Women’s Memory Decline Linked to ECM Changes from Brain Estrogen Loss

New research from investigators at Northwestern Medicine, published in Aging Cell, shows that loss of estrogen production in the brain after menopause is associated with changes in the brain’s extracellular matrix (ECM), a structure between brain cells that supports communication and memory. The findings suggest that estrogen decline may alter hippocampal brain environment in ways that contribute to memory impairment and may help explain why nearly two-thirds of all people with Alzheimer’s disease (AD) are women.

“This study tells us that females—but not males—may be uniquely sensitive to loss of brain estrogen at old age, potentially contributing to an increased risk of Alzheimer’s disease,” said senior author Hong Zhao, MD, PhD, a research professor of obstetrics and gynecology in the division of reproductive science in medicine at Northwestern University Feinberg School of Medicine.

The researchers found that estrogen loss, aging, and female sex are closely linked to changes in the ECM in the hippocampus, a brain region central to learning and memory. The ECM is a network of molecules that fills the spaces between neurons and glial cells to support cell communication and function. It makes up nearly 20% of brain volume and is important for memory and brain development.

To date, most research into AD has focused on neurons and glial cells, with less attention paid to the ECM. In the Northwestern study, ECM changes were examined as a central feature of brain biology affected by estrogen loss, the first study of its kind, the researchers noted.

For their research, the investigators use genetically engineered mouse models in which estrogen production was disrupted by removing aromatase, an enzyme required for estrogen synthesis. The enzyme was eliminated either throughout the body or restricted to the brain. The investigators examined young and old male and female mice, allowing comparison of sex-specific and age-related effects. The team assessed, behavior and social function, and also collected data on genome-wide gene expression changes in the hippocampus.

The research also built upon the current understanding of estrogen’s role in brain function. In the brain, estrogen has been associated with memory and mood-related functions.

“We have provided some of the most compelling evidence that estrogen is so important for memory function and other mood functions in the female brain,” said author Serdar Bulun, MD, chair of the department of obstetrics and gynecology at Feinberg and a Northwestern Medicine physician. “This should motivate clinicians to be more aware of the essential role of estrogen for women’s brains, because once memory is gone, it’s gone.”

The findings indicate that loss of brain estrogen may disrupt ECM organization in the hippocampus, which may impair communication between brain cells. Because the ECM provides a structural and signaling environment for neurons, any alterations of the ECM potentially affect processes required for memory formation and maintenance.

Prior research has shown that women with AD may have lower brain estrogen levels than women without AD. Hormone replacement therapy (HRT), created restore estrogen levels, has produced mixed results in clinical studies however.

The investigators noted that understanding how estrogen affects brain structures such as the ECM may help explain variability in HRT outcomes and could serve as a new avenue for developing future treatments. Rather than focusing only on restoring hormone levels, future therapies could address downstream changes in brain architecture.

ECM restoration could represent one such therapeutic approach. If estrogen loss leads to ECM disruption in the hippocampus, then interventions aimed at normalizing ECM structure before memory decline may support brain function in postmenopausal women.

The Northwestern team are continuing their investigation of how estrogen regulates ECM composition and signaling in specific brain regions, and whether these changes directly drive memory impairment. The noted that more research is also needed to determine how ECM-related mechanisms interact with other known AD pathways.

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Virtual Reality Could Pinpoint Early Signs of Alzheimer’s

Researchers in Japan have developed a test that can predict future neurodegeneration in cognitively healthy individuals using virtual reality. The test evaluates an individual’s spatial navigation ability—one of the first skills affected by Alzheimer’s and related diseases before memory loss or cognitive decline can start being noticed. 

“Our approach may allow earlier identification of risk of neurodegenerative diseases, including Alzheimer’s disease,” said Kazuya Kawabata, MD, PhD, senior assistant professor at the department of neurology in Fujita Health University. “Over the longer term, it may contribute to a shift toward earlier detection, potentially enabling timely therapeutic interventions at preclinical stages and delaying disease progression, thereby preserving cognitive function and quality of life.”

Subtle changes in the brain leading to Alzheimer’s can emerge years before symptoms become evident. Among the brain regions that are first impacted are the hippocampus and the entorhinal cortex, both of which are involved in spatial navigation. In addition, a region within the entorhinal cortex is one of the first sites where tau neurofibrilary tangles start accumulating in Alzheimer’s. 

In their study, published in Alzheimer’s Research & Therapy, Kawabata and colleagues investigated whether deteriorating spatial navigation skills could be an early indication of future cognitive decline in healthy individuals. 

They designed an immersive virtual reality (VR) test to assess path integration, a key component of navigation that refers to our ability to track our position and direction as we move around based on internal cues. Participants navigated a circular virtual environment where they were asked to visit two checkpoints and then return to their starting point without relying on any landmarks or visual cues. Their performance was measured by calculating the distance to the original starting point and how much their direction deviated from that leading back to the starting point. 

The study followed 71 cognitively healthy adults for approximately one year after completing the VR navigation test. High-resolution MRI scans and plasma biomarkers, including p-tau181 and glial fibrillary acidic protein (GFAP), were also analyzed in each participant one year apart in order to compare their navigation skills with established indicators of early Alzheimer’s. 

Results revealed that individuals with poorer performance in the VR path integration test showed greater levels of cortical thinning and volume loss in brain regions affected by early Alzheimer’s and increased levels of p-tau181 and GFAP markers. The test was also able to identify those who experienced the fastest brain decline with high accuracy, especially in parahippocampal regions of the brain. 

These findings indicate that the VR test is able to capture both molecular and structural signatures of early neurodegenerative processes that emerge before clinical symptoms can lead to an Alzheimer’s diagnosis. Although more research will be needed to validate this approach before it can be used in a clinical setting, this dual link supports its potential as a tool for early detection and monitoring of an individual’s risk of Alzheimer’s and related conditions, even when they are still cognitively healthy. 

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Myeloid Malignancy Testing: Insights from a Portuguese Reference Center


Panelists:

Image of Margarida Coucelo, MSc, ErCLG

Margarida Coucelo, MSc, ErCLG

Hemato-Oncology Laboratory at Unidade Funcional de Hematologia Molecular
Unidade Local de Saúde de Coimbra

Panelist

Image of Margarida Coucelo, MSc, ErCLG

Margarida Coucelo, MSc, ErCLG

Margarida Coucelo, MSc, ErCLG, is head of the Hemato-Oncology Laboratory at Unidade Funcional de Hematologia Molecular, Unidade Local de Saúde de Coimbra, one of Portugal’s national reference centers for hemato-oncology. She has extensive experience investigating myeloid malignancies across the full disease spectrum, from chronic conditions, such as myeloproliferative neoplasms (MPN) and myelodysplastic syndromes (MDS), through to acute leukemias. She earned her master’s degree in cellular and molecular biology at the University of Coimbra.



Broadcast Date: 

  • Time: 

The 2022 World Health Organization (WHO) and International Consensus Classification updates for myeloid malignancies went beyond adjusting diagnostic thresholds and fundamentally redefined what constitutes a complete genomic profile. For many laboratories, keeping pace with these changes has required the adoption of broad-coverage NGS applications.

Margarida Coucelo, MSc, ErCLG, has led that transition at Unidade Funcional de Hematologia Molecular, Unidade Local de Saúde de Coimbra, one of Portugal’s national reference centers for hemato-oncology, where she has investigated myeloid malignancies across the full disease spectrum, from chronic conditions such as myeloproliferative neoplasms (MPN) and myelodysplastic syndromes (MDS) through to acute leukemias.

This IPM webinar will describe how expanded NGS workflows are being applied in a high-volume reference setting, and the implications for laboratories navigating the evolving landscape of myeloid malignancy testing.

Key takeaways include:

  • How a comprehensive DNA-based NGS approach can contribute to the identification of relevant variants and inform treatment options and risk stratification
  • Cases studies that cover the detection of rare fusion genes and somatic variants, and how to consolidate germline predisposition testing within a single workflow

A live Q&A session will follow the presentation offering you a chance to pose questions to our expert panelists.

Produced with support from:

Sophia Genetics logo

The post Myeloid Malignancy Testing: Insights from a Portuguese Reference Center appeared first on Inside Precision Medicine.

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Dual CA19-9 Threshold Improves Risk Stratification in Pancreatic Cancer

Researchers from Taiwan have proposed a dual cut-off for the pancreatic tumor marker carbohydrate antigen 19-9 (CA19-9) in which the lower threshold identifies a small subgroup “nonproducers” with poor prognosis and the higher threshold detects the more common high-risk producers.

The approach “prevents the critical underestimation of disease severity and ensures more accurate risk stratification,” write Yung-Yeh Su, MD, from National Institute of Cancer Research in Tainan, and co-authors in Clinical Cancer Research.

Serum levels of CA19-9 (also known as sialyl Lewis antigen A) correlate with pancreatic cancer stage and prognosis in that higher levels indicate more advanced disease and a worse prognosis. Currently, a CA19-9 level below 37 units/mL is considered normal or, in the case of a known diagnosis of pancreatic cancer, prognostic for standard-risk disease.

However, approximately 10% of patients with pancreatic cancer do not have elevated CA19-9 levels, even in the presence of advanced disease. The Lewis antigen-negative status of these CA19-9 nonproducers comes from genetic polymorphisms in the FUT3 gene that impair the fucosyltransferase (FUT) activity required to produce CA19-9.

This is “clinically important because genotyping is rarely available, and Lewis-negative patients are often grouped with ‘low CA19-9’ cases, leading to an underestimation of risk,” Su et al. remark.

In 2012, a CA19-9 cut-off of five units/mL was proposed as a surrogate marker for CA19-9 nonproducers, but Su explained that this was largely an empirical observation based on clinicians noticing that Lewis-negative patients tended to exhibit extremely low baseline CA19-9 levels. It did not take genetic sequencing or genomic data into account.

Su and colleagues therefore set out to provide genomically validated evidence, by correlating CA19-9 levels directly with Lewis antigen genotypes, of a CA19-9 cutoff that would capture Lewis antigen-negative patients and better predict their prognosis.

The study included 615 patients with pancreatic ductal adenocarcinoma who underwent germline whole-exome sequencing to determine their FUT2/FUT3 genotypes.

Overall, 10.1% of participants were classified as FUT3-null, 33.0% as FUT-low, 35.6% as FUT-intermediate, and 21.3% as FUT-high.

The researchers report that median CA19-9 levels increased progressively across the FUT functional groups, from 2.4 units/mL in the FUT3-null group to 348 units/mL in the FUT-low group, 453 units/mL in the FUT-intermediate group, and 1300 units/mL in the FUT-high group.

By contrast, median overall survival (OS) was similar among the groups, at 13.5, 15.1, 14.5, and 14.3 months, respectively.

Using receiver operating characteristic analysis, Su and team identified seven units/mL as the optimal CA19-9 cutoff capable of characterizing the FUT3-null population within the clinical reference range of 37 units/mL or lower. At this cut-off, the sensitivity was 76.5% and the accuracy was 87.9%, which the researchers say represents 7.9 and 1.7 percentage point improvements, respectively, on the literature-defined threshold of five units/mL.

The investigators then grouped the patients by CA19-9 cutoff, without genotyping, and showed that OS was lower at each end of the spectrum.

Specifically, median OS was 13.5 months in participants with a CA19-9 of seven units/mL or lower, 23.2 months among those with a level of >7 to 37 units/mL, 22.0 months in those with a CA19-9 of >37 to 200 units/mL, and 12.8 months in the group with a level above 200 units/mL.

After adjusting for confounding factors, the risk for death was a significant 1.96 times higher in participants with the lowest CA19-9 levels and 1.69-fold higher in those with the highest levels, relative to individuals that had a CA19-9 of >7 to 37 U/mL.

“These data tell us that the conventional normal CA19-9 range of less than 37 units/mL does not distinguish between true low tumor burden and Lewis-negative status,” Su said.

He told Inside Precision Medicine that, at present, Lewis antigen genotyping is not standard clinical practice for pancreatic cancer patients due to added costs, turn-around times, and limited availability of routine genetic testing in many centers.

“This clinical gap is precisely why our findings are highly relevant,” Su remarked. “Because genetic testing is often unfeasible or unavailable, proposing a readily accessible serum CA19-9 cut-off (such as seven units/mL) provides clinicians with a highly feasible, cost-effective, and immediate surrogate marker to identify Lewis-negative patients using standard laboratory assays.”

He explained that robust external validation is now needed before the proposed lower cut-off can be adopted into routine clinical practice. “Because our current cohort may reflect specific regional or demographic characteristics, validating this seven U/mL cut-off in diverse cohorts—particularly in Western populations—is critical to ensure its global applicability.”

To address this, an international external validation study is currently underway.

The post Dual CA19-9 Threshold Improves Risk Stratification in Pancreatic Cancer appeared first on Inside Precision Medicine.

CD169-Positive Macrophages Attacking Melanoma Imaged in Living Tissue

Australian researchers at the Garvan Institute of Medical Research have identified a population of immune cells in the skin that actively interacts with melanoma cells and limits tumor growth. Using intravital imaging in a mouse model of melanoma, the team observed macrophages at the tumor margin engulfing live cancer cells. The research, published in the Journal of Experimental Medicine, identified a subset of tissue-resident macrophages marked by CD169 expression that appear to contribute to local tumor control through direct phagocytosis of melanoma cells and containment of tumor expansion.

“This is the first time anyone has captured a macrophage attacking and engulfing a live cancer cell in real time,” said first author Yuki Keith, PhD, a research officer at Garvan. “We always suspected macrophages were doing more than we gave them credit for—now we have the video footage to prove it. Studying this in a living system is crucial because it is more representative of what happens in real life, showing the complexity of the immune system and paving the way for the treatments of the future.”

Melanoma is an aggressive skin cancer arising from melanocytes. It is influenced by the tumor immune microenvironment, where cancer cells interact with immune and non-immune cells, and the extra-tumor environment, including tumor-draining lymph nodes where adaptive immune responses are initiated. Immune checkpoint blockade therapies, which rely on T cells to recognize and kill cancer cells, have improved outcomes in advanced melanoma, but currently only around half of patients respond to these treatments. Tumors that limit T cell infiltration, sometimes described as immune “cold” tumors, remain particularly difficult to treat.

For their work, the Garvan researchers used intravital two-photon microscopy to visualize immune activity in living mouse models with melanoma tumors. They identified CD169-positive macrophages concentrated at the tumor periphery and in the hypodermis, where they were seen physically engulfing melanoma cells. Functional experiments showed that depletion of these macrophages using CSF1R blockade led to increased tumor growth, indicating these macrophages suppress tumor progression. Importantly, the anti-tumor effect appeared independent of T cells and B cells, suggesting an innate immune mechanism operating at the tumor edge engulfs and kills tumor cells.

The study shows that in this context, CD169-positive macrophages represent a distinct tissue-resident population positioned near blood vessels in deeper skin layers, where they appear capable of directly interacting with emerging tumor cells.

Within this environment, tumor-associated macrophages have previously been associated with both tumor-promoting and tumor-inhibiting roles, depending on context and cellular subtype. The identification of CD169-positive macrophages that directly engulf live melanoma cells helps explain this heterogeneity and indicates there is a spatially defined immune function in the hypodermis.

“We have revealed a novel phagocytic tissue-resident macrophage subset in the skin that suppresses tumor growth in the mouse melanoma model,” Keith said. “Importantly, we showed that analogous subpopulations of CD169+ macrophages are also present in normal human skin and in patients with melanoma, highlighting the therapeutic potential of targeting this specific subset.”

The findings could provide a new path for the development of immunotherapies targeting melanoma. By enhancing the activity or abundance of CD169-positive macrophages, or improving their ability to tag and ingest tumor cells, it cold be possible to strengthen innate immune containment of melanoma. The team also indicated these cells could influence adaptive immunity by presenting tumor antigens to other immune populations, although the mouse model indicated tumor control could occur independently of adaptive responses.

Keith said the Garvan researchers will now look to define how CD169-positive macrophages communicate with T cells and how they might be modulated by new therapies. There is also the potential to develop targeted drugs that increase the activity of CD169-positive macrophages, or to combine macrophage activation with existing checkpoint inhibitors as a method of improving treatment response, particularly in tumors resistant to T cell–focused therapies.

The post CD169-Positive Macrophages Attacking Melanoma Imaged in Living Tissue appeared first on Inside Precision Medicine.

Guardant Nabs Key ACS Nod and Liquid Biopsy Approval 

Colorectal (CRC) detection has become a red hot field, as concerns about rising numbers of young adult cases and competition among multi-cancer panels heat up. Guardant Health took two giant steps forward recently with first the approval of its liquid biopsy test, Guardant360 Liquid CDx, and then the listing of its blood-based Shield test by the American Cancer Society (ACS) as a choice for CRC screening of adults age 45 and older who are at average risk of the disease.

In an updated guideline released today, the ACS added blood-based screening tests, and specifically Shield, to its list of recommended choices for the patients in this subset who have not completed or have declined visual exams and stool tests. The group specifically names Shield, which was approved by the U.S. Food and Drug Administration in 2024.

Shield is an in vitro diagnostic test that detects CRC-derived alterations in cell-free DNA from blood collected in the Guardant Blood Collection Kit. The test is performed at Guardant.

These two advances put Guardant in an excellent position in the cancer liquid biopsy market, which is currently valued at between $7B and $12B and expected to double over the next ten years. 

A spokesperson for Guardant told Inside Precision Medicine,Our current focus is on ensuring the approval and successful launch of the Shield test, with an initial focus on eligible adults age 65 and older across the U.S. who are enrolled in Medicare. In parallel, we are continuing to optimize and improve the performance of the Shield test, with the goal of upgrading the test post-approval.”

This week also, Guardant announced that the Molecular and Clinical Genetics Panel of the U.S. The Food and Drug Administration (FDA)’s Medical Devices Advisory Committee strongly recommended FDA approval of the Shield blood test for these types of patients.

“The advisory committee’s strong support for the approval of Shield reinforces the crucial role that a blood test option can have in improving CRC screening rates for those at average risk,” said AmirAli Talasaz, Guardant Health co-CEO. “Despite the importance of detecting colorectal cancer early, there are notable barriers that can deter average-risk Americans from completing existing screening methods. Shield effectively detects cancer at an early stage when it is most treatable. Providing people with this blood test alongside other non-invasive stool tests can increase the rate of colorectal screening and potentially reduce preventable CRC deaths.”

Colorectal cancer is the second-leading cause of cancer-related deaths in the U.S. The disease has a 91% five-year survival rate when caught at stage I (localized), but one out of three eligible Americans—50 million people—are not being screened for CRC. 

Current primary non-invasive screening options include stool-based tests which have proven efficacy in detecting CRC; however, studies have consistently found that barriers such as handling stool and challenges performing the test impact adherence. 

“Sadly, 76% of deaths caused by colorectal cancer occur in individuals who are not up to date with their screening,” said Daniel Chung, MD, gastroenterologist at Massachusetts General Hospital and professor of medicine at Harvard Medical School. “Clinical evidence and CRC screening guidelines acknowledge the value of offering choice to individuals at average risk for CRC and highlight the role of patient preference in test selection and CRC screening completion.”

The FDA panel’s recommendation is based on Guardant’s premarket approval (PMA) application for Shield, including the results of the pivotal ECLIPSE study evaluating the performance of the test for detecting CRC in average-risk adults. Results from the study appeared in the March 2024 issue of The New England Journal of Medicine. (Chung was an author on this study.) Shield demonstrated 83% sensitivity for the detection of CRC, with 90% specificity for advanced neoplasia. Guardant notes that this performance is within range of existing stool-based tests used as primary CRC screening options, in which overall sensitivity ranges from 67% to 92%.

The post Guardant Nabs Key ACS Nod and Liquid Biopsy Approval  appeared first on Inside Precision Medicine.

AI Foundation Model Maps Tumor Mutations to Predict Cancer Therapy Response

As genomic sequencing becomes routine in oncology, clinicians are increasingly inundated with tumor mutation data—but often without clear guidance on how to use it. A new artificial intelligence foundation model called MutationProjector may help bridge that gap by transforming complex tumor mutation profiles into clinically meaningful representations that can predict treatment response, classify cancer subtypes, and potentially guide therapeutic decisions across tumor types.

The study, led by researchers at the University of California, San Diego (UCSD) and published in Cancer Discovery, describes how the model was trained on more than 30,000 tumor genomes spanning 10 solid tumor types and then applied to a range of downstream clinical tasks, including prediction of immunotherapy and chemotherapy response.

“Right now, increasingly physicians will order gene sequencing panels, and in a couple of years it’ll be the whole genome,” senior author UCSD’s Trey Ideker, PhD. “What’s interesting is that as prolific as that information is becoming in the cancer clinic, relatively few treatment decisions are actually made based on it.”

According to the paper, FDA-approved targeted therapies currently match only about 8% of patients based on sequencing findings. Yet the average tumor contains roughly 11 distinct genomic alterations identified through clinical sequencing. “The mutations are there,” Ideker said. “People just don’t know what to do with them, or whether they’re informative.”

MutationProjector was designed to address that challenge with architecture inspired by large-scale AI systems used in natural language processing and computer vision. Rather than focusing on single-gene biomarkers, the model attempts to capture broader mutational patterns associated with hallmark cancer pathways.

“We’ve known for years that cancer is really a disease of pathways,” Ideker said. “If you could move beyond individual gene biomarkers and instead understand the overall state of the tumor from its mutations, then you could potentially treat that tumor better.”

The model translates tumor genomic information into a compact coordinate-based representation—similar to a UMAP embedding—that places tumors with similar molecular features near one another. Ideker described the output as an “XY coordinate system for a tumor” that integrates information from thousands of mutations simultaneously.

The approach relies heavily on pretraining, a hallmark of modern foundation models. MutationProjector first learned generalizable representations from large collections of tumor genomic data, even when detailed clinical outcome information was unavailable. Researchers then fine-tuned the model using smaller, highly annotated datasets tied to specific therapeutic responses.

Ideker compared the strategy to language learning. “If I want to learn Italian but I only have one book in Italian, I’m going to learn a lot first from English and Spanish, where I have much more data,” he said. “Then I can transfer that knowledge to Italian much more effectively.”

Similarly, the model learned from tens of thousands of tumor genomes before being tuned to predict outcomes such as immunotherapy response using comparatively small patient cohorts.

The researchers reported that the pretrained embeddings achieved strong performance across multiple downstream tasks, including immunotherapy response prediction, chemotherapy response prediction, and metastasis classification. In one analysis, the model predicted immunotherapy response after fine-tuning on only 94 samples, yet still outperformed competing approaches across independent cohorts.

Importantly, the same pretrained model was applied across multiple tasks rather than building separate models for each application. “These findings reflect the current movement toward general-purpose AI systems capable of addressing a broad range of challenges,” the authors wrote.

The study also highlighted the model’s interpretability. By examining how tumors clustered within the embedding space, researchers identified biologically meaningful patterns associated with treatment response and tumor subtype.

For example, MutationProjector distinguished HPV-positive from HPV-negative tumors in cervical and head and neck cancers, partly through pathway signatures involving apoptosis regulation and Wnt signaling. The model also differentiated basal and luminal subtypes in bladder and breast cancers.

Perhaps more significantly for clinical oncology, the system identified both individual and combinatorial biomarkers linked to immunotherapy outcomes.

Among the findings were associations involving KMT2A and SMARCA4 alterations, which may influence immune response through chromatin remodeling and DNA methylation pathways. The model also captured co-alteration patterns such as KRAS-STK11 and STK11-KEAP1, combinations previously associated with resistance to immunotherapy.

“Those mutations individually may not tell you very much,” Ideker said. “But together, they can become highly predictive of treatment response.”

The authors argue that this ability to model combinatorial mutation patterns could help address one of precision oncology’s central limitations: the difficulty of interpreting rare or co-occurring mutations that do not fit established single-gene biomarker frameworks.

Although the current study focused on 10 solid tumor types, the researchers see considerable room for expansion. Ideker said the team has already scaled training datasets from 30,000 to roughly 300,000 tumor genomes while also increasing the size of the neural network itself.

“We’re now scaling this idea substantially,” he said. “The original work was really a demonstration that the concept works.”

Future directions include expanding into additional tumor types such as pancreatic cancer, prostate cancer, and sarcoma, integrating multimodal data sources including transcriptomics and radiology, and potentially applying the framework to liquid biopsy analysis.

Ideker also envisions the technology eventually supporting molecular tumor boards, where oncologists currently debate difficult treatment decisions based on limited genomic evidence.

“We want to get models like this into those discussions to assist in decision-making,” he said.

The long-term goal, he added, is not simply prediction, but deeper biological understanding. “Once you can interpret the mutational patterns that place tumors into different regions of the map, you start learning the pathways of drug resistance,” Ideker said. “And understanding those pathways is ultimately what drives the next generation of cancer therapeutics.”

 

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