The magic bullet: Creating Indium-111 bombesin targeting vectors for use in diagnostic imaging of prostate and breast cancer [abstract]

Abstract only availableBackground: According to the American Cancer Society, over 68,000 men and women will die from prostate and breast cancer in this year alone. Prostate, breast and other cancers have been shown to express the BB2 receptor. For the past decade the Hoffman laboratory has been synthesizing radiopharmaceutical conjugates based on the Bombesin (BBN) peptide (Gln-Trp-Ala-Val-Gly-His-Leu-Met-NH2) that target the BB2 receptor for diagnosis and treatment of cancer. The radioconjugates are composed of a bombesin targeting vector, linking group, chelation moiety and a radioactive metal. One focus of our group is to investigate the efficacy of new Bombesin Targeting Vectors (BTV) which are derivatives of the BBN peptide. In the sixth position of the BTV is a D-phenylalanine amino acid. Our hypothesis is that the D-phenylalanine is responsible for significantly reducing kidney retention. Reduction of kidney retention is crucial for clinical radiotherapeutic applications because the kidney is often the dose limiting organ. In order to understand the structure function relationship of the D-phenylalanine in the BTV targeting vectors, we synthesized and evaluated the BTV peptide with the L-phenylalanine in the sixth position to determine what effect the stereochemistry has upon the in vitro receptor binding and in vivo pharmacokinetic properties of the peptide. Methods: The peptides were synthesized using solid phase peptide synthesis, purified using RP-HPLC, and characterized using electrospray mass spectrometry. Radiolabeling of the peptides was performed using 111InCl3. In vitro cell binding assays and internalization and efflux studies were performed using the PC-3 human cancer cell line. In vivo pharmacokinetic studies were performed using CF-1 mice. Micro-SPECT (single photon emission computed tomography) imaging studies were performed in PC-3 SCID mice. Results: In vivo pharmacokinetic studies at 15 min post-injection gave 39.85 ± 5.07 %ID/g in the BB2 receptor expressing mouse pancreas for the L-Phe-BTV radioconjugate compared to 10.30 ± 0.34 for the D-Phe-BTV. Surprisingly, the kidney clearance for both radioconjugates was statistically identical. Conclusion: Incorporation of the L-Phe instead of the D-Phe into the sixth position of the BTV had no statistically significant effect upon the renal clearance of the radioconjugate. However, the change in stereochemistry from the L to the D-form had significant effects upon the in vivo uptake and retention of the radioconjugate. Further investigations will be conducted to understand the mechanism responsible for the difference in uptake and retention of the two Bombesin radioconjugates

Using Indium-111 labeled radiopharmaceuticals to target the BB2 receptor on human prostate cancer cells [abstract]

Abstract only availableThe BB2 receptor, belonging to the Bombesin receptor family, has been shown to be highly over expressed in a variety of cancer cell lines, including human prostate cancer. Our laboratory have been involved, for over a decade, in synthesizing Bombesin analogues that target the BB2 receptor for the purpose of developing radiopharmaceuticals for diagnostic and/or therapeutic treatment of cancer. Radiopharmaceuticals based on Bombesin are typically composed of a chelator, isotope, linking group and targeting vector [See Bifunctional Conjugate Design [figure below]. Previous studies by our group and others have shown that variations in linking groups affect the retention time of the bifunctional conjugate in prostate cancer (PC-3) cells. Higher retention time allows for more efficacious therapeutic benefits and enhanced diagnostic imaging capabilities. In this study, we seek to determine the pharmacokinetic benefits achieved in altering the linking group using aliphatic and aromatic linking groups. In-vitro analysis of the radiopharmaceuticals studied found that the Bombesin derivative with the aliphatic linking group demonstrated a slightly higher affinity for the BB2 receptor compared to the Bombesin analogs containing aromatic linking groups. In vivo pharmacokinetic and imaging studies were performed using pre-clinical models of prostate cancer. The tumor uptake of the Bombesin derivatives with the aromatic linking groups were found to be significantly higher compared to that of the Bombesin derivative with the aliphatic linking group. In contrast, the aromatic Bombesin analogs also exhibited higher amounts of undesirable accumulation in the kidneys and other non-target tissues. In conclusion, we found that the aliphatic compounds were more appropriate for diagnostic imaging of prostate cancer due to the reduced non-target retention. The Bombesin analogs with aromatic linking groups showed potential for use as therapeutic agents for prostate cancer treatment.National Institutes of Health Molecular Imaging Progra

Targeting the BB2 receptor on human prostate cancer cells using Indium-111 labeled radiopharmaceutical [abstract]

Abstract only availableFaculty Mentor: Dr. Timothy Hoffman, Internal MedicineThe BB2 receptor, belonging to the Bombesin receptor family, has been shown to be highly over expressed in a variety of cancer cell lines, including human prostate cancer. Over expression of the BB2 receptor offers an appealing target for the design of targeted radiopharmaceuticals.  The Hoffman laboratory and others have been involved, for over a decade, in synthesizing Bombesin analogues that target the BB2 receptor for the purpose of developing a viable radiopharmaceutical for diagnostic or therapeutic treatment of cancer. Radiopharmaceuticals based on Bombesin analogues are typically composed of a targeting vector, radioisotope, chelator and linking group [See Bifunctional Conjugate Design figure below]. Previous studies have shown that variations in linking groups may affect the retention time of the bifunctional conjugate in prostate cancer (PC-3) cells.  Higher retention time allows for more efficacious therapeutic benefits and enhanced diagnostic imaging capabilities.  In the work presented, we designed and synthesized a 111In-Bombesin analogue with a phenyl linker group in order to determine if the phenyl linker group would provide higher retention times in prostate cancer.  In-vitro analysis of the radiopharmaceutical was performed using PC-3 cells to determine the affinity of the new compound for the BB2 receptor to be 1.09 nM. In-vivo studies of the radiopharmaceutical were also conducted by injection of the radiopharmaceutical into CF-1 (“normal”) mice, as well as SCID (Severe Combined Immunodeficient) mice bearing 2-3 week old PC-3 tumors. Experimental results on SCID mice revealed uptakes of 6.36, 3.34, 2.42 and 1.69 % Injected Dose of radiopharmaceutical per gram of tumor tissue at 0.25, 1, 4 and 24 hours, respectively. Imaging using Micro-SPECT (Single-Photon Emission Computed Tomography) was performed to track the dispersion of the radiopharmaceutical throughout the mouse model and confirmed the targeted uptake of the radiopharmaceutical

Rod-shape theranostic nanoparticles facilitate antiretroviral drug biodistribution and activity in human immunodeficiency virus susceptible cells and tissues

Human immunodeficiency virus theranostics facilitates the development of long acting (LA) antiretroviral drugs (ARVs) by defining drug-particle cell depots. Optimal drug formulations are made possible based on precise particle composition, structure, shape and size. Through the creation of rod-shaped particles of defined sizes reflective of native LA drugs, theranostic probes can be deployed to measure particle-cell and tissue biodistribution, antiretroviral activities and drug retention. Methods: Herein, we created multimodal rilpivirine (RPV) 177lutetium labeled bismuth sulfide nanorods (177LuBSNRs) then evaluated their structure, morphology, configuration, chemical composition, biological responses and adverse reactions. Particle biodistribution was analyzed by single photon emission computed tomography (SPECT/CT) and laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) imaging. Results: Nanoformulated RPV and BSNRs-RPV particles showed comparable physicochemical and cell biological properties. Drug-particle pharmacokinetics (PK) and biodistribution in lymphoid tissue macrophages proved equivalent, one with the other. Rapid particle uptake and tissue distribution were observed, without adverse reactions, in primary blood-derived and tissue macrophages. The latter was seen within the marginal zones of spleen. Conclusions: These data, taken together, support the use of 177LuBSNRs as theranostic probes as a rapid assessment tool for PK LA ARV measurements

Expedient Single Step Access to Strained Tricyclic Ketals

The synthesis of cyclopropyl methyl ketones and highly strained fused substituted dihydrobenzopyran cyclopropyl lactones derived from coumarin carboxylates and chloroacetone in the presence of potassium carbonate is reported. One step synthetic access to the previously unknown dihydrobenzopyran cyclopropyl tricyclic ketals is achieved with wide substrate scope. Substituted coumarin carboxylates, phenylamides or a quinolin-2(1H)-one possessing alkyl electron donating (methyl, t-butyl) and electron withdrawing groups (F, Cl, Br, NO2) in the 4 or 6 positions formed the highly strained dihydrobenzopyran cyclopropyl tricyclic ketals in moderate yield alongside the expected coumarin carboxylate. Saturation or substitution at the 5-position or 6-OMe afforded no tricyclic ketal compound but solely coumarin carboxylates. The formation of both structures in selected derivatives was confirmed by X-ray crystallography. A plausible mechanism is proposed for the formation of the fused lactone; via intramolecular rearrangement of cis cyclopropyl methyl ketones with phenolic acetate via the formation of a hemiacetal

Rod-shape theranostic nanoparticles facilitate antiretroviral drug biodistribution and activity in human immunodeficiency virus susceptible cells and tissues

Human immunodeficiency virus theranostics facilitates the development of long acting (LA) antiretroviral drugs (ARVs) by defining drug-particle cell depots. Optimal drug formulations are made possible based on precise particle composition, structure, shape and size. Through the creation of rod-shaped particles of defined sizes reflective of native LA drugs, theranostic probes can be deployed to measure particle-cell and tissue biodistribution, antiretroviral activities and drug retention. Methods: Herein, we created multimodal rilpivirine (RPV) 177lutetium labeled bismuth sulfide nanorods (177LuBSNRs) then evaluated their structure, morphology, configuration, chemical composition, biological responses and adverse reactions. Particle biodistribution was analyzed by single photon emission computed tomography (SPECT/CT) and laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) imaging. Results: Nanoformulated RPV and BSNRs-RPV particles showed comparable physicochemical and cell biological properties. Drug-particle pharmacokinetics (PK) and biodistribution in lymphoid tissue macrophages proved equivalent, one with the other. Rapid particle uptake and tissue distribution were observed, without adverse reactions, in primary blood-derived and tissue macrophages. The latter was seen within the marginal zones of spleen. Conclusions: These data, taken together, support the use of 177LuBSNRs as theranostic probes as a rapid assessment tool for PK LA ARV measurements

Investigation of the Biological Impact of Charge Distribution on a NTR1-Targeted Peptide

The neurotensin receptor 1 (NTR1) has been shown to be a promising target, due to its increased level of expression relative to normal tissue, for pancreatic and colon cancers. This has prompted the development of a variety of NTR1-targeted radiopharmaceuticals, based on the neurotensin (NT) peptide, for diagnostic and radiotherapeutic applications. A major obstacle for the clinical translation of NTR1-targeted radiotherapeutics would likely be nephrotoxicity due to the high levels of kidney retention. It is well-known that for many peptide-based agents, renal uptake is influenced by the overall molecular charge. Herein, we investigated the effect of charge distribution on receptor binding and kidney retention. Using the [(N-α-Me)­Arg⁸,Dmt¹¹,Tle¹²]­NT­(6–13) targeting vector, three peptides (¹⁷⁷Lu–K2, ¹⁷⁷Lu–K4, and ¹⁷⁷Lu–K6), with the Lys moved closer (K6) or further away (K2) from the pharmacophore, were synthesized. In vitro competitive binding, internalization and efflux, and confocal microscopy studies were conducted using the NTR1-positive HT-29, human colon cancer cell line. The ^177/natLu–K6 demonstrated the highest binding affinity (21.8 ± 1.2 nM) and the highest level of internalization (4.06% ± 0.20% of the total added amount). In vivo biodistribution, autoradiography, and metabolic studies of ¹⁷⁷Lu-radiolabeled K2, K4, and K6 were examined using CF-1 mice. ¹⁷⁷Lu–K4 and ¹⁷⁷Lu–K6 gave the highest levels of in vivo uptake in NTR1-positive tissues, whereas ¹⁷⁷Lu–K2 yielded nearly 2-fold higher renal uptake relative to the other radioconjugates. In conclusion, the position of the Lys (positively charged amino acid) influences the receptor binding, internalization, in vivo NTR1-targeting efficacy, and kidney retention profile of the radioconjugates. In addition, we have found that hydrophobicity likely play a role in the unique biodistribution profiles of these agents

Crystal structure and solid state computational (DFT/Hirshfeld surface) study for probing a new efficient and recyclable oxidation reagent, 1,2-ethandiylbis(triphenylphosphonium) peroxodisulfate dihydrate

<p>A new, efficient and recyclable reagent, 1,2-Ethandiylbis(triphenylphosphonium) peroxodisulfate dihydrate, for the oxidation of benzylic alcohols has been synthesized and characterized by IR, NMR spectroscopy, and single crystal X-ray crystallography. Using the title compound, the results indicate that the oxidation reactions are rapid, take place under mild reaction conditions, easily to work-up and high yielding. The Hirshfeld surface and associated finger print plots were derived from the X-ray structure to visualize the significant nonclassical C-H ⋅⋅⋅ O/π interactions in the crystal packing. The geometry, vibrational spectroscopy and electronic properties of the bis(triphenylphosphonium) dication have also been investigated by various DFT computational methods.</p