Effect of nicotinamide and pentoxifylline on normal tissue and FSA tumor oxygenation

Transiently hypoxic tumour cell turnover and radiation sensitivity in human tumour xenografts

BACKGROUND

Solid tumour perfusion can be unstable, creating transiently hypoxic cells that can contribute to radiation resistance. We investigated the in vivo lifetime of transiently hypoxic tumour cells and chronically hypoxic tumour cells during tumour growth and following irradiation.

METHODS

Hypoxic cells in SiHa and WiDr human tumour xenografts were labelled using pimonidazole and EF5, and turnover was quantified as the loss of labelled cells over time. The perfusion-modifying drug pentoxifylline was used to reoxygenate transiently hypoxic cells prior to hypoxia marker administration or irradiation.

RESULTS

Chronically hypoxic cells constantly turnover in SiHa and WiDr tumours, with half-lives ranging from 42-82 h and significant numbers surviving >96 h. Transiently hypoxic cells constitute 26% of the total hypoxic cells in WiDr tumours. These transiently hypoxic cells survive at least 24 h, but then rapidly turnover with a half-life of 34 h and are undetectable 72 h after labelling. Transiently hypoxic cells are radiation-resistant, although vascular dysfunction induced by 10 Gy of ionising radiation preferentially kills transiently hypoxic cells.

CONCLUSIONS

Transiently hypoxic tumour cells survive up to 72 h in WiDr tumours and are radiation-resistant, although transiently hypoxic cells are sensitive to vascular dysfunction induced by high doses of ionising radiation.

Angiotensin II type 1 receptor blocker telmisartan inhibits the development of transient hypoxia and improves tumour response to radiation

Hypoxic tumour cells are radiation-resistant and are associated with poor therapeutic outcome. A poorly understood source of tumour hypoxia is unstable perfusion, which exposes tumour cells to varying oxygen tensions over time creating "transiently" hypoxic cells. Evidence suggests that angiotensin II type 1 receptor blockers (ARBs) can improve tumour perfusion by reducing collagen deposition from cancer associated fibroblasts (CAFs). However, the influence of ARBs on transient hypoxia and tumour radiation response is unknown. We tested how the ARBs losartan and telmisartan affected the solid tumour microenvironment, using fluorescent perfusion dyes and positron emission tomography to quantify tumour perfusion, and a combination of hypoxia markers and the hemorheological agent pentoxifylline to assess transient tumour hypoxia. We found CAF-containing tumours have reduced collagen I levels in response to telmisartan, but not losartan. Telmisartan significantly increased tumour blood flow, stabilized microregional tumour perfusion, and decreased tumour hypoxia by reducing the development of transient hypoxia. Telmisartan-treated tumours were more responsive to radiation, indicating that telmisartan reduces a therapeutically important population of transiently hypoxic tumour cells. Our findings indicate telmisartan is capable of modifying the tumour microenvironment to stabilize tumour perfusion, reduce transient hypoxia, and improve tumour radiation response.

Tumor hypoxia correlates with metastatic tumor growth of pancreatic cancer in an orthotopic murine model

BACKGROUND

The role of tumor hypoxia has become a major focus in cancer research since it influences both local and systemic tumor growth. Oxygen measurements taken in human pancreatic cancer have shown extremely low oxygen tension. The aim of this study was to develop an orthotopic model for pancreatic cancer that mimics the specific tumor microenvironment and to evaluate the role of tumor oxygenation in local tumor growth and systemic dissemination in this model.

MATERIALS AND METHODS

We used two established human pancreatic cancer cell lines for xenobiotic tumor induction. After subcutaneous tumor formation one small tumor piece was transplanted into the pancreatic parenchyma of mice of the different study groups. Upon orthotopic tumor induction tumor oxygenation was measured with the Eppendorf histograph. Histological evaluation was performed with pimonidazole, an in vivo marker of hypoxia.

RESULTS

The tumor take rate was 100% in this model. Metastatic tumor dissemination occurred within the abdominal cavity, and distant metastasis were observed in the lung parenchyma. Oxygen measurements taken in various abdominal organs and xenograft tumor showed a high variation between different organs and xenografted tumors. Tumor oxygenation correlated well with the metastatic score in this model. Furthermore hypoxia was found both in the tumor center and also at the rim of a growing tumor mass. A high number of hypoxic cells were detectable in metastases located in the lung parenchyma.

CONCLUSION

This study provides experimental evidence that tumor hypoxia influences metastatic disease progression and supports recent assumptions that tumor hypoxia is actively involved in progression of pancreatic cancer. It further demonstrates that tumor hypoxia is not only found in the center of a tumor mass, but also occurs at the invasion front.

Antiangiogenic activity of genistein in pancreatic carcinoma cells is mediated by the inhibition of hypoxia-inducible factor-1 and the down-regulation of VEGF gene expression

BACKGROUND

Previous reports indicate that Genistein, a naturally occurring isoflavonoid, exhibits strong antiangiogenic activity. The underlying mechanism of inhibition, however, remains unclear. Among the biologic effects of Genistein are the inhibition of tyrosine kinases and the inhibition of hypoxic activation of hypoxia-inducible factor-1 (HIF-1), one of the main regulators of VEGF gene expression.

METHODS

Hypoxic cell culture was performed in a modular incubator chamber. Vascular endothelial growth factor (VEGF) protein secretion was measured using the enzyme-linked immunosorbent assay, binding of DNA by HIF-1 was measured using the electrophoretic mobility shift assay, and mRNA quantification was performed using Northern blot analysis. Pancreatic carcinoma was studied in an orthotopic murine model. Angiogenesis in vivo was quantified by staining xenograft tumors for endothelial cell markers.

RESULTS

VEGF protein secretion was dose-dependently suppressed with increasing doses of Genistein. Furthermore, treatment of pancreatic carcinoma cells with Genistein led to impaired activation of HIF-1 under hypoxic culture conditions. Northern blot analysis indicated that VEGF mRNA expression decreased upon treatment with Genistein, both under normoxic and hypoxic culture conditions. In vivo, Genistein inhibited tumor growth for xenograft pancreatic carcinoma cells, whereas extensive hypoxia was observed in xenograft tumors and was not influenced by Genistein therapy. Similarly, decreased VEGF mRNA levels were observed in Genistein-treated Capan-1 xenograft tumors.

CONCLUSIONS

The current study indicates that the previously reported antiangiogenic activity of Genistein probably is mediated by the inhibition of HIF-1, an important regulator of VEGF gene homeostasis, particularly under low-oxygen conditions. Therefore, this bioactive compound may well be beneficial to patients with pancreatic carcinoma.

Pharmacological intervention to prevent or ameliorate chronic radiation injuries

Until the 1990s, chronic radiation-induced normal-tissue injury was viewed as being due solely to the delayed mitotic death of parenchymal or vascular cells; these injuries were held to be inevitable, progressive, and untreatable. It is now clear that parenchymal and vascular cells are active participants in the response to radiation injury rather than passive observers dying as they attempt to divide. This offers fundamentally new approaches to radiation injury because it allows for the possibility of pharmacological interventions directed at modulating steps in the cascade of events leading to expression of injury. Such interventions would be relevant to both cancer patients and victims of radiation accidents. Prophylaxis and treatment of chronic radiation injuries have been experimentally shown in multiple organ systems (eg, lung, kidney, soft tissue) and with fundamentally different pharmacological agents (eg, corticosteroids, angiotensin-converting enzyme inhibitors, pentoxifylline, superoxide dismutase). For the most part, this has been achieved using clinically relevant radiation and drug schedules and with agents that have already been approved for human use. Unfortunately, assessment of the utility of these agents for clinical use has been minimal, and there are no established mechanisms for any of the experimental or clinical successes. Clinical development of pharmacological approaches to modification of chronic radiation injuries could lead to significant improvement in survival and quality of life for radiotherapy patients and for victims of radiation accidents or nuclear terrorism.

The modification of human tumour blood flow using pentoxifylline, nicotinamide and carbogen

AIM

To assess the effect of combining oral nicotinamide, oral pentoxifylline and carbogen gas (2% CO2, 98% O2) breathing on human tumour red cell flux.

METHODS AND MATERIALS

Microregional red blood cell flux was measured in accessible tumour nodules using laser Doppler microprobes in 11 patients with histologically proven malignancy. Patients received single oral doses of nicotinamide 40 mgkg-1 and pentoxifylline 1200 mg 2h before a 10-min period of carbogen gas breathing, corresponding to peak plasma concentrations of these drugs. Red cell flux in up to six microregions in each tumour was measured for 30 min, recording pre-, during and post-carbogen breathing for 10 min each.

RESULTS

Data from ten of the 11 patients could be assessed. The red cell flux in 48 microregions was analysed and the mean red cell flux was calculated. A mean relative increase in red cell flux of 1.18 (+/-0.09, 95% confidence interval (CI)) was observed after 6 min of carbogen breathing, 2h after the administration of nicotinamide and pentoxifylline. This compares to relative increases of 1.4 (+/-0.39, 95%CI) after nicotinamide with carbogen and 1.15 (+/-0.10, 95%CI) after pentoxifylline with carbogen. These differences are not statistically significant (P>0.05). The increased red cell flux persisted after the cessation of carbogen gas breathing.

CONCLUSIONS

A combination of pentoxifylline, nicotinamide and carbogen produces an increase in human tumour red cell flux, similar to that observed when each of the drugs are used alone with carbogen breathing.