This ebook offers the most recent findings on employing nano/microrobots in biophysics for cancer treatment 👨🔬 Remember, you can read the first chapter of all our ebooks for free! Find out more- https://ow.ly/vR1m50SxFlw Biophysical Society
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Multi sample proteome standardization using Regen V peptides for axon regeneration. We expect approach developed by us will be adopted by folks working in all areas of biomedical sciences (cancer, cardiovascular, neuroscience) utilizing labeled proteomics such as 18-plex TMT:
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Using the methods of molecular biophysics, we showed that dinuclear Co(III) supramolecular cylinders [Co2L3]6+ selectively bind to various alternative DNA structures, such as junctions, G-quadruplexes and bulges that are involved in the development of numerous human malignancies, including cancer. The results suggest that the stabilization of alternative DNA structures by Co(III) cylinders might contribute to the mechanism of their anticancer activity.
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⏪ #Leica2023 in review 🔷 Do you also think that organoids have a huge potential for biomedical research? 🔷 Watch the full video to see how fellow scientists from the Technical University of Munich gain insights into developmental processes in cancer organoids. Find out how they use microscopy to understand different spatiotemporal processes in physiologically relevant disease models. 👉 https://fcld.ly/4xlt8q0 #Microhubimaging #fluorescencemicroscopy
Gain insights into developmental processes in cancer organoids!
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Associate Professor of Anatomic Pathology and PhD in Clinical, Experimental Applied Oncology and Translational Research on Tumors. Author of 232 publications on international, peer-reviewed journals with impact factor
Hot topics in neurooncology Diffuse Gliomas with FGFR3::TACC3 Fusion: Morphological and Molecular Features and Classification Challenges https://lnkd.in/d_UyBM2i
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With the increasing prevalence of this illness, if this innovative invention has the potential to revive and wil significantly improve the lives of many affected individuals. Its ability to address the root causes and provide effective solutions could be a game-changer in the medical field, offering new hope to those who have been impacted. Let's hope for its success......
Nanorobot with hidden weapon kills cancer cell‼️ Robot’s weapon is hidden in a nanostructure & exposed only in the tumour microenvironment, sparing healthy cells. “If you were to administer it as a drug, it would indiscriminately start killing cells in the body, which would not be good. To get around this problem, we have hidden the weapon inside a nanostructure built from DNA.” says Professor Björn Högberg at the Department of Medical Biochemistry and Biophysics, Karolinska Institutet via Brood AI Christine Raibaldi Kasra Jadid Haghighi Steve Davis
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LinkedIn Top Voice. Expert in providing executive search, professional recruiting solutions, and best experiences for companies and people. Enhancer of clients' employment brands and mentor of people.
Nanorobots in the fight against cancer Florian Palatini, thank you for sharing this development shared by professor Björn Högberg at the Department of Medical Biochemistry and Biophysics, Karolinska Institutet I find the concept of nanorobots targeting cancer cells both intriguing and cautiously optimistic. I love innovative technologies, but I prefer to acknowledge this potential for groundbreaking advancements with the need for careful consideration. These development in nanorobot news represents a fascinating intersection of nanotechnology, targeted drug delivery, and cancer treatment. Targeted approach: The use of a hidden weapon that's only exposed in the tumor microenvironment is a crucial advancement. This specificity could potentially reduce systemic side effects, which are a major challenge in current cancer treatments. DNA nanostructure: Utilizing DNA as a building material for the nanostructure is ingenious. DNA is biocompatible, programmable, and can be designed to respond to specific stimuli in the tumor environment. Potential impact: If successful, this technology could revolutionize cancer treatment by offering a highly targeted approach that minimizes damage to healthy cells - a long-standing goal in oncology. Challenges ahead: While promising, we must consider several factors: Delivery efficiency: Ensuring these nanorobots reach their intended targets in sufficient quantities. Immune response: The body's immune system might recognize and eliminate these nanostructures before they can act. Long-term effects: We need extensive studies to understand any potential long-term consequences of introducing these nanorobots into the body. Scalability and cost: Translating this technology from lab to clinic will require overcoming significant production and economic hurdles. Ethical considerations: As with any new technology, we must carefully consider the ethical implications and ensure equitable access if proven effective. In conclusion, while this nanorobot technology is still in its early stages, it represents an exciting direction in cancer research. It embodies the spirit of innovation mentioned in the comment - challenging norms and pushing boundaries. However, we must balance enthusiasm with rigorous scientific evaluation. Extensive research, clinical trials, and peer review will be crucial in determining the true potential of this technology in cancer treatment.
Nanorobot with hidden weapon kills cancer cell‼️ Robot’s weapon is hidden in a nanostructure & exposed only in the tumour microenvironment, sparing healthy cells. “If you were to administer it as a drug, it would indiscriminately start killing cells in the body, which would not be good. To get around this problem, we have hidden the weapon inside a nanostructure built from DNA.” says Professor Björn Högberg at the Department of Medical Biochemistry and Biophysics, Karolinska Institutet via Brood AI Christine Raibaldi Kasra Jadid Haghighi Steve Davis
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🚀 Innovative Breakthrough in Cancer Treatment: Nanorobots with Hidden Weapons! 🦠 A revolutionary approach in cancer therapy has emerged, where nanorobots equipped with hidden weapons target and destroy cancer cells while sparing healthy ones. These nanostructures, built from DNA, remain inactive until they encounter the tumor microenvironment, ensuring precision in treatment. Professor Björn Högberg from Karolinska Institutet explains, "If administered as a drug, it would indiscriminately start killing cells in the body, which would not be good. To get around this problem, we have hidden the weapon inside a nanostructure built from DNA." This advancement could be a game-changer in the fight against cancer! #CancerResearch #Nanotechnology #Innovation #Healthcare #Biotech
Nanorobot with hidden weapon kills cancer cell‼️ Robot’s weapon is hidden in a nanostructure & exposed only in the tumour microenvironment, sparing healthy cells. “If you were to administer it as a drug, it would indiscriminately start killing cells in the body, which would not be good. To get around this problem, we have hidden the weapon inside a nanostructure built from DNA.” says Professor Björn Högberg at the Department of Medical Biochemistry and Biophysics, Karolinska Institutet via Brood AI Christine Raibaldi Kasra Jadid Haghighi Steve Davis
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#Nanobots to kill cancer cells in a mouse model https://lnkd.in/gwdTbVfi #Cell #Science #Innovation #Cancer #Technology #NanoTechnology #Robots #Robotics
Nanorobot with hidden weapon kills cancer cell‼️ Robot’s weapon is hidden in a nanostructure & exposed only in the tumour microenvironment, sparing healthy cells. “If you were to administer it as a drug, it would indiscriminately start killing cells in the body, which would not be good. To get around this problem, we have hidden the weapon inside a nanostructure built from DNA.” says Professor Björn Högberg at the Department of Medical Biochemistry and Biophysics, Karolinska Institutet via Brood AI Christine Raibaldi Kasra Jadid Haghighi Steve Davis
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That sounds like a cutting-edge approach to cancer treatment! The concept of using nanorobots equipped with hidden weapons that can selectively target and destroy cancer cells while sparing healthy ones is a promising advancement in nanomedicine. By taking advantage of the unique properties of the tumor microenvironment, these nanostructures could potentially release their "weapon" only when they encounter cancer cells, reducing collateral damage to healthy tissues. This technology could lead to more effective and less toxic cancer treatments in the future. This advancement leverages the thermal characteristics of the nanorobots to deliver precise attacks on cancer. Linear accelerators what will you do now ????
Nanorobot with hidden weapon kills cancer cell‼️ Robot’s weapon is hidden in a nanostructure & exposed only in the tumour microenvironment, sparing healthy cells. “If you were to administer it as a drug, it would indiscriminately start killing cells in the body, which would not be good. To get around this problem, we have hidden the weapon inside a nanostructure built from DNA.” says Professor Björn Högberg at the Department of Medical Biochemistry and Biophysics, Karolinska Institutet via Brood AI Christine Raibaldi Kasra Jadid Haghighi Steve Davis
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Technology is increasingly replacing humans in various tasks, offering a more productive and efficient approach to many aspects of work and daily life. Automated systems, artificial intelligence, and advanced machinery are taking over repetitive and time-consuming tasks, allowing for greater accuracy, speed, and cost-effectiveness. This shift not only enhances productivity but also enables humans to focus on more creative and strategic activities, driving innovation and growth in numerous industries. While this transition presents challenges, it ultimately fosters a more efficient and streamlined way of achieving goals.
Nanorobot with hidden weapon kills cancer cell‼️ Robot’s weapon is hidden in a nanostructure & exposed only in the tumour microenvironment, sparing healthy cells. “If you were to administer it as a drug, it would indiscriminately start killing cells in the body, which would not be good. To get around this problem, we have hidden the weapon inside a nanostructure built from DNA.” says Professor Björn Högberg at the Department of Medical Biochemistry and Biophysics, Karolinska Institutet via Brood AI Christine Raibaldi Kasra Jadid Haghighi Steve Davis
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