CrossBridge Bio Enters an Agreement to be Acquired by Eli Lilly to Advance Next-Generation Dual-Payload Antibody-Drug Conjugates

On April 14, 2026 CrossBridge Bio, Inc., a pre-clinical biotechnology company pioneering the development of next-generation dual-payload antibody-drug conjugates (ADCs) reported a definitive agreement to be acquired by Eli Lilly and Company ("Lilly").

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CrossBridge Bio, a Houston-based biotechnology firm founded in 2023, is developing a new dual-payload ADC technology originally created by Kyoji Tsuchikama at the University of Texas Health Science Center at Houston (UTHealth Houston). The company is focused on advancing next-generation ADCs with the potential to transform clinical practice. Its lead candidate, CBB-120, is a TROP2-targeting TOP1i/ATRi dual-payload ADC for cancer treatment. It is designed to enhance the therapeutic index and generate more durable responses compared to current TROP2-targeting ADCs, while also addressing key resistance mechanisms. U.S. Food and Drug Administration Investigational New Drug application for CBB-120 is anticipated in 2026.

"We look forward to seeing how Lilly advances our new generation of dual-payload antibody-drug conjugates, including CBB-120, with the potential to meaningfully improve outcomes for patients with limited treatment options. At CrossBridge Bio, we believe our dual-payload ADC platform is uniquely positioned to be transformative in oncology. I’m proud of how well our team has executed and advanced our platform in such a short time since the company’s founding. By becoming a part of Lilly, a leader in patient-focused therapeutic development, we are well-positioned to further accelerate the clinical potential of this approach," said Dr. Michael Torres, Co-Founder and CEO.

Under the terms of the agreement, Lilly will acquire CrossBridge Bio, and CrossBridge Bio shareholders could receive up to $300 million in cash, inclusive of an upfront payment and a subsequent payment upon achieving a specified development milestone.

Cooley LLP is serving as legal counsel to CrossBridge Bio, and Zwick Advisory, LLC acts as a strategic advisor to the Company’s Board of Directors.

(Press release, CrossBridge Bio, APR 14, 2026, View Source [SID1234664381])

BostonGene and ImmunoGenesis Announce Strategic Partnership to Overcome Immunotherapy Resistance

On April 14, 2026 BostonGene, developer of the leading AI foundation model for tumor and immune biology, and ImmunoGenesis, a clinical-stage biotech company developing innovative, science-driven immunotherapies, reported a strategic partnership to accelerate the clinical development of IMGS-001, the company’s lead program. IMGS-001 is a cytotoxic immune checkpoint inhibitor targeting both PD-L1 and PD-L2, and is being studied in a phase 1a/b dose-escalation and dose-expansion safety and efficacy trial (NCT06014502) in patients with solid tumors that have failed to respond to standard of care therapies. This collaboration will investigate the effect of IMGS-001 on patients based on each patient’s comprehensive immune and genetic profile, which can help identify those patients most likely to respond.

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"IMGS-001, through its multifunctional mechanism of both direct cell killing and PD-1 pathway blockade, has been specifically engineered to drive clinical benefit in patients with tumors resistant to current immunotherapies," said James Barlow, President and CEO of ImmunoGenesis. "BostonGene’s cutting edge technology can both elucidate the mechanism of action of the drug and identify those patients with unmet medical need most likely to benefit."

Through this collaboration, BostonGene will apply its AI-driven multiomic platform to perform deep molecular characterization of patients treated with IMGS-001. By integrating high-resolution spatial biology with systemic immune monitoring, the partnership will generate the critical data needed to visualize how IMGS-001 treatment may reshape the tumor microenvironment and identify specific biology to predict patient response. This data-driven approach moves beyond traditional biomarker analysis to deliver a system-level understanding of disease biology and therapeutic impact. It is expected to enable more precise patient selection, improve clinical decision-making, and accelerate the development of IMGS-001.

"We believe this partnership represents a significant leap beyond conventional clinical monitoring," said Charles Schweizer, PhD, Senior Vice President of Clinical Development at ImmunoGenesis. "By embedding BostonGene’s AI-powered insights into our clinical framework, we are decoding the precise cellular and molecular pathways driving clinical outcomes. This clarity will allow us to move with greater speed and precision, ultimately strengthening the potential of IMGS-001 to address unmet medical needs for patients with cold or immune excluded tumors."

The integration of BostonGene’s technology allows for a real-time assessment of how IMGS-001 can unlock anti-tumor immunity. By mapping the complex interactions between the immune system and the tumor, the two companies aim to eliminate the "trial and error" often associated with immunotherapy, ensuring the right patients receive the most effective treatment at the right time.

"Modern oncology demands a shift from broad application to data-driven precision," said Nathan Fowler, MD, Chief Medical Officer of BostonGene. "By combining our spatial and multiomic expertise with the innovative pipeline at ImmunoGenesis, we are defining the mechanism by which IMGS-001 overcomes immunotherapy resistance. This critical collaboration delivers important evidence needed to guide the next generation of precision immunotherapy."

(Press release, BostonGene, APR 14, 2026, View Source [SID1234664380])

Samsung Bioepis Initiates Phase 1 Clinical Trial for SBE303, Nectin-4 Targeting Antibody-Drug Conjugate (ADC) Candidate

On April 14, 2026 Samsung Bioepis Co., Ltd. reported the initiation of Phase 1 clinical trial for SBE303. SBE303 is Samsung Bioepis’s first novel antibody-drug conjugate (ADC) candidate engineered to bind to Nectin-4, an adhesion protein that is specifically expressed in tumor cells, including urothelial cancer, lung cancer, and breast cancer.1 The Phase 1 clinical trial for SBE303 is an open‑label, multi-center, first‑in‑human trial to evaluate the safety, tolerability and efficacy of SBE303 in participants with advanced refractory solid tumors. More information on this study is available at clinicaltrials.gov (NCT07524348).

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(Press release, Samsung Bioepis, APR 14, 2026, View Source [SID1234664379])

Kivu Bioscience to Present Preclinical Data on Next-Generation ADC Programs at AACR Annual Meeting 2026

On April 14, 2026 Kivu Bioscience, a clinical-stage biotechnology company developing next-generation antibody-drug conjugates (ADCs) for difficult-to-treat cancers, reported upcoming poster presentations at the American Association for Cancer Research (AACR) (Free AACR Whitepaper) Annual Meeting 2026, held April 17–22, in San Diego.

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"We are excited to present new data at AACR (Free AACR Whitepaper) that highlight both the strength of our ADC platform and the continued advancement of our pipeline," said Mohit Trikha, Ph.D., Chief Executive Officer, Kivu Bioscience. "KIVU-107 has the potential to be a best-in-class PTK7-targeted ADC, designed to overcome the tolerability challenges seen with earlier programs. Our second program, KIVU-305, expands our reach into CEACAM5, reinforcing our ability to develop differentiated ADCs with improved stability, tolerability and anti-tumor activity."

Poster Presentation Details

Title: KIVU-107: a clinical-stage, best-in-class PTK7 antibody-drug conjugate (ADC) with favorable PK and an improved tolerability profile
Session: Experimental and Molecular Therapeutics
Date/Time: Tuesday, April 21, 2026, 2:00 PM – 5:00 PM PT

Location: Section 10
Poster Number: 5649

KIVU-107 is an ADC targeting protein tyrosine kinase 7 (PTK7), a validated oncology target associated with tumor-initiating cells and overexpressed across multiple solid tumors. A Phase 1 clinical trial in patients with advanced solid tumors is ongoing (NCT07229313).

Title: Preclinical efficacy and safety of KIVU-305, a novel CEACAM5-targeting antibody-drug conjugate (ADC) for colorectal cancer
Session Track: Experimental and Molecular Therapeutics
Date/Time: Tuesday, April 21, 2026, 2:00 PM – 5:00 PM PT

Location: Section 10
Poster Number: 5648

KIVU-305 is a next-generation ADC targeting CEACAM5, a well-validated antigen highly expressed in colorectal, pancreatic, gastric and lung cancers. While earlier CEACAM5-targeted ADCs established clinical feasibility, their impact has been limited by efficacy at tolerable doses, underscoring the need for improved linker-payload design. KIVU-305 is designed to address these challenges, with a Phase 1 clinical trial in patients with advanced solid tumors planned for 2026.

(Press release, Kivu Bioscience, APR 14, 2026, View Source [SID1234664378])

Dyve Biosciences and Moffitt Cancer Center Report Promising Study Results for First-of-Its-Kind Topical Therapy Targeting Tumor Acidity

On April 14, 2026 Dyve Biosciences, in collaboration with Moffitt Cancer Center, reported significant study results for a first-of-its-kind investigational therapy applied to the skin and designed to work throughout the body to target the tumor microenvironment, a key driver of treatment resistance and immune evasion.

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The treatment, a novel transdermal therapy designed to modulate tumor pH, helped make tumors substantially less acidic, restore T-cell activity, slow tumor growth and improve survival in preclinical studies.

The findings were recently published in Frontiers in Immunology following studies conducted by researchers at Moffitt Cancer Center using animal models of bladder cancer. Known as DYV800, the treatment also demonstrated systemic effects, with activity beyond the site of application, and may have broader potential across multiple solid tumor types where tumor acidity plays a role.

Instead of attacking the tumor directly, this approach targets the conditions that help tumors survive. Tumor acidity may act as an upstream immune checkpoint and suppress immune response before traditional checkpoint pathways are engaged. Prior research has shown tumor-reactive CD8 T-cell responses can drop significantly in acidic conditions, reinforcing the role of pH in limiting immune activity.

Researchers have increasingly focused on the tumor microenvironment because it influences how tumors grow, evade the immune system and respond to treatment. One important factor is tumor acidity. Solid tumors often develop this acidic environment, typically ranging from pH 6.2 to 6.8 compared to a normal physiological pH of 7.4. This can suppress immune function and contribute to treatment resistance, making it a key focus of ongoing cancer research.

Modulating tumor pH and making tumors less acidic may help restore immune function and improve how some cancer treatments work. In these studies, DYV800 was associated with increased intratumoral pH, 4-1BB, TNF-α, IFN-γ, and antigen-specific CD8 responses, together with reduced tumor burden and prolonged survival. These findings reinforce the view that pH modulation may help improve immune activity within acidic tumor microenvironments.

Designed to Work Systemically

Dyve Biosciences’ transdermal platform delivers medicine through the skin, allowing it to circulate throughout the body. This enables the treatment to reach tumors beyond the site of application and influence the tumor microenvironment systemically.

In follow-on analyses, DYV800 increased tumor pH and helped restore T-cell activity suppressed in acidic environments. These findings were consistent with earlier observations of slower tumor growth, improved survival, and effects beyond the site of application.

In the published work, acidic conditions suppressed tumor-reactive T-cell function at multiple levels, including proliferation, migration, cytokine production, and antigen-specific reactivity, supporting the view that tumor acidity may act as an upstream immune checkpoint.

"Tumor acidity is a major barrier that can prevent the immune system from doing its job," said Shari Pilon-Thomas, PhD, Co-Director, Center for Immunization and Infection Research in Cancer (CIIRC) at Moffitt Cancer Center and Corresponding Author. "By making tumors less acidic, we were able to restore immune activity and improve anti-tumor response in our preclinical models. We believe targeting tumor acidity could represent a potential breakthrough in cancer treatment, particularly when used in combination with immunotherapy, where raising tumor pH may help improve the effectiveness of checkpoint inhibitors."

"We believe this approach represents a game-changing new way to treat cancer by targeting the tumor microenvironment," said Dr. Ryan Beal, CEO of Dyve Biosciences. "Instead of going after the tumor directly, we’re changing the conditions that allow it to survive. That shift has the potential to improve how existing treatments work and expand what’s possible for patients."

DYV800 is an investigational product. Safety and efficacy have not been established.

Long-Standing Cancer Challenge

Tumor acidity has long been recognized as a driver of immune suppression in cancer and may act as an upstream immune checkpoint, but delivering therapies that can safely and effectively change that environment remains a challenge.

Oral buffering approaches showed early promise but have been difficult to translate into clinical use due to dosing limitations, gastrointestinal side effects, and poor tolerability. This has limited the ability to consistently modulate tumor acidity in patients.

Dyve Biosciences’ approach delivers pH-modulating therapy through the skin, bypassing limitations associated with traditional oral delivery and eliminating the need for needles.

New Approach to Drug Delivery

Traditional methods for modulating tumor acidity, including oral buffering strategies, have faced challenges with dosing and tolerability.

DYV800 is designed as a non-invasive transdermal approach intended to address those translational barriers. If the underlying mechanism translates clinically, pH modulation may have broader relevance across solid tumors characterized by acidic tumor microenvironments, where acidity may act as an upstream immune checkpoint.

Preparing for Human Trials

Dyve Biosciences is working with Moffitt Cancer Center through a five-year, multi-trial strategic alliance to advance clinical development. First-in-human studies are expected to begin in 2026.

Early clinical studies are expected to evaluate safety, dosing, and how modulating tumor pH may affect the tumor microenvironment and immune response in patients.

This approach may have relevance across multiple cancers, particularly solid tumors where tumor acidity affects immune response. It may also warrant study alongside existing cancer treatments, including immunotherapy, where reducing tumor acidity may help improve T-cell activity and treatment response.

If supported in clinical trials, pH modulation could represent a new way to make certain cancers more responsive to treatment by changing the tumor environment.

(Press release, Dyve Biosciences, APR 14, 2026, View Source [SID1234664377])