Brad P. Barnett

Fluorine (19F) MRS and MRI in biomedicine

Shortly after the introduction of 1H MRI, fluorinated molecules were tested as MR‐detectable tracers or contrast agents. Many fluorinated compounds, which are nontoxic and chemically inert, are now being used in a broad range of biomedical applications, including anesthetics, chemotherapeutic agents, and molecules with high oxygen solubility for respiration and blood substitution. These compounds can be monitored by fluorine (19F) MRI and/or MRS, providing a noninvasive means to interrogate associated functions in biological systems. As a result of the lack of endogenous fluorine in living organisms, 19F MRI of ‘hotspots’ of targeted fluorinated contrast agents has recently opened up new research avenues in molecular and cellular imaging. This includes the specific targeting and imaging of cellular surface epitopes, as well as MRI cell tracking of endogenous macrophages, injected immune cells and stem cell transplants. Copyright

Glucose and Weight Control in Mice with a Designed Ghrelin O-Acyltransferase Inhibitor

Metabolism Without Modification Obesity-associated metabolic disease has rapidly become a public health priority in the developed world and is being addressed through prevention strategies aimed at lifestyle changes and through pharmacological approaches. Barnett et al. (p. 1689, published online 18 November) designed a drug that inhibits the action of ghrelin, a circulating peptide hormone that increases fat mass and food intake. The drug, a bisubstrate analog called GO-CoA-Tat, is a selective antagonist of ghrelin O-acyltransferase (GOAT), an enzyme that catalyzes a posttranslational modification that is essential for ghrelin activity. Injection of GO-CoA-Tat into wild-type mice on a high-fat diet improved glucose tolerance and reduced weight gain, probably through changes in metabolic activity. Because GO-CoA-Tat is a peptide-based drug that requires repeated injection, it is unsuitable for clinical use, but GOAT does represent a potentially valuable target for future drug development efforts in metabolic disease. A drug inhibiting the activation of ghrelin, a peptide that promotes weight gain, has beneficial metabolic effects in mice. Ghrelin is a gastric peptide hormone that stimulates weight gain in vertebrates. The biological activities of ghrelin require octanoylation of the peptide on Ser3, an unusual posttranslational modification that is catalyzed by the enzyme ghrelin O-acyltransferase (GOAT). Here, we describe the design, synthesis, and characterization of GO-CoA-Tat, a peptide-based bisubstrate analog that antagonizes GOAT. GO-CoA-Tat potently inhibits GOAT in vitro, in cultured cells, and in mice. Intraperitoneal administration of GO-CoA-Tat improves glucose tolerance and reduces weight gain in wild-type mice but not in ghrelin-deficient mice, supporting the concept that its beneficial metabolic effects are due specifically to GOAT inhibition. In addition to serving as a research tool for mapping ghrelin actions, GO-CoA-Tat may help pave the way for clinical targeting of GOAT in metabolic diseases.

Magnetic resonance–guided, real-time targeted delivery and imaging of magnetocapsules immunoprotecting pancreatic islet cells

In type I diabetes mellitus, islet transplantation provides a moment-to-moment fine regulation of insulin. Success rates vary widely, however, necessitating suitable methods to monitor islet delivery, engraftment and survival. Here magnetic resonance–trackable magnetocapsules have been used simultaneously to immunoprotect pancreatic β-cells and to monitor, non-invasively in real-time, hepatic delivery and engraftment by magnetic resonance imaging (MRI). Magnetocapsules were detected as single capsules with an altered magnetic resonance appearance on capsule rupture. Magnetocapsules were functional in vivo because mouse β-cells restored normal glycemia in streptozotocin-induced diabetic mice and human islets induced sustained C-peptide levels in swine. In this large-animal model, magnetocapsules could be precisely targeted for infusion by using magnetic resonance fluoroscopy, whereas MRI facilitated monitoring of liver engraftment over time. These findings are directly applicable to ongoing improvements in islet cell transplantation for human diabetes, particularly because our magnetocapsules comprise clinically applicable materials.

Fluorocapsules for improved function, immunoprotection, and visualization of cellular therapeutics with MR, US, and CT imaging

PURPOSE To develop novel immunoprotective alginate microcapsule formulations containing perfluorocarbons (PFCs) that may increase cell function, provide immunoprotection for xenografted cells, and simultaneously enable multimodality imaging. MATERIALS AND METHODS All animal experiments were approved by an Institutional Animal Care and Use Committee. Cadaveric human islet cells were encapsulated with alginate, poly-l-lysine, and perfluorooctyl bromide (PFOB) or perfluoropolyether (PFPE). In vitro viability and the glucose-stimulation index for insulin were determined over the course of 2 weeks and analyzed by using a cross-sectional time series regression model. The sensitivity of multimodality (computed tomography [CT], ultrasonography [US], and fluorine 19 [(19)F] magnetic resonance [MR] imaging) detection was determined for fluorocapsules embedded in gel phantoms. C57BL/6 mice intraperitoneally receiving 6000 PFOB-labeled (n = 6) or 6000 PFPE-labeled (n = 6) islet-containing fluorocapsules and control mice intraperitoneally receiving 6000 PFOB-labeled (n = 6) or 6000 PFPE-labeled (n = 6) fluorocapsules without islets were monitored for human C-peptide (insulin) secretion during a period of 55 days. Mice underwent (19)F MR imaging at 9.4 T and micro-CT. Swine (n = 2) receiving 9000 PFOB capsules through renal artery catheterization were imaged with a clinical multidetector CT scanner. Signal intensity was evaluated by using a paired t test. RESULTS Compared with nonfluorinated alginate microcapsules, PFOB fluorocapsules increased insulin secretion of encapsulated human islets, with values up to 18.5% (3.78 vs 3.19) at 8-mmol/L glucose concentration after 7 days in culture (P < .001). After placement of the immunoprotected encapsulated cells into mice, a sustained insulin release was achieved with human C-peptide levels of 19.1 pmol/L ± 0.9 (standard deviation) and 33.0 pmol/L ± 1.0 for PFPE and PFOB capsules, respectively. Fluorocapsules were readily visualized with (19)F MR imaging, US imaging, and CT with research- and clinical-grade imagers for all modalities. CONCLUSION Fluorocapsules enhance glucose responsiveness and insulin secretion in vitro, enable long-term insulin secretion by xenografted islet cells in vivo, and represent a novel contrast agent platform for multimodality imaging.

Use of perfluorocarbon nanoparticles for non-invasive multimodal cell tracking of human pancreatic islets

In vivo imaging of engraftment and immunorejection of transplanted islets is critical for further clinical development, with (1)H MR imaging of superparamagnetic iron oxide-labeled cells being the current premier modality. Using perfluorocarbon nanoparticles, we present here a strategy for non-invasive imaging of cells using other modalities. To this end, human cadaveric islets were labeled with rhodamine-perfluorooctylbromide (PFOB) nanoparticles, rhodamine-perfluoropolyether (PFPE) nanoparticles or Feridex as control and tested in vitro for cell viability and c-peptide secretion for 1 week. (19)F MRI, computed tomography (CT) and ultrasound (US) imaging was performed on labeled cell phantoms and on cells following transplantation beneath the kidney capsule of mice and rabbits. PFOB and PFPE-labeling did not reduce human islet viability or glucose responsiveness as compared with unlabeled cells or SPIO-labeled cells. PFOB- and PFPE-labeled islets were effectively fluorinated for visualization by (19)F MRI. PFOB-labeled islets were acoustically reflective for detection by US imaging and became sufficiently brominated to become radiopaque allowing visualization with CT. Thus, perfluorocarbon nanoparticles are multimodal cellular contrast agents that may find applications in real-time targeted delivery and imaging of transplanted human islets or other cells in a clinically applicable manner using MRI, US or CT imaging.

Synthesis of magnetic resonance–, X-ray– and ultrasound-visible alginate microcapsules for immunoisolation and noninvasive imaging of cellular therapeutics

Cell therapy has the potential to treat or cure a wide variety of diseases. Non-invasive cell tracking techniques are, however, necessary to translate this approach to the clinical setting. This protocol details methods to create microcapsules that are visible by X-ray, ultrasound (US) or magnetic resonance (MR) for the encapsulation and immunoisolation of cellular therapeutics. Three steps are generally used to encapsulate cellular therapeutics in an alginate matrix: (i) droplets of cell-containing liquid alginate are extruded, using an electrostatic generator, through a needle tip into a solution containing a dissolved divalent cation salt to form a solid gel; (ii) the resulting gelled spheres are coated with polycations as a cross-linker; and (iii) these complexes are then incubated in a second solution of alginate to form a semipermeable membrane composed of an inner and an outer layer of alginate. The microcapsules can be rendered visible during the first step by adding contrast agents to the primary alginate layer. Such contrast agents include superparamagnetic iron oxide for detection by 1H MR imaging (MRI); the radiopaque agents barium or bismuth sulfate for detection by X-ray modalities; or perfluorocarbon emulsions for multimodal detection by 19F MRI, X-ray and US imaging. The entire synthesis can be completed within 2 h.

Catheter-directed gastric artery chemical embolization suppresses systemic ghrelin levels in porcine model

PURPOSE To prospectively test, in a porcine model, the hypothesis that catheter-directed gastric artery chemical embolization (GACE) can result in suppression of systemic ghrelin levels and affect weight gain. MATERIALS AND METHODS This study, which had Animal Care and Use Committee approval, was performed in healthy, growing swine (weight range, 40-45 kg; n = 10). GACE was performed in five swine with the infusion of sodium morrhuate (125 mug) selectively into the gastric arteries that supply the fundus. Five control animals underwent a sham procedure with 5 mL of saline. Weight and fasting plasma ghrelin levels were obtained in animals at baseline and in weeks 1-4. Statistical testing for substantial differences in ghrelin blood levels over time and between treated and untreated animals was performed by using a cross-sectional time-series linear model with feasibility generalized least squares. RESULTS The pattern of the change in ghrelin levels over time was significantly different between control and treated animals (P < .004). In treated animals, ghrelin levels were significantly reduced at week 1 (mean, 664.1 pg/mL +/- 103.1 [standard error of the mean], P < .02), week 2 (mean, 618.1 pg/mL +/- 180.4, P < .001), week 3 (mean, 578.4 pg/mL +/- 214.9, P < .001), and week 4 (mean, 876.6 pg/mL +/- 228.6, P < .03) relative to baseline (mean, 1006.3 pg/mL +/- 190.1). The percentage change in serum ghrelin values in swine treated with GACE decreased from baseline to -34%, -38.6%, -42.5%, and -12.9% during weeks 1-4, respectively. In control swine, percentage change in serum ghrelin was -1.7%, -9.7%, +2.6%, and +18.2% during weeks 1-4, respectively. At the end of 4 weeks, control swine continued to gain weight, with a 15.1% increase from their original weight, while the weight in swine treated with GACE plateaued at an increase of 7.8% from the original weight. CONCLUSION Catheter-directed GACE can suppress the appetite hormone ghrelin and affect weight gain.

X‐Ray‐Visible Microcapsules Containing Mesenchymal Stem Cells Improve Hind Limb Perfusion in a Rabbit Model of Peripheral Arterial Disease

The therapeutic goal in peripheral arterial disease (PAD) patients is to restore blood flow to ischemic tissue. Stem cell transplantation offers a new avenue to enhance arteriogenesis and angiogenesis. Two major problems with cell therapies are poor cell survival and the lack of visualization of cell delivery and distribution. To address these therapeutic barriers, allogeneic bone marrow‐derived mesenchymal stem cells (MSCs) were encapsulated in alginate impregnated with a radiopaque contrast agent (MSC‐Xcaps.) In vitro MSC‐Xcap viability by a fluorometric assay was high (96.9% ± 2.7% at 30 days postencapsulation) and as few as 10 Xcaps were visible on clinical x‐ray fluoroscopic systems. Using an endovascular PAD model, rabbits (n = 21) were randomized to receive MSC‐Xcaps (n = 6), empty Xcaps (n = 5), unencapsulated MSCs (n = 5), or sham intramuscular injections (n = 5) in the ischemic thigh 24 hours postocclusion. Immediately after MSC transplantation and 14 days later, digital radiographs acquired on a clinical angiographic system demonstrated persistent visualization of the Xcap injection sites with retained contrast‐to‐noise. Using a modified TIMI frame count, quantitative angiography demonstrated a 65% improvement in hind limb perfusion or arteriogenesis in MSC‐Xcap‐treated animals versus empty Xcaps. Post‐mortem immunohistopathology of vessel density by anti‐CD31 staining demonstrated an 87% enhancement in angiogenesis in Xcap‐MSC‐treated animals versus empty Xcaps. MSC‐Xcaps represent the first x‐ray‐visible cellular therapeutic with enhanced efficacy for PAD treatment. STEM CELLS2012;30:1286–1296

In Vitro Assessment of EmboGel and UltraGel Radiopaque Hydrogels for the Endovascular Treatment of Aneurysms

PURPOSE To describe two hydrogel embolic materials, the alginate-based EmboGel and the polyethylene glycol diacrylate-based UltraGel and examine their use as embolic agents in in vitro models of abdominal aortic aneurysm (AAA) endoleak and saccular aneurysms. MATERIALS AND METHODS EmboGel is a mixture of iohexol and alginate, with a calcium chloride solution used to induce polymerization. UltraGel is a mixture of igracure, iohexol, and polyethylene glycol diacrylate and polymerizes in the presence of ultraviolet (UV) light. Modified microcatheter delivery systems were used in both cases to demonstrate use of the hydrogels in fusiform and saccular aneurysm models. RESULTS Preliminary in vitro results suggest that EmboGel and UltraGel provide effective embolization in fusiform and saccular aneurysm models, respectively. Due to the rapid polymerization of EmboGel, the agent was delivered in a strand-like form. When used in conjunction with a stent in an AAA endoleak model, this form was able to effectively fill the aneurysmal cavity and occlude it from the central blood flow. UltraGel, conversely, was delivered as a liquid and slowly polymerized in the presence of UV light. This system in a saccular aneurysm model was able to form a solid cast inside the aneurysm wall, again showing complete occlusion from the parent flow. CONCLUSIONS Preliminary results indicate these two novel hydrogel applications may prove effective for the treatment of saccular and fusiform aneurysms.

Vision Concerns After Mild Traumatic Brain Injury

Opinion statementMild traumatic brain injury (mTBI) can manifest with visual dysfunction including deficits in accommodation, vergence movements, versions, and field of vision as well increased photosensitivity and a decline in ocular and overall health. Patients with incomitant strabismus should be referred to an ophthalmologist for intervention. Patients with mTBI who experience photosensitivity, or deficits in accommodation, versions, vergences, or field of vision may benefit from vision rehabilitation. These therapies may include spectacles with tinting and a variety of prism combinations. Patients with chronic visual dysfunction following mTBI may benefit from occupational, vestibular, cognitive, and other forms of physical therapy.