Potential of Magnetic Resonance Lymphography With Intrapulmonary Injection of Gadopentetate Dimeglumine for Visualization of the Pulmonary Lymphatic Basin in Dogs

Real-time lymphography by indocyanine green fluorescence: improved navigation for regional lymph node staging

OBJECTIVES

Lymphatic imaging is an important step for the identification of lymphonodal positive disease in solid malignancies. Various methods have been established to detect positive lymph nodes, but the available diagnostic tools leave some inherent drawbacks. The aim of this study was to validate the indocyanine green (ICG) guided approach for transcutaneous and transmesenterial navigation with accurate lymph vessel and node identification for regional lymph node staging in solid malignancies.

METHODS

After institutional review board approval, a planar fluorescence imaging system was applied for lymphography and lymph node detection using ICG. A total of 96 patients were recruited and subject to fluorescence navigation for axillary (n = 46), inguinal (n = 16), and mesenterial (n = 34) visualization to analyze technical and clinical feasibility of the method after regional lymph node dissection and the applicability.

RESULTS

Overall fluorescence imaging identified lymphatic vessels and the SLN in 92 out of 96 patients (detection rate: 96%) after a mean injection of 7 mg ICG. Sensitivity based on fluorescent emission of ICG navigation was 95.6% in 65 out of 68 patients with lymph node dissection. All solid tumors were feasible for fluorescence-guided navigation with a broad spectrum.

CONCLUSION

Fluorescence-guided real-time lymphography with navigation to regional lymph nodes enables accurate visualization for a broad spectrum of different solid tumors with potential lymphonodal spread. In addition, the technique can be applied for lymphography in non-malignant diseases. With reference to the broad application spectrum, institutional investment in camera equipment can be justified.

Contrast enhanced lung MRI in mice using ultra-short echo time radial imaging and intratracheally administrated Gd-DOTA-based nanoparticles

PURPOSE

To investigate the in vivo T1 -enhancement of the lung parenchyma in free-breathing healthy mice following intratracheal administration of Gd-DOTA-based nanoparticles, to assess the enhancement kinetics of the instilled contrast medium and to identify its elimination pathways.

METHODS

Ultrashort Echo Time (276 μs) proton MRI of the lung was performed (N = 14) at 4.7 T after the intratracheal instillation of 50 μL of seven different concentrations of contrast agent solution (from 2 to 100 mM of Gd(3+) ). The signal enhancement (SE) in lungs, blood, liver, kidneys, and bladder was assessed (N = 3) for a 50 mM concentration solution at different time points.

RESULTS

The largest SE in lungs (266 ± 14%) was observed for a 50 mM solution of Gd(3+) . In lungs, the SE was observed to decay exponentially with a time constant of 149 ± 51 min. The passage of the nanoparticles from lung tissue to blood and kidneys, and ultimately to the bladder, was observed. No significant hepatic enhancement was measured.

CONCLUSION

This study demonstrates the feasibility of large SEs of lung tissue using intratracheally administrated solutions of Gd-based contrast agents. In future applications, the SE in lungs could be used to image the biodistribution of coadministrated drug aerosols or to selectively enhance lung diseased tissues.

Indirect magnetic resonance lymphangiography in patients with lymphedema preliminary results in humans

PURPOSE

To assess the feasibility of indirect magnetic resonance (MR) lymphangiography with intracutaneous injection of gadodiamide, a commercially available, non-ionic, extracellular paramagnetic contrast agent for the detection of lymphatic vessels in patients with lymphedema.

MATERIALS AND METHODS

In 2005, three patients with lymphedema of the lower extremities (1 primary, 2 secondary) were referred by the Foeldi Clinic for Lymphology for indirect magnetic resonance lymphangiography. 4.5 mL of gadodiamide and 0.5 mL of mepivacainhydrochloride 1% were injected intracutaneously into the dorsal aspect of each foot. MR imaging was performed with a 1.5-T system equipped with high-performance gradients. For indirect magnetic resonance lymphangiography, a 3D Fast Low Angle Shot (FLASH) sequence (TR/TE: 5.1/1.23; flip angle: 25; matrix: 448 x 448; bandwidth: 330 Hz/pixel; 6/8 rectangular field of view with a maximum dimension of 500 mm; slices: 88; voxel size: 2.0 mm x 1.0 mm x 1.0mm; acquisition time: 0 min 31 s) was used.

RESULTS

Indirect magnetic resonance lymphangiography depicted lymphatic vessels of the lower and upper leg, and inguinal lymph nodes in all three patients. After 5 min of contrast material application, concomitant venous enhancement was detected. Collateral vessels with dermal back-flow were seen in two patients. A lymphocele in the inguinal region with the afferent lymphatic vessel was depicted in one patient.

CONCLUSION

In the presented small study group, indirect magnetic resonance lymphangiography was technically feasible, and no complications were observed after intracutaneous injection of gadodiamide. Visualizing the lymphatic vessels and accompanying complications non-invasively and without the use of radiation, the presented method has the capability to become a routine diagnostic imaging tool in patients with primary and secondary lymphedema. The method is not able to characterize lymph node morphology, but could provide additional information about the lymphatic vessels when lymph nodes are examined, e.g. with super-paramagnetic iron oxide particles.

Computed Tomography Lymphography With Intrapulmonary Injection of Iopamidol for Sentinel Lymph Node Localization

PURPOSE

Experimental and clinical evaluation of the potential utility of indirect computed tomographic lymphography (CT-LG) with intrapulmonary injection of iopamidol for preoperative localization of sentinel lymph node station in non-small cell lung cancer.

METHODS

CT-LG with intrapulmonary injection of 0.5 mL of undiluted iopamidol was performed in 10 dogs using a multidetector-row CT unit, followed by postmortem examination of enhanced lymph nodes in 5 of these dogs. The CT-LG with peritumoral injection of 1 mL of the contrast agent was also performed in 9 patients with non-small cell lung cancer without lymphadenopathy. At surgery, enhanced lymph nodes were resected under CT-LG guide, followed by standard lymph node dissection with macroscopic and histologic examination. A significant enhancement of lymph nodes was determined when CT attenuation value was increased with 30 Hounsfield units (HU) compared with precontrast images.

RESULTS

CT-LG visualized a total of 15 enhanced lymph nodes (on average, 1.5 nodes per animal) within 2 minutes after contrast injection in the 10 dogs, with average size of 6.7+/- 1.9 mm and average maximum CT attenuation of 149 +/- 41 HU. All the 8 enhanced nodes in 5 dogs were found in the appropriate anatomic locations in postmortem examinations. Without noticeable complications, CT-LG visualized 30 ipsilateral intrathoracic lymph nodes including 19 hilar/pulmonary and 11 mediastinal nodes in the 9 patients (on average, 2.2 hilar/pulmonary and 1.1 mediastinal nodes per patient) within 2 minutes after contrast injection, with average size of 4.7+/- 0.4 mm and average maximum CT attenuation of 134 +/- 52 HU. At surgery, all these enhanced nodes could be accurately found and resected under CT-LG guidance. Metastasis was not evident in either of these enhanced lymph nodes or the remaining distant nodes in all patients.

CONCLUSION

Quick and accurate localization of sentinel lymph node station on detailed underlying lung anatomy by using indirect CT-LG may be of value to guide selective lymph node dissection for minimally invasive surgery in non-small cell lung cancer.

Preoperative imaging of the lung sentinel lymphatic basin with computed tomographic lymphography: a preliminary study

BACKGROUND

Preoperative localization of the sentinel node basin would guide selective lymph node dissection. We tried to identify these nodal stations with indirect computed tomographic lymphography using a conventional extracellular contrast agent, iopamidol.

METHODS

Eleven consecutive patients scheduled to undergo anatomic resection of suspected lung cancer, without lymphadenopathy, were given a peritumoral injection of undiluted iopamidol under computed tomography guidance, and lymphatic migration was assessed by multidetector-row helical computed tomography.

RESULTS

There were no complications such as bleeding, pneumothorax, or allergic reactions. Enhanced nodes were detected in all but 1 patient who had diffuse lymph nodal calcification. Enhanced nodes were identified at 32 ipsilateral intrathoracic nodal stations (20 hilar stations and 12 mediastinal stations). The average length of the longer axis of the enhanced nodes was 4.8 mm (range, 3 to 8 mm), and the average attenuation of the enhanced nodes was 132 (range, 46 to 261) Hounsfield units. In 9 patients with confirmed lung cancer, enhanced nodes appeared at 26 nodal stations, and all apparent enhanced nodes were identified as actual lymph nodes at appropriate position during lymphadenectomy. None of the resected lymph nodes had metastatic involvement.

CONCLUSIONS

Indirect computed tomographic lymphography with the peritumoral injection of iopamidol effectively depicts the drainage nodes unless they are diffusely calcified. Although further study is required, this method could guide selective lymph node dissection.