Silica nanoparticles eliminate prostate tumors in mice

Researchers at Weill Cornell Medicine have developed tiny silica nanoparticles that destroyed aggressive prostate cancer tumors in mice while boosting the immune system. The treatment led to complete remissions when combined with immunotherapy.

The nanoparticles, called Cornell Prime Dots, were tested in mouse models of aggressive prostate cancer. They triggered a form of cell death known as ferroptosis and shifted tumors from an immune-resistant state to one that attracts cancer-fighting cells.

In survival studies, the particles alone modestly extended survival. Combining them with immune checkpoint blockade produced complete or near-complete remissions in four of ten mice. Adding a third therapy targeting tumor-associated macrophages raised complete remissions to five of ten mice.

Senior author Dr. Michelle Bradbury said the approach could represent a new clinical paradigm. The team plans to move the work toward human clinical trials. The study was published June 15 in Cancer Research.

相关文章

Microscopic view of enhanced natural killer cells attacking cancer cells due to a drug developed by McGill researchers.
AI 生成的图像

McGill researchers use reversible drug approach to boost natural killer cells against hard-to-treat cancers

由 AI 报道 AI 生成的图像 事实核查

Researchers at McGill University report a drug-based method to temporarily enhance natural killer (NK) cells—an immune cell type—by inhibiting two proteins, improving the cells’ ability to attack several aggressive cancers in preclinical experiments.

Researchers from the Institute for Bioengineering of Catalonia and collaborating institutions report that engineered “supramolecular” nanoparticles restored aspects of blood-brain barrier function in Alzheimer’s-model mice, rapidly lowering brain amyloid-β and producing improvements on behavioral and memory tests.

由 AI 报道

Researchers at USC Stem Cell have developed a method to produce large numbers of immune cell precursors that can be engineered to target cancer. The approach, published in the journal Cell, uses granulocyte-monocyte progenitors that self-renew in the laboratory.

Scientists at Brown University and the University of Michigan have created and stabilized a previously theoretical crystal phase by assembling custom silver nanoparticles. The breakthrough, published in Science, reveals details of metal crystal transformations and shows room-temperature quantum optical properties.

此网站使用 cookie

我们使用 cookie 进行分析以改进我们的网站。阅读我们的 隐私政策 以获取更多信息。
拒绝