Soft Tissue Sarcoma Clinical Trial
Official title:
Evaluating Bacterial Response Throughout Sarcoma Management Using An Optically Tracked, Hand-Held Fluorescent Imaging Device
The investigators have recently developed an innovative optical molecular imaging platform
(called PRODIGI) based on high-resolution fluorescence and white-light technologies in a
hand-held, real-time, high-resolution, non-invasive format. PRODIGI offers a non-contact
means of obtaining instantaneous image-based measurements of diagnostically-relevant
biological and molecular information of a wound and surrounding skin tissues for the first
time and could have significant impact on improving conventional wound care, management, and
guidance of intervention. In preliminary preclinical testing, the investigators have
discovered that when wounds are illuminated by violet/blue light, endogenous collagen in the
connective tissue matrix emit a characteristic green fluorescent signal, while most
pathogenic bacterial species emit a unique red fluorescence signal due to the production of
endogenous porphyrins. Therefore, with autofluorescence imaging, no exogenous contrast
agents are needed during imaging, making this approach particularly appealing as a
diagnostic imaging method for clinical use.
In the context of this study, PRODIGI is used to assess wound complications in patients
diagnosed with soft tissue sarcoma and treated with pre-operative radiotherapy. Both pre-
and postoperative external beam radiotherapy combined with limb salvage surgery have
similarly high rates of local control in the management of extremity soft tissue sarcoma.
The main acute side effect associated with preoperative radiotherapy is wound healing
complications. Wound care overall is a major clinical challenge and presents an enormous
burden to health care worldwide. The objective of this clinical study is to determine if
PRODIGI coupled with an optical tracking platform has clinical utility in identifying,
quantitatively measuring and longitudinally tracking bacterial imbalance on the patient's
intact skin surface at the location of the surgical resection site for adult patients with
lower limb soft tissue sarcoma treated with preoperative intensity-modulated radiation
therapy and limb salvage surgery and, further, to investigate whether this bacterial
imbalance is related to radiotherapy dose and wound complications.
Optical Tracking System
For this study, PRODIGI was combined with a commercial optical tracking system (OTS,
Polaris, NDI Medical, Waterloo, Ontario, Canada) to track the movement of the device in
space relative to a patient over time. This addition is in the form of an infrared-light
camera, which tracks four IR reflective spheres (NDI Medical, Waterloo, Ontario, Canada)
that are fixed to the external housing of PRODIGI device.
The OTS has been described previously. Briefly, it consists of optical tracking technology,
which provides 6 degrees of freedom (x, y, z, pitch. yaw, roll), attached to the camera
along with software developed in house to register and visualize the tracked camera pose
relative to a previously acquired radiological volumetric image data. The in-house software
platform GTxEyes performs tracking and navigation of the imaging camera, camera calibration
(including any image distortion), registration of the camera coordinates with respect to the
CT images, and co-visualization (e.g. visual overlay) of the camera and CT images. Radiation
dose planning information can also be spatially co-registered and overlaid with the hybrid
optical-CT images/videos using methods described previously by our group.
After loading a CT image of the patient, the OTS is registered to the CT coordinate space by
identification of known fiducials using a conventional pointer tool. With registration
complete, the coordinates of the PRODIGI camera can be tracked in real time relative to the
CT image. Viewing options include orthogonal views through the CT image, corrected PRODIGI
image and a virtual image based on the CT surface rendering viewed from the perspective of a
virtual camera at the PRODIGI coordinates. Radiation dose can be displayed on the real and
virtual camera views as either isodose lines or colorwash.
Patient Population
Patients will be recruited from the Princess Margaret Cancer Centre, University Health
Network (Ontario, Canada) sarcoma clinic to be treated with pre-operative external beam RT
followed by surgical resection of lower limb soft-tissue sarcoma. Informed consent was
obtained according to institutional Research Ethics Board (REB) requirements and Good
Clinical Practice (GCP) (ClinicalTrials.gov NCT02270086). Patients with pre-existing skin
issues, who received prior radiotherapy or required chemotherapy were not eligible to the
study.
Imaging Procedures
At the radiotherapy planning stage, a CT scan of the patient sarcoma site is acquired for
standard treatment planning purposes. Prior to the CT scan, small radio-opaque fiduciary
markers (Suremark TM skin marking labels) were placed on the patient's six radiation
treatment setup points, making the <1 mm diameter points easy to identify in the CT images.
After the CT scan, these markers were replaced with ink tattoos and used during radiation
treatment to align the patient with radiation therapy machine reference frame. In addition
to the CT fiducial markers placed at the treatment setup points, a flexible radio-opaque
wire was overlaid on the planned surgical incision. This enabled localization of the entire
surgical scar during the radiation treatment plan procedure. A radiotherapy stereotactic
mask was also made at that stage. Following CT simulation scan acquisition, an appropriate
radiotherapy plan was designed as per institutional clinical standard guidelines.
Imaging with PRODIGI and the OTS was performed throughout the sarcoma management, i.e.
during radiotherapy and in the operating room. Imaging was performed at three time points
during RT: fractions 0, 12 and 25, i.e. at the beginning, middle and end of the treatment.
Four out of six treatment setup points marked with radio-opaque fiduciary markers on the CT
scans were used to perform the optical to CT co-registration. An optically-tracked pointer
tool using four IR reflective spheres (identical to the ones fixed to the PRODIGI system)
was used to register the patient in space with respect to the IR camera. For this, the
pointer was placed sequentially on each tattoo mark, identified and spatially registered by
the tracking IR camera and visualized in real-time on the CT scans using the custom-built
software GTxEyes. The locations of the tattoo points in the optical tracking coordinate
system were then registered to the corresponding points in the CT image using the fiduciary
CT markers. Once registration was completed, the planned surgical scar was drawn on the
patient's skin with a marker by superimposing the optically-tracked pointer on the scar
visible on the CT scans. An imaging session consisted of both WL and corresponding AF
imaging of the planned skin surgical incision and surrounding tissue. Room lights were
turned off during AF imaging to avoid background signal and artifacts. The four reflective
spheres on the PRODIGI device were pointed towards the IR camera to ensure proper tracking
in 3D during the entire session.
To perform PRODIGI imaging in the operating room, a sterilization method approved by UHN's
control and processing department using a sterile drape was found to be the most effective
way to ensure proper sterile conditions without damaging the instrument or affecting its
performance. An elongated sterile drape (Cardinal Health Canada, 29-59029) was used to cover
the entire PRODIGI imaging system, i.e. the camera and electrical power cord. Six strong
neodymium magnets (Super Magnets, 8 mm diameter) were embedded into the emission filter
slider and six corresponding magnets were autoclaved prior to each use and placed on the
outside of the drape to hold it in place to avoid image quality degradation. Steri-strips
(3M, R1547) were applied on the outside of the draped device to tighten the drape around the
IR reflective spheres to insure adequate tracking during imaging. Imaging was performed at
five time points: before and after sterilization of the surgical site (OR1, OR2), once the
flap was raised (OR3), after tumor excision (OR4) and after closure (OR5).
The combined WL and AF images were part of a superset of data recorded using the tracking
system. The superset also included preoperative patient CT and the patient's RT dose volume.
A skin surface model was generated from the patient's CT, where each surface point held a
quantitative tuple that contained the surface normal vector, the RT dose, the WL scalar, the
AF scalar, and the camera pose corresponding to the AF scalar. Overlay of WL and AF images
on the skin surface model was visualized using the software ParaView.
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