Using nanoparticles to deliver cancer drugs offers a way to hit tumors with large doses of drugs while avoiding the harmful side effects that often come with chemotherapy. However, so far, only a handful of nanoparticle-based cancer drugs have been FDA-approved.
A new study from MIT and Broad Institute of MIT and Harvard researchers may help to overcome some of the obstacles to the development of nanoparticle-based drugs. The teams analysis of the interactions between 35 different types of nanoparticles and nearly 500 types of cancer cells revealed thousands of biological traits that influence whether those cells take up different types of nanoparticles.
The findings could help researchers better tailor their drug-delivery particles to specific types of cancer, or design new particles that take advantage of the biological features of particular types of cancer cells.
We are excited by our findings because it is really just the beginning we can use this approach to map out what types of nanoparticles are best to target certain cell types, from cancer to immune cells and other kinds of healthy and diseased organ cells. We are learning how surface chemistry and other material properties play a role in targeting, says Paula Hammond, an MIT Institute Professor, head of the Department of Chemical Engineering, and a member of MITs Koch Institute for Integrative Cancer Research.
Hammond is the senior author of the new study, which appears today in Science. The papers lead authors are Natalie Boehnke, an MIT postdoc who will soon join the faculty at the University of Minnesota, and Joelle Straehla, the Charles W. and Jennifer C. Johnson Clinical Investigator at the Koch Institute, an instructor at Harvard Medical School, and a pediatric oncologist at Dana-Farber Cancer Institute.
Cell-particle interactions
Hammonds lab has previously developed many types of nanoparticles that can be used to deliver drugs to cells. Studies in her lab and others have shown that different types of cancer cells often respond differently to the same nanoparticles. Boehnke, who was studying ovarian cancer when she joined Hammonds lab, and Straehla, who was studying brain cancer, also noticed this phenomenon in their studies.
The researchers hypothesized that biological differences between cells could be driving the variation in their responses. To figure out what those differences might be, they decided to pursue a large-scale study in which they could look at a huge number of different cells interacting with many types of nanoparticles.
Straehla had recently learned about the Broad Institutes PRISM platform, which was designed to allow researchers to rapidly screen thousands of drugs on hundreds of different cancer types at the same time. With instrumental collaboration from Angela Koehler, an MIT associate professor of biological engineering, the team decided to try to adapt that platform to screen cell-nanoparticle interactions instead of cell-drug interactions.
Using this approach, we can start thinking about whether there is something about a cells genotypic signature that predicts how many nanoparticles it will take up, Boehnke says.
For their screen, the researchers used 488 cancer cell lines from 22 different tissues of origin. Each cell type is barcoded with a unique DNA sequence that allows researchers to identify the cells later on. For each cell type, extensive datasets are also available on their gene expression profiles and other biological characteristics.
On the nanoparticle side, the researchers created 35 particles, each of which had a core consisting of either liposomes (particles made from many fatty molecules called lipids), a polymer known as PLGA, or another polymer called polystyrene. The researchers also coated the particles with different types of protective or targeting molecules, including polymers such as polyethylene glycol, antibodies, and polysaccharides. This allowed them to study the influence of both the core composition and the surface chemistry of the particles.
Working with Broad Institute scientists, including Jennifer Roth, director of the PRISM lab, the researchers exposed pools of hundreds of different cells to one of 35 different nanoparticles. Each nanoparticle had a fluorescent tag, so the researchers could use a cell-sorting technique to separate the cells based on how much fluorescence they gave off after an exposure of either four or 24 hours.
Based on these measurements, each cell line was assigned a score representing its affinity for each nanoparticle. The researchers then used machine learning algorithms to analyze those scores along with all of the other biological data available for each cell line.
This analysis yielded thousands of features, or biomarkers, associated with affinity for different types of nanoparticles. Many of these markers were genes that code for the cellular machinery needed to bind particles, bring them into a cell, or process them. Some of these genes were already known to be involved in nanoparticle trafficking, but many others were new.
We found some markers that we expected, and we also found much more that has really been unexplored. We're hoping that other people can use this dataset to help expand their view of how nanoparticles and cells interact, Straehla says.
Particle uptake
The researchers picked out one of the biomarkers they identified, a protein called SLC46A3, for further study. The PRISM screen had shown that high levels of this protein correlated with very low uptake of lipid-based nanoparticles. When the researchers tested these particles in mouse models of melanoma, they found the same correlation. The findings suggest that this biomarker could be used to help doctors identify patients whose tumors are more likely to respond to nanoparticle-based therapies.
Now, the researchers are trying to uncover the mechanism of how SLC46A3 regulates nanoparticle uptake. If they could discover new ways to decrease cellular levels of this protein, that could help make tumors more susceptible to drugs carried by lipid nanoparticles. The researchers are also working on further exploring some of the other biomarkers they found.
This screening approach could also be used to investigate many other types of nanoparticles that the researchers didnt look at in this study.
The sky is the limit in terms of what other undiscovered biomarkers are out there that we just haven't captured because we haven't screened them, Boehnke says. Hopefully its an inspiration for others to start looking at their nanoparticle systems in a similar manner.
The research was funded, in part, by SPARC funding to the Broad Institute, the Marble Center for Cancer Nanomedicine at the Koch Institute, and the Koch Institute Support (core) Grant from the National Cancer Institute.
Here is the original post:
How different cancer cells respond to drug-delivering nanoparticles - MIT News
- Nanomedicine: Principles, Properties, and Regulatory Issues - October 6th, 2024
- Center for Nanomedicine - Johns Hopkins Medicine - October 6th, 2024
- Delivering the power of nanomedicine to patients today - October 6th, 2024
- Emerging Applications of Nanotechnology in Healthcare and Medicine - October 6th, 2024
- Tiny skin-stabbing stars designed to get meds through the epidermis - October 6th, 2024
- Inhibition of HIV-1 infection with curcumin conjugated PEG-citrate ... - October 6th, 2024
- Montgomery County, Kansas - Kansas Historical Society - October 6th, 2024
- The Nanomedicine Revolution - PMC - National Center for Biotechnology ... - October 6th, 2024
- Fawn Creek township, Montgomery County, Kansas (KS) detailed profile - October 6th, 2024
- Fawn Creek, Montgomery County, Kansas Population and Demographics - October 6th, 2024
- An Introduction to Nanomedicine - AZoNano - October 6th, 2024
- Nanomedicine Market is expected to show growth from 2024 to 2030, reported by Maximize Market Research - openPR - October 6th, 2024
- Oro Rx Healthcare LLP Unveils Oroceuticals: The Next-Gen Nutrition Delivery Tech - Hindustan Times - October 27th, 2023
- Leapfrogging as pharma leader of the worldNational Policy on Research and Development and Innovation in Pharma-MedTech Sector in India - The Sangai... - October 27th, 2023
- What will Indian healthcare look like in 2047? Robotics, AI, biotech will shape the future - The Economic Times - February 16th, 2023
- Going Beyond Target Or Mechanism Of Disease: Disruptive Innovation In Drug Delivery Systems - Forbes - September 12th, 2022
- Nanomedicine Market Size, Share, Types, Products, Trends, Growth, Applications and Forecast 2022 to 2028 - Digital Journal - September 12th, 2022
- Nano-preterm infants may not benefit from noninvasive versus invasive ventilation at birth - University of Alabama at Birmingham - September 12th, 2022
- Juan De Borbon - Introducing Cutting-Edge Techniques To The Healthcare Industry - CEOWORLD magazine - September 12th, 2022
- Organic thin-film sensors for light-source analysis and anti-counterfeiting applications - Nanowerk - September 12th, 2022
- Whole Exome Sequencing Market Projected to Reach CAGR of 19.0% Forecast by 2029, Global Trends, Size, Share, Growth, Future Scope and Key Player... - September 12th, 2022
- Another 'Dr. Copper' - MINING.COM - MINING.com - September 12th, 2022
- Artemisinin Combination Therapy Market Insights and Emerging Trends by 2027 - BioSpace - August 19th, 2022
- NASEM Recommends That EPA Conduct Ecological Risk Assessment of UV Filters Found in Sunscreen, Including Titanium Oxide and Zinc Oxide - JD Supra - August 19th, 2022
- Fast and noninvasive electronic nose for sniffing out COVID-19 based on exhaled breath-print recognition | npj Digital Medicine - Nature.com - August 19th, 2022
- Applications in Chronic Wound Healing | IJN - Dove Medical Press - July 25th, 2022
- Fundamental Knowledge on Nanobots - Bio-IT World - July 25th, 2022
- Nanorobots Market to close to USD 19576.43 million with CAGR of 12.23% during the forecast period to 2029 - Digital Journal - July 25th, 2022
- Microscopic Robots Made from White Blood Cells Could Treat and Prevent Life-Threatening Illnesses - Good News Network - July 25th, 2022
- Nano Therapy Market 2022 Growth Is Expected To See Development Trends and Challenges to 2030 This Is Ardee - This Is Ardee - July 25th, 2022
- Artificial Intelligence (AI), Cloud Computing, 5G, And Nanotech In Healthcare: How Organizations Are Preparing Best For The Future - Inventiva - July 25th, 2022
- Potassium Channels as a Target for Cancer Therapy & Research | OTT - Dove Medical Press - July 25th, 2022
- How can Nanotechnology be Used to Reverse Skin Aging? - AZoNano - May 20th, 2022
- Should Nanomaterial Synthesis Rely on Automation? - AZoNano - May 20th, 2022
- Fabrication Methods of Ceramic Nanoparticles - AZoNano - May 20th, 2022
- Explained: What are nanobots and how they can be used to help clean teeth? - Firstpost - May 20th, 2022
- Understanding the Health Risks of Graphene - AZoNano - May 20th, 2022
- Prevalence and predictors of SARS-CoV-2 | IDR - Dove Medical Press - May 20th, 2022
- Patches and robotic pills may one day replace injections - Science News for Students - May 20th, 2022
- Nanotechnology in the Nutricosmetics Industry - AZoNano - May 20th, 2022
- Nanomedicine: Nanotechnology, Biology and Medicine ... - December 22nd, 2021
- Frontiers | Nanomedicine: Principles, Properties, and ... - December 22nd, 2021
- Nanotechnology In Medicine: Huge Potential, But What Are ... - December 22nd, 2021
- Verseon Praised for Disruptive Approach to Physics- and AI-Based Drug Discovery - Digital Journal - December 22nd, 2021
- Nanotech opens up job options in variety of industries - BL on Campus - August 17th, 2021
- Homeopathic remedies that cattle farmers can use - Thats Farming - August 17th, 2021
- Healthcare Nanotechnology (Nanomedicine) Market Trend, Technology Innovations and Growth Prediction 2021-2027 The Manomet Current - The Manomet... - August 17th, 2021
- Regenerative Medicine Market Size Worth $57.08 Billion By 2027: Grand View Research, Inc. - PRNewswire - August 17th, 2021
- Nanotechnology Market Share, Industry Size, Leading Companies Outlook, Upcoming Challenges and Opportunities till 2028 - The Market Writeuo - The... - August 17th, 2021
- Global Nanomedicine Market is Expected to Grow at an Impressive CAGR by 2028 The Manomet Current - The Manomet Current - August 17th, 2021
- Complementary Protection May Be at Hand With a COVID-19-Preventing Nasal Spray - Newsweek - August 17th, 2021
- Nanorobotics Market By Player, Region, Type, Application And Sales Channel, Regions, Type and Application, Revenue Market Forecast to 2028 - Digital... - August 17th, 2021
- MagForce AG announces results of 2021 Annual General Meeting and changes to the Supervisory Board - Yahoo Eurosport UK - August 17th, 2021
- McMaster University researchers awarded more than $3M in Federal funds for projects - insauga.com - August 17th, 2021
- Global NANOTECHNOLOGY IN MEDICAL APPLICATIONS Statistics, CAGR, Outlook, and Covid-19 Impact 2016 The Bisouv Network - The Bisouv Network - February 14th, 2021
- Nanotechnology in Medical Market Demand Analysis To 2026 Lead By-Smith and Nephew, Novartis, Merck, Mitsui Chemicals, Amgen, Cytimmune KSU | The... - February 14th, 2021
- NanoViricides's Broad-Spectrum Antiviral Drug Candidate for the Treatment of COVID-19 Infections was Well Tolerated in GLP and non-GLP Animal Safety... - February 9th, 2021
- Nanorobots In Blood Market Top-Vendor And Industry Analysis By End-User Segments Till 2028 | Aries Chemical, GE Water & Process Technologies KSU... - February 9th, 2021
- Precision NanoSystems Receives Contribution from the Government of Canada to Build RNA Medicine Biomanufacturing Centre - PRNewswire - February 3rd, 2021
- Vaccine Production in BC's Future - AM 1150 (iHeartRadio) - February 3rd, 2021
- New facility to be built in Vancouver will produce 240 million vaccine doses annually | Urbanized - Daily Hive - February 3rd, 2021
- Faster tracking of treatment responses - MIT News - February 3rd, 2021
- NANOBIOTIX Announces First Patient Injected With NBTXR3 in Esophageal Cancer - Business Wire - February 3rd, 2021
- New Instrument Will Uncover Structure and Chemical Composition on Sub-Cell Scale - Georgia Tech News Center - January 12th, 2021
- Johns Hopkins Department of Otolaryngology-Head and Neck Surgery receives $15M contribution - The Hub at Johns Hopkins - January 9th, 2021
- COVID-19 Impact on Nanomedicine Market Size, Latest Trends, Growth and Share 2020 to 2026| Clinical Cardiology, Urology, Genetics, Orthopedics -... - January 9th, 2021
- Nanomedicine Market: Industry Analysis and forecast 2026: By Modality, Diseases, Application and Region - LionLowdown - January 9th, 2021
- Clene Nanomedicine Presents Blinded Interim Results from RESCUE-ALS Phase 2 Study at the 31st International Symposium on ALS/MNDResults provide... - December 16th, 2020
- Global Nanomedicine market 2020- Industry Overview, Global Trends, Market Analysis, CAGR Values and Country Level Demand To Forecast by 2027 -... - December 16th, 2020
- NHMRC awards Griffith University $4.5 million in research funding - Griffith News - December 16th, 2020
- Global Nanomedicine Market Analysis and Forecast to 2025 by Cancer Detection, Monitoring Therapy & Disease Detection - ResearchAndMarkets.com -... - December 10th, 2020
- Medical Physics Market: Growing Incidence of Chronic Diseases in Developing Regions to Drive the Market - BioSpace - December 10th, 2020
- Joseph DeSimone wins Harvey Prize in Science and Technology | The Dish - Stanford University News - December 10th, 2020
- Cancer Nanomedicine Market to Build Excessive Revenue at Healthy Growth rate at 12.50% up to 2027 - PharmiWeb.com - December 4th, 2020
- Sensing the body at all scales - MIT News - December 4th, 2020
- Healthcare Nanotechnology (Nanomedicine) Market Research Report with Revenue, Gross Margin, Market Share and Future Prospects till 2026 - The Market... - December 4th, 2020
- Technion Harvey prize in science awarded to Israeli, American professors - The Jerusalem Post - December 4th, 2020
- Cancer Nanomedicine Market Size, Comprehensive Analysis, Development Strategy, Future Plans and Industry Growth with High CAGR by Forecast 2026 |... - December 4th, 2020
- Visualization nanozyme based on tumor microenvironment unlocking for intensive combination therapy of breast cancer - Science Advances - December 4th, 2020
- Nanomedicine Market 2019 Global Outlook, Research, Trends and Forecast to 2025 - The Haitian-Caribbean News Network - December 4th, 2020