Research ArticlesImaging

Rapid, Label-Free Detection of Brain Tumors with Stimulated Raman Scattering Microscopy

Science Translational Medicine  04 Sep 2013:
Vol. 5, Issue 201, pp. 201ra119
DOI: 10.1126/scitranslmed.3005954

You are currently viewing the editor's summary.

View Full Text
As a service to the community, AAAS/Science has made this article free with registration.

Virtual Histology

During brain tumor surgery, precision is key. Removing healthy tissue can cause neurologic deficits; leaving behind tumor tissue can allow cancer to spread and treatment to fail. To help the surgeon clearly see tumor versus normal tissue, Ji and colleagues developed a stimulated Raman scattering (SRS) microscopy method and demonstrated its ability to identify malignant human brain tissue.

In SRS microscopy, laser beams are directed at the tissue sample to generate a series of output signals called “Raman spectra.” These spectra depend on the molecular composition of the tissue. Ji et al. implanted human brain cancer (glioblastoma) cells into mice, allowed them to infiltrate and grow into tumors, and then removed slices for SRS imaging. From the resulting spectra, the authors were able to differentiate the two major components of brain tissue—lipid-rich white matter and protein-rich cortex—as well as tumors, which are full of proteins. Intraoperatively, using an imaging window into mouse brains, the authors found that SRS microscopy could locate tumor infiltration in areas that appeared normal by eye, which suggests that this tool could be applied during surgery.

Imaging fresh tissue slices ex vivo could also complement or perhaps replace standard hematoxylin and eosin (H&E) staining in the clinic because it avoids artifacts inherent in imaging frozen or fixed tissues. To this end, Ji and colleagues showed that SRS microscopy could identify hypercellular tumor regions in fresh surgical specimens from a patient with glioblastoma. Certain diagnostic features were present in these specimens and readily identified by SRS, including pseudopalisading necrosis and microvascular proliferation. The next step will be to apply SRS microscopy to a large collection of human specimens to see whether this technology may be useful in quickly distinguishing glioblastoma from healthy tissue, both outside and inside the operating room.