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Stanford researchers have engineered a heterologous system for the high-efficiency production of numerous taxanes and taxane intermediates.

Stanford researchers have developed a more sensitive and accurate pathogenic infection diagnosis method using intact genetically modified pathogens. Pathogen infection clinical diagnosis requires direct pathogen detection or the detection of pathogen specific antibodies.

Non-small-cell lung cancer (NSCLC) accounts for approximately 85% of all lung cancer cases, making it the leading cause of cancer-related deaths globally. Post-surgical recurrence and treatment resistance are the main causes of cancer-related mortality.

Stanford researchers have developed a novel ultrasound-guided technique to 3D print conductive polymers directly within optically opaque biological tissues.

Stanford researchers have developed MedFM, a multimodal foundation model designed to classify and interpret medical images with expert-level performance across a wide range of modalities, including X-rays, MRIs, CT scans, histopathology, and clinical photos.

Stanford researchers have developed a neuromonitoring-guided cognitive intervention that enhances working memory by dynamically identifying and reinforcing engagement of individualized brain networks in real time.

The absence of a remote, reliable measure of rigidity, bradykinesia and tremor is a major limitation for telemedicine and multicenter clinical trials in Parkinson's disease (PD).

Researchers at Stanford have developed a fast and accurate algorithm for analyzing heartbeat patterns in real time.

Stanford researchers have developed a novel gene therapy vector, AAV-capGL to overcome immune barriers that currently limit the efficacy and safety of adeno-associated virus (AAV)-based gene therapies.

Stanford researchers have invented techniques to adaptively tune the operation of a wireless full-duplex node. To enable full-duplex operation, the receiver circuit needs to be able to cancel the transmitter's signal in order to receive data from other nodes.

The wireless spectrum is increasingly fragmented due to the growing proliferation of unlicensed wireless devices and piecemeal licensed spectrum allocations.

Engineers in Prof. Sachin Katti's laboratory have developed a 3 X 3 in-band full duplex MIMO radio, that can simultaneously transmit and receive on the same channel using standard WiFi 802.11n PHY for 20 Mhz bandwidth.

Engineers in Prof. Sachin Katti's laboratory have developed a full duplex wireless system designed to double throughput by simultaneously transmitting and receiving signal on a standard single inband antenna.

Wireless spectrum is increasingly fragmented due to the growing proliferation of unlicensed wireless devices and piecemeal licensed spectrum allocations.

Stanford researchers have developed a fast and flexible platform for building human brain organoids that mimic the complexity of the brain's cellular makeup. This breakthrough enables faster research and better disease modeling for neurological conditions.