BailiCD19 × CD3 T-cell engager | ||||||||||||||||||||
| BMS-986353 (CC-97540)Bristol-Myers SquibbCD19 CAR-T (autoimmune) | ||||||||||||||||||||
| FT819FateCD19 CAR-T (autoimmune) | ||||||||||||||||||||
| tafasitamab (Monjuvi)Incyte CorporationCD19 mAb | ||||||||||||||||||||
| AZD0120AstraZenecaBCMA/CD19 | ||||||||||||||||||||
| blinatumomab (Blincyto)AmgenCD19 × CD3 bispecific | ||||||||||||||||||||
| MK-1045Merck & Co.CD19 × CD3 T-cell engager | ||||||||||||||||||||
| NKX019NkartaCD19 CAR-NK (autoimmune) | ||||||||||||||||||||
| obecabtagene autoleucel (Auca…Autolus LimitedCD19 CAR-T | ||||||||||||||||||||
| KYV-101KyvernaCD19 CAR-T (autoimmune) | ||||||||||||||||||||
| AZD0486AstraZenecaCD19 × CD3 T-cell engager | ||||||||||||||||||||
| CABA-201Cabaletta BioCD19 CAR-T (autoimmune) | ||||||||||||||||||||
| YK012Excyte BiopharmaCD19 × CD3 T-cell engager | ||||||||||||||||||||
| CTX112CRISPRCD19 CAR-T (autoimmune) | ||||||||||||||||||||
| tisagenlecleucel (Kymriah)NovartisCD19 CAR-T | ||||||||||||||||||||
| loncastuximab tesirine (Zynlo…ADC TherapeuticsCD19 ADC | ||||||||||||||||||||
| InebilizumabAmgenCD19 | ||||||||||||||||||||
| ObexelimabZenas BioPharma (USA)CD19 | ||||||||||||||||||||
| zamtocabtagene autoleucelMiltenyi BiomedicineCD19 | ||||||||||||||||||||
| EB103Estrella BiopharmaCD19 | ||||||||||||||||||||
| BudoprutugClimb BioAnti-CD19 (mAb) | ||||||||||||||||||||
| MB-CART19.1Miltenyi BiomedicineCD19 | ||||||||||||||||||||
| PIT565NovartisCD19 × CD3 T-cell engager | ||||||||||||||||||||
| CLN-978CullinanCD19 × CD3 T-cell engager | ||||||||||||||||||||
| ABBV-319AbbVieCD19 ADC (GRM payload) | ||||||||||||||||||||
| HN2301Shenzhen MagicRNACD19 CAR-T (autoimmune) | ||||||||||||||||||||
| MC-1-50Chongqing PrecisionCD19 | ||||||||||||||||||||
| SC291Sana BiotechnologyCD19 CAR-T (autoimmune) | ||||||||||||||||||||
| TI-0032-IIITherornaCD19 CAR-T (autoimmune) | ||||||||||||||||||||
| axicabtagene ciloleucel (Yesc…Kite, A Gilead CompanyCD19 CAR-T | ||||||||||||||||||||
| lisocabtagene maraleucel (Bre…Bristol-Myers SquibbCD19 CAR-T | ||||||||||||||||||||
| Relma-celShanghai Ming JuCD19 | ||||||||||||||||||||
| CD19 t-haNKImmunityBioCD19 | ||||||||||||||||||||
| CC312CytoCaresCD19 × CD3 T-cell engager | ||||||||||||||||||||
| P-CD19CD20-ALLO1PoseidaCD19 | ||||||||||||||||||||
| FCTX-CL19-1FamiCordTxCD19 | ||||||||||||||||||||
| MB-CART2019.1Miltenyi BiomedicineCD19/CD20 CAR-T (MS) |
Beyond the grid Beta
White-space indications — a single asset 9 found
More assets in this family (28) — same mechanism, beyond the matrix top 40 by activity
| Phase | Mechanism | Company | Modality | Readout | Trial |
|---|---|---|---|---|---|
| Ph2 | CD19 t-haNK- Administration — CD19 | ImmunityBio | IV/SC | 2Q27 | NCT07125872 |
| Ph2 | S1904 CD19 CAR-T — CD19 | Hebei Senlang | Cell therapy | 1Q27 | NCT07244406 |
| Ph2 | KTE-X19 — CD19 | Kite, A Gilead Company | 3Q27 | NCT06253663 | |
| Ph2 | LY3541860 — Anti-CD19 (mAb) | Eli Lilly | 4Q25 | NCT06220669 | |
| Ph2 | CAR-T-19 cell — CD19 | Beijing Yongtai Ruike | Cell therapy | 2Q25 | NCT06179524 |
| Ph2 | pCAR-19B cells — CD19 | Chongqing Precision | 4Q24 | NCT05334823 | |
| Ph2 | Human CD19Targeted T Cells — CD19 | Hrain | Cell therapy | 3Q24 | NCT05436223 |
| Ph1+Ph2 | GC012F — CD19 | Gracell | Cell therapy | 1Q27 | NCT06530849 |
| Ph1+Ph2 | GT719 — CD19 | Grit Biotechnology | 2Q28 | NCT06948981 | |
| Ph1+Ph2 | Prizloncabtagene autoleucel — CD19 | Johnson & Johnson | 4Q28 | NCT05421663 | |
| Ph1+Ph2 | Rondecabtagene autoleucel — CD19 | Lyell Immunopharma | 4Q28 | NCT05826535 | |
| Ph1+Ph2 | CRC01 — CD19 CAR-T (autoimmune) | Curocell | 2Q30 | NCT07364396 | |
| Ph1+Ph2 | AT101 — CD19 | AbClon | 1Q30 | NCT05338931 | |
| Ph1 | HB2198 — CD19/CD20 bispecific (mAb) | Hinge Bio | ⏰ 3Q26 | NCT07439263 | |
| Ph1 | Inaticabtagene Autoleucel — CD19 | Juventas Cell Therapy | ⏰ 3Q26 | NCT07091370 | |
| Ph1 | Anti-CD19 UCAR-T cells — CD19 | Chongqing Precision | Cell therapy | ⏰ 4Q26 | NCT06686524 |
| Ph1 | RJMty19 — CD19 | Guangdong Ruishun | ⏰ 4Q26 | NCT06340490 | |
| Ph1 | ssCART-19 — CD19 | Shanghai Unicar-Therapy B… | Cell therapy | 1Q27 | NCT07093073 |
| Ph1 | HN2302 — CD19 CAR-T (autoimmune) | Shenzhen MagicRNA | 4Q27 | NCT07523282 | |
| Ph1 | CPTX2309 — CD19 CAR-T (autoimmune) | Capstan | IV | 4Q27 | NCT06917742 |
| Ph1 | IASO-782 — Anti-CD19 (mAb) | Shanghai IASO | 3Q27 | NCT07483346 | |
| Ph1 | UB-VV410 — CD19 CAR-T (autoimmune) | Nanjing IASO | 2Q28 | NCT07109986 | |
| Ph1 | KN5501 cell — CD19 CAR-NK (autoimmune) | Ruitherapeutics | 3Q27 | NCT07358988 | |
| Ph1 | ARM011 — CD19 | TriArm Therapeutics (Taiw… | Cell therapy | 2Q28 | NCT07066397 |
| Ph1 | ABBV-519 — CD19 ADC (GRM payload) | AbbVie | SC | 1Q29 | NCT07607964 |
| Ph1 | ALA-101 — CD19 | Arovella | 1Q30 | NCT07518329 | |
| Ph1 | C402-CD19-CAR — CD19 | Shanghai Exuma | 1Q26 | NCT06830031 | |
| Ph1 | ZM001 — CD19 CAR-T (autoimmune) | Beijing Immunochina Medic… | 1Q26 | NCT06852573 |
Trials not yet mapped to an indication (2) — trials of in-grid assets whose condition isn’t an indication column yet — surfaced per trial so none are hidden
| Phase | Mechanism | Company | Modality | Readout | Trial |
|---|---|---|---|---|---|
| Ph2 | zamtocabtagene autoleucel — CD19unclassified | Miltenyi Biomedicine | 4Q29 | NCT06508931 | |
| Ph1 | GT719 — CD19unclassified | Grit Biotechnology | 1Q28 | NCT07021209 |
Frequently asked
Common questions about the CD19-targeted therapies landscape
- What drugs are in the CD19-targeted therapies class?
- 70 assets in the CD19-targeted therapies class are tracked in this platform view, including YTS109 cell, Surovatamig, and rapcabtagene autoleucel (YTB323). The heatmap maps every drug against the indications it is being developed for.
- What conditions are CD19-targeted therapies being developed for?
- CD19-targeted therapies are in clinical development across 30 indications, including Lupus, Hodgkin, DLBCL, ALL, and Systemic Sclerosis.
- How many CD19-targeted therapies are in late-stage trials?
- Of the 70 tracked assets in the CD19-targeted therapies class, 14 are in Phase 3, developed by 56 sponsors, across 188 mapped trials.
- What are the upcoming CD19-targeted therapies catalysts?
- Near-term catalysts in this class include Obexelimab (data readout, Jun '26); YK012 (data readout, Jun '26); YTS109 cell (data readout, Aug '26). Dates combine estimated trial readouts and confirmed FDA decision dates.
- How is the CD19-targeted therapies platform compiled?
- Assets are compiled from a curated CD19-targeted therapies target roster and matched to their ClinicalTrials.gov trials (2008–present). Each cell links to the underlying trial records.
- Is the CD19-targeted therapies heatmap free to use?
- Yes — viewing and searching the CD19-targeted therapies heatmap is free. A TheraRadar Pro subscription adds advanced filters, row/column selection, and one-click export to PowerPoint, PDF, and CSV.
How this is built — methodology & limits
These grids are only as good as the data and the classification behind them — so here is exactly what goes in, what stays out, how every assignment is made, and where the limits are.
Where the data comes from
Every heatmap is built from the public ClinicalTrials.gov registry, via its official API — interventional drug and biologic trials with a start date of 2008 or later. The master index holds over 145,000 trials and is refreshed weekly (see the “updated” date on this page). A disease landscape draws only from the active, Phase 1–3, industry-sponsored slice of that index.
- In scope: industry-sponsored trials in Phase 1, 2, or 3, with an active status (recruiting, active-not-recruiting, not-yet-recruiting, or enrolling by invitation). Phase 4 sits in the index but is left out of the landscapes.
- Filtered out: deeply stale programs (a primary completion date more than two years past with no update to completed or terminated); basket trials and incidental mentions (a trial counts toward a disease only when that disease is genuinely the subject of study — not a secondary cohort, an organ-of-origin overlap, or a passing mention); and healthy-volunteer studies.
We do not exclude trials by sponsor geography. Where a sponsor is based in China, the program is flagged on the page rather than hidden, so you can weigh it yourself. An automated test fails the weekly refresh if the underlying index is more than 14 days old, so a published grid is never built on a stale index.
How a trial is matched to a disease
Matching uses a structured medical ontology, not keyword guessing, and is designed so that no trial is ever silently dropped — every trial that clears the filters gets a classification, even if that is just “Other.” It runs as an ordered sequence of steps, stopping at the first that applies:
- Healthy-volunteer studies are set aside as non-disease trials.
- Ontology match — each tracked disease is linked to its official identifiers in the standard medical taxonomy (MeSH), so a trial can be matched even when its text uses a synonym.
- Curated disease patterns — a hand-maintained library of over 150 disease-name patterns covers the more granular indications across oncology, hematology, infectious disease, cardiometabolic, immunology, and neuropsychiatry.
- Basket guard — a trial matching four or more distinct diseases, or carrying explicit basket language (“tumor-agnostic,” “all solid tumors,” “pan-cancer”), is grouped into a single advanced-solid-tumor category rather than over-counted across every cancer it touches.
- Therapeutic-area roll-up — a trial with no specific match, but which the taxonomy still places under a broad area, is assigned to that area (“Oncology — other,” “Immunology — other,” …), checking cancers first so a site-specific tumor isn’t filed under its anatomical system.
A “drop-if-parent-present” rule keeps a generic name from drowning out a subtype: a trial matching both lupus and lupus nephritis is reported only as lupus nephritis. Internal abbreviations are translated to the plain disease names used across the site (for example, “CRC” becomes “Colorectal Cancer”), and the same classifier is shared by every heatmap, so the same trial always maps to the same disease wherever it appears.
How a drug is matched to its mechanism
Mechanism of action is the hardest part to get right, so it is assigned in layers — leaning on curated and public data first, with AI as a last resort:
- Curated rulebook (first). A rulebook we maintain — over 600 drug-to-mechanism rules — is checked first, matching on drug names, trial acronyms, sponsor trial identifiers, and intervention lists. First match wins, which stops a combination trial from being counted several times.
- Public molecular-target data. Where no rule applies, each intervention’s target is looked up in a public target database, with verbose or gene-symbol labels normalized into consistent short forms so one target isn’t split across several columns.
- Standard-of-care backbones. A small set of rules recognizes common combination scaffolds (checkpoint-inhibitor monotherapy, standard chemotherapy regimens, established standard-of-care agents) so they aren’t mistaken for the experimental arm.
- AI as a last resort, then cross-checked. Only for genuinely opaque sponsor code-names that none of the first three steps can resolve do we ask an AI model to propose a mechanism — applied only above a fixed confidence bar, then automatically cross-checked against the sponsor’s own pipeline page. Where AI and the sponsor agree, the program is marked sponsor-verified. Where they contradict, the label is discarded entirely — not shown, not counted.
New mechanism rules are independently double-verified before they’re trusted — a second, adversarial pass set up to disprove the first — and each is checked so it can’t mislabel an unrelated trial. Drugs whose mechanism isn’t publicly disclosed are shown openly as “Emerging — not yet disclosed” rather than guessed at: for a tool meant to support real decisions, “we don’t yet know” is a more trustworthy answer than a confident guess.
Where AI is used — and where it isn’t
The disease and mechanism matching above is driven first by deterministic rules and public ontologies, not AI. AI plays three bounded, disclosed roles: (1) an optional extra check that a trial genuinely studies the disease, on top of the ontology match; (2) inferring a trial’s treatment setting on the competitive grids when the rules don’t cover it, only above a fixed confidence bar; and (3) the last-resort mechanism step above, always cross-checked against the sponsor’s disclosures. Wherever an AI label reaches a cell, the page marks it (⚙️ or ✅) — AI is never the silent, sole source of what you see.
What the on-page markers mean
- ✅ Sponsor-verified — AI proposed the mechanism and it matched the sponsor’s own pipeline page. High-trust.
- ⚙️ AI-classified — AI proposed it above the confidence bar but it has not yet been cross-checked against the sponsor. Useful; verify before citing. It never means a person reviewed it.
- ⚡ First-in-class — the mechanism hasn’t appeared in any other disease landscape we’ve built. This reflects the scope of landscapes published so far (the tooltip lists exactly which were scanned), not an absolute claim about the whole market.
- 🌱 First-in-indication — the only program competing on that mechanism within this disease.
- 🆕 NME candidate — the interventions match no drug in our approved-drug index, suggesting a new molecular entity. The index is incomplete — a signal, not a regulatory fact.
- 🔗 Combination · 👶 Pediatric · 🔥 Hot (readout within six months) · ⏳ Stale (completion date passed but still marked active — often a stalled program).
Sponsor names are resolved through a curated parent/subsidiary map; unrecognized sponsors appear under their raw registry name. The registry records the sponsor at a trial’s inception, so names are as originally filed and may not reflect later acquisitions. To keep large grids legible, mechanisms with a single program are listed separately rather than crowding the main grid, and very small players are listed below it — presentation choices only; nothing is removed from the underlying counts.
How we score programs — “what’s about to move”
Each program carries a 0–100 score that deliberately ranks imminence over raw stage — the most decision-relevant signal on a competitive grid. It is the sum of:
- Clinical phase — up to 40 points (Phase 3 = 40, Phase 2 = 25, Phase 1 = 10).
- Readout proximity — up to 60 points (next readout <6 months = 60, 6–12 months = 45, 1–2 years = 30, distant = 5).
- Stale penalty — the score is halved if a trial is past its expected readout but still listed as active.
Cell colour on the grid is driven by this score, so a Phase 2 program about to read out can — correctly — outrank a dormant Phase 3 one. It answers “what’s about to move,” not just “what’s furthest along.”
What each grid plots
- Indication landscape — one disease — companies (rows) × mechanism of action (columns): who is competing, and on what mechanism.
- Company portfolio — one company — diseases (rows) × mechanism (columns): where it is active, and what it is betting on.
- MOA platform (this page) — one mechanism family — drugs (rows) × diseases (columns): who is working on this class, and where.
- Competitive landscape — one disease — mechanism (rows) × clinical setting (columns), aggregated across companies; setting columns are tailored per disease (e.g. lines of therapy in oncology; biologic-naïve vs. biologic-experienced in IBD).
What we don’t claim
- First-in-class is editorial, not absolute — “not seen in the landscapes we’ve built,” not “novel across the industry.”
- NME candidate is a signal, not a filing — absent from our (incomplete) approved-drug index.
- Disease matching is automated and not exhaustively validated per disease — ontology and pattern matching can occasionally include or miss a trial.
- AI-classified mechanisms are machine-proposed — unconfirmed unless they also carry ✅.
- Sponsor names are as-filed and may lag current ownership.
- Grids are as fresh as their last rebuild from the weekly index — no faster continuous refresh is claimed.
Data: ClinicalTrials.gov v2 API + FDA Drugs@FDA (approved-drug index). Spot an error? [email protected].
Data: ClinicalTrials.gov · Curated target-family roster · Trials registered 2008 onwards.