Big Bore RT
Big Bore RT
  • Big Bore RT - CT scanner for radiation therapy and oncology

Big Bore RT

Big Bore RT
Big Bore RT is designed as a CT simulator to enhance clinical confidence, accelerate time to treat and maximize value of its investment without compromising on patient experience – four dimensions that are essential towards excellent care.

Clinical image gallery

  • BBRT Chest abdomen pelvis
    BBRT Chest abdomen pelvis
  • BBRT Abdomen for adenocarcinoma of the rectum
    BBRT Abdomen for adenocarcinoma of the rectum
  • BBRT Abdomen iDose IMR
    BBRT Abdomen iDose IMR
  • BBRT Abdomen and Pelvis with O-MAR
    BBRT Abdomen and Pelvis with O-MAR
  • BBRT lung CT Full FOV 3mm slice thickness
    BBRT lung CT Full FOV 3mm slice thickness
  • BBRT BI-lateral knee
    BBRT BI-lateral knee
  • BBRT Abdomen 50 cm FOV and 2mm Slice thickness
    BBRT Abdomen 50 cm FOV and 2mm Slice thickness
  • BBRT Abdomen and Pelvis
    BBRT Abdomen and Pelvis
  • BBRT Abdomen IMR
    BBRT Abdomen IMR
  • BBRT Brain iDose IMR
    BBRT Brain iDose IMR
  • iDose⁴ with O-MAR
    iDose⁴ with O-MAR
Features
Advance user comfort and proficiency during interventional procedures
The interventional controls designed for the Big Bore RT offers user flexibility, workflow efficiency and automatic position transcribing. With accurate and fine incremental movements of the table available at the click of a button, to quickly and clearly visualize the needle tip during interventional procedures, clinicians can focus on what matters most, the patient.
Advance user comfort and proficiency during interventional procedures
Focusing on what matters in radiation oncology
Big Bore RT offers advanced tools to facilitate accurate efficient patient marking and simulation workflow. Featuring 60 cm true scan FOV for full anatomic visualization. It provides spatial positioning accuracy of less than 2mm between the imaging plane and the laser marking plane for confidence in patient marking. This meets the AAPM TG 66.
Focusing on what matters in radiation oncology
The Power of Two
Philips provides two leading technologies that can improve image quality. iDose4* improves image quality* through artifact prevention and increased spatial resolution at low dose. O-MAR reduces artifacts caused by large orthopedic implants. Together they product high image quality with reduced artifacts.
The Power of Two


Specifications
  • Features
    Bore size
    85 cm
    Scan field of view
    60 cm
    Gantry tilt
    -30° to +30° w/0.5° increments
    Generator power
    80 kW

Documentation

Big Bore RT Product Brochure
PDF|790.88 KB

Related products

  • Ingenia Ambition/Elition MR-RT Next generation MRI for radiation therapy is here
    The state-of-the-art Ingenia MR-RT platform featuring Ambition 1.5T and Elition 3.0T MR systems meets specific RT needs by providing high-quality MR images acquired in the treatment position. Smoothly integrate MRI through a comprehensive solution that considers your whole workflow, even for MR-only radiotherapy.
  • iPatient Clinical solution
    Envision personalized, patient-centric imaging with you in control of important advances in dose management and workflow, designed to make every day more productive. The Philips iPatient software helps you do all of this, and more.
  • Iterative Model Reconstruction Reconstruction technology
    IMR sets a new direction in CT image quality with industry-leading low-contrast resolution and virtually noise*-free images. Innovations in hardware and the reconstruction algorithm result in a reconstruction speed – less than three minutes for the majority of reference protocols – that allows model-based benefits to be achieved in even the most demanding applications.
  • O-MAR Metal artifact reduction for orthopedic implants
    O-MAR helps to improve visualization of anatomy by reducing artifacts related to beam hardening, photon starvation and streaking caused by metal inside the body.
Disclaimer
* In clinical practice, the use of IMR may reduce CT patient dose depending on the clinical task, patient size, anatomical location, and clinical practice. A consultation with a radiologist and a physicist should be made to determine the appropriate dose to obtain diagnostic image quality for the particular clinical task. Lower image noise, improved spatial resolution, improved low-contrast detectability, and/or dose reduction, were tested using reference body protocols. All metrics were tested on phantoms. Dose reduction assessments were performed using 0.8 mm slices, and tested on the MITA CT IQ Phantom (CCT183, The Phantom Laboratory), using human observers. Data on file.
** Image noise as defined by IEC standard 61223-3-5. Image noise was assessed using reference body protocol, on a phantom. Data on file