On November 8, 2021 Boston Scientific Corporation (NYSE: BSX) reported that it will participate in two upcoming investor conferences (Press release, Boston Scientific, NOV 8, 2021, View Source [SID1234594710]).

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On November 15, 2021, Dan Brennan, executive vice president and chief financial officer, and Lauren Tengler, vice president, Investor Relations, will participate in a 30-minute question-and-answer session with the host analyst at the virtual 2021 Stifel Healthcare Conference. The session will begin at approximately 8:00 a.m. EST.

On December 1, 2021, Dave Pierce, executive vice president and president, MedSurg & Endoscopy; Dr. Brian Dunkin, chief medical officer, Endoscopy; and Lauren Tengler will participate in a 45-minute question-and-answer session with the host analyst for the 2021 virtual Evercore ISI HealthCONx Conference. The session will begin at approximately 8:00 a.m. EST.

A live webcast and replay of the webcast for each event will be accessible at investors.bostonscientific.com. The replay will be available approximately one hour following the completion of each event.

On November 8, 2021 Black Diamond Therapeutics, Inc. (Nasdaq: BDTX), a precision oncology medicine company pioneering the discovery and development of MasterKey therapies, reported financial results for the third quarter ended September 30, 2021 and provided a corporate update (Press release, Black Diamond Therapeutics, NOV 8, 2021, View Source [SID1234594709]).

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Early/Late Stage Pipeline Development - Target Scouting - Clinical Biomarkers - Indication Selection & Expansion - BD&L Contacts - Conference Reports - Combinatorial Drug Settings - Companion Diagnostics - Drug Repositioning - First-in-class Analysis - Competitive Analysis - Deals & Licensing

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"Black Diamond’s approach remains deeply rooted in our proprietary Mutation-Allostery-Pharmacology (MAP) drug discovery engine, which leverages population-level genetic sequencing that allows for the identification of novel oncogenic mutations. We are well-positioned to advance differentiated MasterKey programs across a range of oncogenic targets for patient populations with unmet need," said David Epstein, Ph.D., President and Chief Executive Officer of Black Diamond Therapeutics. "We are excited by the continuing progression of our pipeline of MasterKey inhibitor programs, including the BDTX-189 MasterKey-01 study, our BDTX-1535 program with an IND filing anticipated by the first half of 2022, and our BRAF and fibroblast growth factor receptor (FGFR) programs."

Recent Developments

BDTX-189:

Black Diamond remains on-track with preparations for initiating the Phase 2 portion of the MasterKey-01 Phase 1/2 study of BDTX-189 by the end of 2021. The Company completed the Phase 1 dose-escalation portion of the study and has selected the recommended Phase 2 dose for BDTX-189.
BDTX-1535:

Black Diamond continues to advance BDTX-1535 through IND-enabling studies and expects to file an IND application by the first half of 2022.
In October 2021, Black Diamond presented pre-clinical data for BDTX-1535 at the ANE International Conference:
In cell-based assays, BDTX-1535 achieved potent and selective inhibition of a range of EGFR mutations expressed in glioblastoma (GBM) and non-small cell lung cancer (NSCLC), including canonical, non-canonical, and drug-resistance mutations, such as EGFR-C797S that can arise following treatment with osimertinib.
BDTX-1535 demonstrated a favorable brain-penetrant pharmacokinetic (PK) profile in mouse, rat, and dog models.
In a range of tumor models, including intercranial GBM models and lung cancer drug resistance models expressing the targeted EGFR mutations, BDTX-1535 showed dose-dependent tumor growth inhibition and achieved complete regression without notable impact on body weight.
Early-Stage Pipeline:

Black Diamond continues to progress its early-stage pipeline programs designed to target cancers driven by mutations in BRAF and FGFR. The Company anticipates IND filings for both programs in 2022.
In October 2021, Black Diamond presented pre-clinical data for both the BRAF and FGFR programs at the ANE International Conference:
BRAF:
The presentation described pre-clinical data for a lead compound from Black Diamond’s BRAF program, which is designed for potency and selectivity against a spectrum of non-canonical Class II/III mutations, in addition to Class I mutations (V600E).
In cell-based assays, the lead compound demonstrated potent inhibition of a spectrum of Class I/II/III BRAF mutations.
In contrast to current-generation BRAF inhibitors, such as encorafenib and vemurafenib, treatment of cells harboring wild type BRAF (WT-BRAF) with the Black Diamond compound was not observed to lead to an increase in pERK, a signal of paradoxical activation.
In a BRAF-KIAA1549 fusion allograft tumor model, the lead compound exhibited dose-dependent inhibition of pERK and anti-tumor efficacy.
FGFR:
The presentation was illustrative of the Black Diamond approach, centered on a four-pronged optimization strategy with the goal of delivering an inhibitor that has broad coverage of FGFR2 and FGFR3 oncogenes, while sparing inhibition of FGFR1 and retaining activity against resistance mutations.
In cell-based assays, FGFR program compounds demonstrated potent and selective inhibition of a spectrum of FGFR2/3 oncogenic mutations, while sparing FGFR1. Additionally, FGFR program compounds demonstrated improved potency against resistance mutations.
In an in vivo study conducted in a UM-UC-14 (FGFR3-S249C) mouse model, FGFR program compounds demonstrated anti-tumor activity. Additionally, in mouse and rat models, FGFR program compounds did not promote hyperphosphatemia.
Corporate:

In September 2021, Black Diamond entered into a strategic partnership with OpenEye Scientific to incorporate OpenEye’s Orion molecular design platform into Black Diamond’s proprietary Mutation-Allostery-Pharmacology (MAP) drug discovery engine to help advance MasterKey inhibitor cancer therapies. OpenEye’s Orion Software-as-a-Service platform enables Black Diamond to perform rapid simulations and analysis of protein motion.
Financial Highlights

Black Diamond ended the third quarter of 2021 with $235.0 million in cash, cash equivalents, and investments compared to $315.1 million as of December 31, 2020. Net cash used in operations was $26.5 million for the third quarter of 2021 compared to $11.5 million for the third quarter of 2020.
Research and development (R&D) expenses were $27.6 million for the third quarter of 2021 compared to $12.9 million for the third quarter of 2020. The increase in R&D expenses was primarily related to an increase in headcount and increased spend across preclinical and clinical development.
General and administrative (G&A) expenses were $7.7 million for the third quarter of 2021 compared to $5.6 million for the third quarter of 2020. The increase in G&A expenses was primarily due to an increase in personnel and other corporate-related costs.

On November 8, 2021 Black Diamond Therapeutics, Inc. (Nasdaq: BDTX), a precision oncology medicine company pioneering the discovery and development of MasterKey therapies, reported that its President and Chief Executive Officer, David M. Epstein, Ph.D., will present an update about the Company’s progress at the following upcoming investor conferences (Press release, Black Diamond Therapeutics, NOV 8, 2021, View Source [SID1234594708]):

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Early/Late Stage Pipeline Development - Target Scouting - Clinical Biomarkers - Indication Selection & Expansion - BD&L Contacts - Conference Reports - Combinatorial Drug Settings - Companion Diagnostics - Drug Repositioning - First-in-class Analysis - Competitive Analysis - Deals & Licensing

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The Stifel 2021 Virtual Healthcare Conference. The corporate presentation will take place on Monday, November 15, 2021 at 4:40 PM ET.
The 2021 Jefferies London Healthcare Conference. The presentation will be available on-demand beginning Thursday, November 18, 2021, starting at 4:00 AM ET.
A webcast of the Stifel presentation can be accessed by visiting the investor relations section of the Company’s website, www.blackdiamondtherapeutics.com. A replay of each presentation will also be available and archived on the site for 30 days.

On November 8, 2021 ATP, a leader in life sciences venture capital, reported the launch of Marengo Therapeutics, Inc. to develop novel antibodies that target V T cell receptor (TCR) variants, selectively boosting anti-tumor T cells and promoting longterm protection against cancer. $80 million in launch financing from ATP will help advance Marengo’s proprietary Selective T Cell Activation Repertoire (STAR) platform and progress the company’s lead candidate into the clinic in 2022 (Press release, Marengo Therapeutics, NOV 8, 2021, View Source [SID1234594707]).

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Early/Late Stage Pipeline Development - Target Scouting - Clinical Biomarkers - Indication Selection & Expansion - BD&L Contacts - Conference Reports - Combinatorial Drug Settings - Companion Diagnostics - Drug Repositioning - First-in-class Analysis - Competitive Analysis - Deals & Licensing

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Marengo is based in Cambridge, Massachusetts, and led by Chief Executive Officer Zhen Su, M.D., MBA, who joined from Merck KGaA, where he was Senior Vice President and Head of Global Oncology following a successful tenure as Chief Medical Officer for EMD Serono. During his time at Merck KGaA, Dr. Su was instrumental in delivering multiple drug approvals and double-digit growth of the oncology business in addition to building a robust pipeline of assets and establishing key partnerships in the immuno-oncology field.

"Existing immuno-oncology therapies have transformed cancer care, yet they are often unable to overcome dysfunctional T cell responses that develop in patients with cancer and that result in less than a third of patients achieving a durable response," Dr. Su said. "Marengo’s deep understanding of T cell biology and TCR signaling has driven our discovery of a new mode of T cell activation that promises to more effectively attack tumors and provide long-term protection against cancer. We believe this discovery represents a remarkable departure in the field of immuno-oncology, and our team is working to translate it into a great leap forward for patients."

From its proprietary antibody library targeting diverse germline-encoded TCR Vβ variants, Marengo can deploy therapeutic antibodies to prime the activation of clonally diverse T cells within both CD8+ and CD4+ effector pools that drive both near-term effector responses to tumors and long-term tumor immunity-promoting memory T cell responses. The activation of T 2 cells using this approach also comes with reduced pro-inflammatory cytokine release that may translate into a better safety and tolerability profile.

"ATP created Marengo Therapeutics to realize the potential of an exciting scientific discovery we have been incubating for several years," said Seth Harrison, M.D., founder and Managing Partner at ATP. "Priming specific T cells to fight cancer could pave the way to an entirely new class of much-needed effective and durable immunotherapies. We have been and continue to be incredibly energized by the promise of Marengo’s science, and I have great confidence that Zhen and the Marengo leadership team, with their experience and expertise, will deliver on our ambitions to transform cancer care for patients."

Lead Program
Marengo’s first-in-class lead candidate, STAR0602, is an antibody fusion molecule that binds and activates a specific Vβ TCR variant T cell subset while also delivering additional signals to the same T cell (known as cis-targeting) to further re-program the T cell to enhance anti-tumor activity. STAR0602 is expected to enter the clinic in late 2022 for the treatment of advanced and metastatic solid tumor cancers. Marengo is developing a broad pipeline of additional STAR programs that engage other immune cell types.

"Marengo’s STAR platform is highly flexible; it can turbo-charge cancer patients’ T cells, but with an inherent selectivity and flexibility that enables the engineering of more robust adaptive immune responses to tumors," said Andrew Bayliffe, Ph.D., Chief Scientific Officer of Marengo and Venture Partner at ATP.

Raj Chopra, FRCP, FRCPath, FRSB, Ph.D., Chief Medical Officer of Marengo and Head of Oncology and Venture Partner at ATP, added: "The platform has far-reaching applications, with the potential to ’tune’ a patient’s T cell responses on a personalized basis and in a way that could be integrated into different therapeutic regimens to treat a wide variety of advanced cancers."

On November 8, 2021 Beam Therapeutics Inc. (Nasdaq: BEAM), a biotechnology company developing precision genetic medicines through base editing, reported recent business and pipeline updates, as well as third quarter 2021 financial results (Press release, Beam Therapeutics, NOV 8, 2021, View Source [SID1234594706]).

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As part of today’s update, Beam announced that its Investigational New Drug (IND) application for BEAM-101 for the treatment of sickle cell disease was cleared by the U.S. Food and Drug Administration (FDA). BEAM-101, the company’s lead ex vivo base editing product candidate, is a patient-specific, autologous hematopoietic investigational cell therapy which incorporates base edits that mimic single nucleotide polymorphisms seen in individuals with hereditary persistence of fetal hemoglobin (HPFH) to potentially alleviate the effects of mutations causing sickle cell disease or beta-thalassemia. This is the first open IND for base editing technology, a next-generation form of CRISPR capable of making single base changes without creating double strand breaks in the DNA. Beam is preparing to initiate a Phase 1/2 clinical trial designed to assess the safety and efficacy of BEAM-101 for the treatment of sickle cell disease, which Beam refers to as the BEACON-101 trial.

"We are thrilled to share that the FDA has cleared our first IND. BEAM-101 has the potential to offer a one-time treatment for patients with sickle cell disease, and this clearance enables the important transition from a preclinical to a clinical-stage company, bringing us closer to our ultimate goal of helping patients," said John Evans, chief executive officer of Beam. "As leaders in the field of base editing, this milestone underscores the expertise of our team and the significant potential of our technology. We are grateful to the team members who have dedicated countless hours to this effort, and we look forward to this program’s continued evaluation in the clinic. As we look toward 2022, we believe we are well-positioned both financially and organizationally to execute on our vision."

"In addition to the clearance of our IND for BEAM-101, we are pleased to announce that we have initiated IND-enabling studies for BEAM-102, our Makassar base editing approach for the treatment of sickle cell disease," said Giuseppe Ciaramella, Ph.D., president and chief scientific officer of Beam. "We have also made continued progress on BEAM-201, our multiplexed base editing approach for the treatment of relapsed/refractory T-cell acute lymphoblastic leukemia and T-cell lymphoblastic leukemia as well as continued advancement across our robust portfolio, as showcased by a number of recent and upcoming data presentations demonstrating our leadership in base editing as well as optimized delivery technologies for our programs. Importantly, we also expect to nominate our first development candidate for in vivo base editing in the liver using LNP delivery for the treatment of patients with glycogen storage disease type Ia (R83C mutation) by the end of the year. We’ve made extraordinary progress as a company this year and remain committed to advancing novel science so that we may reach as many patients as possible."

Upcoming Base Editing Data Presentations

Preclinical data highlighting potential of CAR T multiplex base editing approach targeting CD5 at 2021 SITC (Free SITC Whitepaper) Annual Meeting. At the Society for Immunotherapy of Cancer (SITC) (Free SITC Whitepaper)’s (SITC) (Free SITC Whitepaper) 36th Annual Meeting, Beam will present preclinical data from its multiplex edited allogeneic CAR T research targeting CD5-positive hematologic malignancies in a poster titled "CD5 knockout enhances the potency of multiplex base-edited allogeneic anti-CD5 CAR T-cell therapy for the treatment of T-cell malignancies."
Multiple abstracts accepted for presentation at the 63rd American Society of Hematology (ASH) (Free ASH Whitepaper) Annual Meeting & Exposition (ASH) (Free ASH Whitepaper). At this year’s ASH (Free ASH Whitepaper) meeting, Beam will present preclinical data highlighting its base editing approach to address sickle cell disease, including new preclinical data for BEAM-102, and data highlighting Beam’s in vivo high-throughput lipid nanoparticle (LNP) screening approach to identify novel LNPs that can deliver base editors to tissues beyond the liver, such as hematopoietic stem cells. In addition, Beam will present an overview on the application of base editing for the treatment of beta-hemoglobinopathies and other genetic blood disorders during a scientific program session. Details of the presentations can be found here.
Recent Base Editing Progress & Data Updates

BEAM-102 IND-enabling studies initiated. Beam has initiated IND-enabling studies for BEAM-102 for the treatment of sickle cell disease. BEAM-102 aims to directly correct the causative mutation in sickle cell disease by recreating a naturally-occurring normal human hemoglobin variant, HbG Makassar.
Preclinical data highlighting base editing approach to address GSDIa presented at European Society of Gene & Cell Therapy. Beam recently presented preclinical data demonstrating the ability of its liver-targeted base editing approach to directly correct R83C, one of the primary disease-causing mutations of glycogen storage disease type Ia (GSDIa), and the elimination of the disease phenotype in a novel in vivo model.
Optimized LNP delivery approaches for in vivo base editing to the liver and other tissues presented at TIDES 2021. Beam announced new preclinical data highlighting advancements with its approach to developing novel LNP formulations for increased in vivo liver editing potency, with high levels of editing at what Beam believes could be a clinically-relevant dose level of 1.0 mg/kg. Beam remains on track to nominate its first Development Candidate for in vivo base editing using LNP delivery by the end of 2021. Also at TIDES, Beam reported an update on its proprietary approach to developing LNPs to deliver base editors to tissues beyond the liver, including hematopoietic stem and progenitor cells.
Preclinical data highlighting potential of base editors to target disease drivers of chronic hepatitis B infection presented at 2021 International HBV Meeting. Beam recently presented data demonstrating the potential of its cytosine base editors to reduce viral markers, including hepatitis B surface antigen (HBsAg) expression, and prevent viral rebound of hepatitis B virus (HBV) in in vitro models.
Business Highlights

Executed non-exclusive option and license agreement with Sana Biotechnology for Cas12b. Under the agreement, Beam granted Sana non-exclusive commercial rights to utilize its CRISPR Cas12b system with certain allogeneic T-cell and stem cell-derived programs. The agreement excludes any rights to base editing using Beam’s Cas12b system, which rights remain exclusively with Beam. Sana agreed to pay Beam an upfront payment of $50 million, and Beam may also receive certain target option exercise fees, certain milestone payments upon the achievement of certain development and commercial sale milestones, and certain royalties on net sales of royalty-bearing products by Sana.
Third Quarter 2021 Financial Results

Cash Position: Cash, cash equivalents and marketable securities were $933.4 million as of September 30, 2021, compared to $299.7 million as of December 31, 2020.
Research & Development (R&D) Expenses: R&D expenses were $54.6 million for the third quarter of 2021, compared to $29.8 million for the third quarter of 2020.
General & Administrative (G&A) Expenses: G&A expenses were $15.8 million for the third quarter of 2021, compared to $7.5 million for the third quarter of 2020.
Net Loss: Net loss attributable to common stockholders was $28.1 million, or $0.42 per share, for the third quarter of 2021, compared to $34.5 million, or $0.69 per share, for the third quarter of 2020.
About Sickle Cell Disease and Beta-Thalassemia

Sickle cell disease, a severe inherited blood disease, is caused by a single point mutation, E6V, in the beta globin gene. This mutation causes the mutated form of sickle hemoglobin (HbS) to aggregate into long, rigid molecules that bend red blood cells into a sickle shape under conditions of low oxygen. Sickled cells obstruct blood vessels and die prematurely, ultimately resulting in anemia, severe pain (crises), infections, stroke, organ failure, and early death. Sickle cell disease is the most common inherited blood disorder in the United States, affecting an estimated 100,000 individuals, of which a significant proportion are of African-American descent. Beta-thalassemia is another inherited blood disorder characterized by severe anemia caused by reduced production of functional hemoglobin due to insufficient expression of the beta globin protein. Transfusion-dependent beta-thalassemia (TDBT) is the most severe form of this disease, often requiring multiple transfusions per year. Patients with TDBT suffer from failure to thrive, persistent infections, and life-threatening anemia.

About BEAM-101
BEAM-101 is a patient-specific, autologous hematopoietic cell therapy under investigation for the treatment of sickle cell disease. BEAM-101 incorporates ex vivo base edits that mimic single nucleotide polymorphisms seen in individuals with hereditary persistence of fetal hemoglobin (HPFH) to potentially alleviate the effects of mutations causing sickle cell disease or beta-thalassemia by increasing the levels of fetal hemoglobin (HbF).