Multimodal imaging guides surgical management in a preclinical spinal implant infection model
Stephen D. Zoller, Howard Y. Park, Tove Olafsen, Charles Zamilpa, Zachary D.C. Burke, Gideon Blumstein, William L. Sheppard, Christopher D. Hamad, Kellyn R. Hori, Jen-Chieh Tseng, Julie Czupryna, Craig McMannus, Jason T. Lee, Mafalda Bispo, Francisco Romero Pastrana, Elisa J.M. Raineri, Jeffery F. Miller, Lloyd S. Miller, Jan Maarten van Dijl, Kevin P. Francis, Nicholas M. Bernthal
Stephen D. Zoller, Howard Y. Park, Tove Olafsen, Charles Zamilpa, Zachary D.C. Burke, Gideon Blumstein, William L. Sheppard, Christopher D. Hamad, Kellyn R. Hori, Jen-Chieh Tseng, Julie Czupryna, Craig McMannus, Jason T. Lee, Mafalda Bispo, Francisco Romero Pastrana, Elisa J.M. Raineri, Jeffery F. Miller, Lloyd S. Miller, Jan Maarten van Dijl, Kevin P. Francis, Nicholas M. Bernthal
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Research Article Bone biology Infectious disease

Multimodal imaging guides surgical management in a preclinical spinal implant infection model

Abstract

Spine implant infections portend disastrous outcomes, as diagnosis is challenging and surgical eradication is at odds with mechanical spinal stability. Current imaging modalities can detect anatomical alterations and anomalies but cannot differentiate between infection and aseptic loosening, diagnose specific pathogens, or delineate the extent of an infection. Herein, a fully human monoclonal antibody 1D9, recognizing the immunodominant staphylococcal antigen A on the surface of Staphylococcus aureus, was assessed as a nuclear and fluorescent imaging probe in a preclinical model of S. aureus spinal implant infection, utilizing bioluminescently labeled bacteria to confirm the specificity and sensitivity of this targeting. Postoperative mice were administered 1D9 probe dual labeled with 89-zirconium (89Zr) and a near infrared dye (NIR680) (89Zr-NIR680-1D9), and PET-CT and in vivo fluorescence and bioluminescence imaging were performed. The 89Zr-NIR680-1D9 probe accurately diagnosed both acute and subacute implant infection and permitted fluorescent image-guided surgery for selective debridement of infected tissue. Therefore, a single probe could noninvasively diagnose an infection and facilitate image-guided surgery to improve the clinical management of implant infections.

Authors

Stephen D. Zoller, Howard Y. Park, Tove Olafsen, Charles Zamilpa, Zachary D.C. Burke, Gideon Blumstein, William L. Sheppard, Christopher D. Hamad, Kellyn R. Hori, Jen-Chieh Tseng, Julie Czupryna, Craig McMannus, Jason T. Lee, Mafalda Bispo, Francisco Romero Pastrana, Elisa J.M. Raineri, Jeffery F. Miller, Lloyd S. Miller, Jan Maarten van Dijl, Kevin P. Francis, Nicholas M. Bernthal

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Figure 6

NIR680-1D9 targeting of S. aureus spine implant infection.

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NIR680-1D9 targeting of S. aureus spine implant infection. Following ide...
Following identification of infection with 18F-FDG and 89Zr-680-1D9 PET imaging, infection was then visualized using the Solaris Fluorescence Image-Guided Surgery System (PerkinElmer). On POD 10, 48 hours after 1D9 antibody probe i.v. injection on POD 8, a mouse with acute spinal implant infection was isolated under the image-guided surgery system and analyzed both with and without fluorescent excitation at 680 nm. Prior to skin incision (A and D), no fluorescent signal was visible. Following skin incision (B and E), fluorescent signal was only present with excitation. Following partial excision of infected tissue, as identified by fluorescent signal (C and F), fluorescent signal remained present both in host tissue and explanted tissue. (G) BLI of the infected mouse on POD 7. (H) BLI of a sterile mouse on POD 7. BLI, bioluminescence imaging; 89Zr, 89-zirconium; 1D9, Staphylococcus antibody probe.