Benjamin F. Edwards

Syntheses and preliminary biological studies of four meso-Tetra[(nido-carboranylmethyl)phenyl]porphyrins

Two meso-tetra[(nido-carboranylmethyl)phenyl]porphyrins (para- and meta-regioisomers) and their corresponding Zn(II) complexes have been synthesized with the aim of studying the effect of carborane distribution and metalation on the biological properties of this series of compounds. In vitro cell toxicity, uptake/efflux, and subcellular localization using rat 9L, mouse B16 and/or human U-373MG cells were evaluated. All four amphiphilic porphyrins display very low cytotoxicities and time- and concentration-dependent uptake by cells, which is influenced by serum proteins. Preliminary subcellular localization studies suggest that one of these compounds localizes in close proximity to the cell nucleus. All four nido-carboranylporphyrins show promise as boron-carriers for the boron neutron capture therapy of cancers, particularly the metal-free nido-carboranylporphyrins 5 and 12, which are able to deliver higher amount of boron to cells in vitro than the corresponding zinc complexes.

Topographic distribution of bcl-2 protein in feline tissues in health and neoplasia.

The bcl-2 family of genes encodes proteins that influence apoptosis. In the present immunohis-tochemical study, the topographic distribution of bcl-2 protein was examined in healthy feline fetal, neonatal, and adult tissues, a feline renal cell line, and feline tumors obtained from a veterinary hospital. The topographic distribution of bcl-2 in healthy tissues was similar to that described in human tissues. In lymphoid tissues, follicular mantle cells strongly expressed bcl-2. In complex and differentiating epithelium, bcl-2 expression was detected in stem cell and proliferation zones. Bcl-2 expression was also detected in lower crypts of the intestine and in skin basal layers. The feline Crandell kidney cells expressed bcl-2 diffusely throughout the cytoplasm. Of 180 tumors examined, bcl-2 was expressed almost uniformly in cutaneous basal cell tumors, thyroid adenomas, and mammary carcinomas and in 50% of the lymphomas examined. Bcl-2 may play a role in blocking apoptotic cell death in a broad range of normal feline tissues, whereas dysregulated bcl-2 may extend the life of certain tumors or render certain tumors resistant to therapy because most chemotherapeutic and radiotherapeutic agents eliminate tumor cells by triggering apoptosis.

Human renal clear cell carcinoma: Establishment and characterization of a new cell line (G-2101)

SummaryA human cell line has been established from a renal adenocarcinoma rib metastasis of a 58-y-old male. This cell line has been maintained in continuous culture for 20 mo. through more than 50 passages. It displays simulataneous expression of the intermediate filaments cytokeratin and vimentin. Flow cytometric analysis of DNA content reveals a major hyperdiploid population.

Promising cancer treatment modality: the University of California Davis/McClellan Nuclear Radiation Center neutron capture therapy program

Neutron capture therapy (NCT) is a promising new binary therapeutic modality for the treatment of localized tumors. It is accomplished by injection and localization within the tumor of a neutron capture agent (NCA) that alone, is non- toxic. Whenthe tumor is then exposed to neutrons, a relatively non-toxic form of radiation, crytotoxic products are produced that directly or indirectly cause tumor cell death, and yet preserves normal surrounding tissue not contain the NCA. The UC Davis NCT program is currently working to develop and test new compounds or NCA in vitro and in vivo. Many groups worldwide are also working to develop the next generation NCA, but less than five facilities internationally are currently capable to treating clinical brain tumor patients by NCT and only two US facilities, MIT and Brookhaven National Laboratory. In addition to compound development, the UC Davis NCT program is preparing the UC Davis McClellan Nuclear Radiation Centers 2 megawatt TRIGA reactor for NCT clinical trials which would make it the only such facility on the West Coast.

Evaluation of monophosphoryl lipid A as an immune adjuvant for photodynamic therapy in a rat sarcoma model: preliminary results

Photodynamic therapy (PDT) is a treatment option for several forms of human cancer, and like traditional chemotherapy and ionizing radiation therapy, PDT alone is not curative for some cases. Recent efforts have aimed at developing strategies for adjuvant therapy for PDT. Given the nature of PDT-mediated cell damage, immunotherapy is a promising adjuvant for long-term control of solid tumors. A candidate immune stimulant for use with PDT is monophosphoryl lipid A (MLA), a non-toxic fraction of the endotoxin molecule. The hypothesis is that adjuvant MLA immunotherapy with PDT will improve local tumor control and prevent growth of subsequently implanted tumor cells when compared to PDT alone. To date, no significant differences in circulating leukocyte populations or tumor infiltrating lymphocyte populations have been identified in 9L tumor-bearing F344 rats after systemic administrations of MLA. Likewise, no significant difference has been identified in local tumor control following PDT of 9L tumors with or without adjuvant MLA. Further results are pending.

Evaluation of ALA-induced PpIX as a photosensitizer for PDT in cats

Given exogenously, ALA defeats intrinsic regulatory feedback mechanisms allowing intracellular accumulation of protoporphyrin IX (PpIX), a highly efficient photosensitizer. In vivo, PpIX synthesis in neoplastic mammary tissues averages 20-fold higher than in normal mammary tissues. PpIX is retained intracellularly, unlike perivascular localization of other photosensitizers, and it is then cleared quickly from the body. In vitro, ALA induced PpIX production in our laboratory in 6 cell lines tested, including an established feline kidney cell line and dermal fibroblasts from primary skin biopsy explant, resulting in photosensitization. Fluorescent microscopy confirmed PpIX production in skin adnexae following ALA administration in a normal cat. To evaluate toxicity, three cats were treated with a single i.v. dose of ALA (either 100, 200, of 400 mg/kg) and followed for 7 days. Cats receiving 100 or 200 mg/kg ALA i.v. had elevated liver enzymes and bilirubin within 24 hours. Histopathology revealed hydropic changes in the liver and renal fibrosis. The cat receiving 400 mg/kg ALA intravenously had cutaneous flush, bradycardia and apnea associated with ALA administration; within 24 hours the cat was lethargic, anorectic and icteric. ALT, AST and bilirubin concentrations had increased significantly. At necropsy the liver had a prominent lobular pattern; histopathology revealed severe periportal hepatitis and splenic necrosis. Systemically administered ALA induces PpIX production, but toxicity may preclude its clinical application in the cat. PpIX levels seem to be more time dependent than those dependent at these three ALA doses and they are well beyond the saturation point for adequate PpIX conversion. The literature is scant regarding toxicity associated with parenteral administration of ALA.

Efficacy of pyropheophorbide-a-hexyl ether for photodynamic therapy of rat 9L gliosarcoma

In preliminary studies, the efficacy of a new photosensitizer, pyropheophorbide-(alpha) - hexyl ether (HPPH #23), for use in photodynamic therapy (PDT) was assessed using the rat 9L gliosarcoma tumor model in subcutaneous flank tumors, intracranial tumors, and in vivo. Flank and intracranial tumors were irradiated with 75 - 203 J/cm2 24 hours after 0.3 - 0.6 mg/kg IV injection of HPPH #23. At 24 hours post-PDT, and flank tumors showed a range of necrosis at the highest laser dose from 50 - 100%. The overlying skin and underlying muscle were spared. Intracranial tumors exhibited moderate to severe hemorrhagic necrosis. Areas of brain adjacent to tumor within the irradiated field also showed some damage. In vitro phototoxicity of HPPH #23 was compared to that of Photofrin II (PhII). Cells growing in culture dishes were exposed to HPPH #23 or PhII for 20 hours, washed free of unbound drug, then irradiated at 2.5 J/cm2, 17 mW/cm2 at 665 nm (HPPH #23) or 630 nm (PhII). Irradiated cultures were maintained in dark incubators for an additional 4 - 5 days, and phototoxic inhibition of cell proliferation was quantified by the sulphorhodamine B spectrophotometric assay. Under identical irradiation conditions, the IC50 for HPPH #23 (0.25 (mu) g/ml) was 10-fold lower than that of PhII (2.5 (mu) g/ml). Complete cell kill was achieved at sensitizer doses of 0.5 (mu) g/ml (HPPH #23) and 5.0 (mu) g/ml (PhII).