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Carbogen and Nicotinamide Increase Blood Flow and 5-Fluorouracil Delivery but not 5-Fluorouracil Retention in Colorectal Cancer Metastases in Patients

Authors' Affiliations: ¹ Cancer Research UK PET Oncology Group and Hammersmith Imanet, Hammersmith Hospital NHS Trust, London; ² Wolfson Molecular Imaging Centre, University of Manchester, Manchester, United Kingdom; and ³ Mount Vernon Hospital, Northwood, Middlesex

Requests for reprints: Pat Price, University of Manchester, Wolfson Molecular Imaging Centre, 27 Palatine Road, Manchester M20 3LJ, United Kingdom. Phone: 44-161-446-8003; Fax: 44-161-446-8111; E-mail: pat.price{at}manchester.ac.uk.

	Abstract

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Purpose: To examine whether carbogen and nicotinamide increases 5-fluorouracil (5-FU) delivery to colorectal cancer metastases.

Experimental Design: Six patients were scanned using positron emission tomography. Two scans were done to coincide with the start of separate chemotherapy cycles. At the second positron emission tomography session, 60 mg/kg nicotinamide was given orally 2 to 3 hours before 10-minute carbogen inhalation. In the middle of carbogen treatment, [¹⁵O]H₂O (to measure regional tissue perfusion) and then [¹⁸F]5-FU (to measure 5-FU tissue pharmacokinetics) were administered.

Results: Regions of interest were drawn in 12 liver metastases, 6 spleens, 6 livers, and 12 kidneys. Nicotinamide and carbogen administration increased mean blood pO₂ from 93 mm Hg (95% confidence interval, 79-198) to 278 mm Hg (95% confidence interval, 241-316; P = 0.031). Regional perfusion (mL_blood/min/mL_tissue) increased in metastases (mean change = 52%, range –32% to +261%, P = 0.024), but decreased in kidney (mean change = –42%, range –82% to –11%, P = 0.0005) and liver (mean change = –34%, range –43% to –26%, P = 0.031). 5-FU uptake at 3.75 minutes (m²/mL) increased in tumor (mean change = 40%, range –39% to +196%, P = 0.06) and decreased in kidney (mean change = –25%, range –71% to 12%, P = 0.043). 5-FU delivery measured as K₁ increased in tumor (mean change = 74%, range –23% to +293%, P = 0.0039). No differences were seen in [¹⁸F]5-FU tumor exposure (net area under curve) and retention.

Conclusion: Nicotinamide and carbogen administration can increase 5-FU delivery to colorectal cancer liver metastases. Despite an increase in perfusion and 5-FU delivery, the effects were not directly related and did not increase 5-FU retention or tissue exposure.

It is postulated that the administration of nicotinamide and carbogen to patients with metastatic colorectal cancer should selectively increase the uptake of 5-FU into a tumor, by increasing tumor blood flow, without changing the systemic exposure to the drug. The nicotinamide and carbogen combination is being explored as an approach for reducing tumor hypoxia, an important cause of cancer treatment resistance (7), and improving radiotherapy response (8–11). Nicotinamide, an amide of vitamin B₃, can increase tumor blood flow via a mechanism thought to involve the stabilization of the tumor microvasculature (reducing contractility and fluctuations in blood flow; refs. 12, 13) and a decrease in interstitial fluid pressure (14). Additional mechanisms involving an effect of nicotinamide on tumor metabolism have also been implicated (9, 15). Carbogen (oxygen plus 3-5% carbon dioxide) increases blood flow and the amount of oxygen that can diffuse into tumors via a mechanism thought to involve the inhibition of hyperoxia-induced vasoconstriction (16–18). A combination of nicotinamide and carbogen was shown to increase the blood flow of human tumors (12, 19). For example, using laser Doppler probes, a 17% increase in human tumor blood flow was found 5 minutes after the start of carbogen inhalation, reaching a plateau at 8 to 10 minutes and rapidly dropping to baseline on cessation of carbogen inhalation (12). Moreover, in experimental tumors, carbogen increased the tumor uptake, half-life, and exposure of 5-FU, a finding attributed to an increase in the blood flow and a change in the pH gradient in the tumors (20).

The hypothesis behind the study reported here, therefore, was that nicotinamide and carbogen would increase 5-FU uptake in colorectal cancer liver metastases by increasing tumor blood flow and thus drug delivery. To test this hypothesis, the effect of nicotinamide and carbogen on tumor and normal tissue blood flow and 5-FU pharmacokinetics was studied using [¹⁵O]H₂O and [¹⁸F]5-FU positron emission tomography (PET). The measurement of tumor blood flow using [¹⁵O]H₂O PET is an established technique (21, 22). The use of PET to study the in vivo pharmacokinetics of 5-FU in cancer patients has also been described (6, 23–25). Recently, we showed that [¹⁸F]5-FU PET can provide a highly sensitive and quantitative pharmacokinetic analysis of 5-FU in tissues (24), and that the delivery of [¹⁸F]5-FU to tumors is lower than to normal tissues, such as the spleen, liver, and kidney (26).

	Materials and Methods

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Patients and study outline. Ethical approval was obtained from the Hammersmith and Charing Cross Hospital Research Ethics Committees and permission to administer radioisotopes was granted from the Administration of Radioactive Substances Advisory Committee of the United Kingdom. Informed consent was obtained from all patients. Eight patients with colorectal cancer metastases receiving first-line chemotherapy with 5-FU/folinic acid were enrolled (five from the Hammersmith Hospital and three from the Charing Cross Hospital). Inclusion criteria included an ability to swallow and retain oral medication. Exclusion criteria included patients with a history of chronic pulmonary obstructive disease, which would impair their hypoxic respiratory drive and make them intolerant of the high oxygen content of carbogen. Chemotherapy consisted of 5-FU plus folinic acid given as the de Gramont regimen (folinic acid 200 mg/m² 2-hour infusion, 5-FU 400 mg/m² bolus, and 600 mg/m² 22-hour continuous infusion, days 1 and 2, repeated every 2 weeks) or modified de Gramont regimen (folinic acid 350 mg, 5-FU 400 mg/m² bolus and 2,800 mg/m² 46-hour continuous infusion, repeated every 2 weeks). Patients underwent two PET scanning sessions, separated by a minimum of 2 weeks and a maximum of 2 months. Scanning was done in the early afternoon to avoid diurnal variation in the metabolism of 5-FU (27). The first scanning session occurred on day 1 of the de Gramont regimen and did not involve administration of nicotinamide and carbogen. [¹⁸F]5-FU was given concurrently with the administration of therapeutic bolus 5-FU. The second scanning session occurred during a subsequent cycle of chemotherapy and patients were given 60 mg/kg nicotinamide orally 2 to 3 hours before scanning commenced. Carbogen (95% oxygen, 5% carbon dioxide) inhalation began 5 minutes before the start of both the [¹⁵O]H₂O and [¹⁸F]5-FU scans and continued for a further 5 minutes during each scan. Patients breathed carbogen (delivered at 10 L/min) through tightly fitting masks.

PET scanning. Imaging was done at the Hammersmith Hospital using an ECAT 931-08/12 PET (two-dimensional) scanner (CTI/Siemens, Knoxville, TN) allowing data collection from 15 planes with an axial field of view of 10.8 cm. Patients were positioned using data from a recent computed tomography scan and X-ray simulation, as described elsewhere (28). Positioning was confirmed using a short transmission scan after which a 20-minute transmission scan was carried out to correct for the attenuation of photons in the body. After insertion of arterial and venous cannulas, [¹⁵O]H₂O (29) was injected i.v. and the patients were scanned for 10 minutes. Ten minutes after completion of the water scan, [¹⁸F]5-FU (30) was administered as a 30-second i.v. bolus and the patients were scanned for a further 90 minutes.

Continuous arterial sampling was carried out during scanning to measure blood radioactivity (31). Discrete arterial samples were taken for calibration and to measure the contribution of parent and metabolite radioactivity in plasma and whole blood using reverse-phase high performance liquid chromatography (24). The arterial blood was also analyzed for CO₂ (mm Hg), O₂ (mm Hg), glucose (mmol/mL), and pH.

PET data analysis. Reconstructed PET images were analyzed and regions of interest (ROI) drawn using a recent computed tomography scan to assist delineation of tumor and normal tissue areas. ROIs were defined using ANALYZE image analysis software (Biomedical Imaging Resource, Mayo Foundation, Rochester, MN) on summated images rather than individual time frames. The ROIs were defined on a minimum of three consecutive slices and the top and bottom planes were not sampled to reduce the effect of organ movement. The ROI was projected onto the dynamic scan to measure the radioactivity of individual time frames for each plane defined, and the mean voxel count for the midframe time was calculated. Voxel counts in kBq/mL were decay corrected and normalized for body surface area and injected activity, using the following equation:

where is the decay constant (1.053 x 10^–4 s^–1 for ¹⁸F and 5.6896 x 10^–3 s^–1 for ¹⁵O) at time (t) and BSA is body surface area. The normalized data were plotted against midframe times to obtain a tissue activity curve. The area under the tissue activity curve (AUC_{0-90 minutes}, m².min.mL^–1) was calculated as a measure of tissue exposure to the radiotracer. The standardized uptake value (SUV) was calculated at various time points to measure the uptake of the radiotracer into tissues. The SUV at 3.75 minutes (SUV_3.75) was used as a measure of early [¹⁸F]5-FU uptake (32).

[¹⁸F]5-FU PET data were also analyzed using kinetic modeling. Spectral analysis (33, 34) was used to obtain K₁, the clearance of [¹⁸F]5-FU from plasma to tissue (mL_blood/min/mL_tissue) as a measure of 5-FU delivery. Spectral analysis was also used to obtain the impulse response function (IRF) at different time points from which the fractional retention of [¹⁸F]5-FU (FRF) was obtained (FRF = IRF_{60 minutes}/IRF_{1 minute}) as a measure of 5-FU retention (with some contribution from radiolabeled catabolites of [¹⁸F]5-FU in tissues).

The [¹⁵O]H₂O PET data were modeled using the modified Kety-Schmidt equation, adjusted for use in dynamic [¹⁵O]H₂O PET scans (21, 35), to measure regional perfusion (mL_blood/min/mL_tissue) and the volume of distribution (V_d) of water in normal tissue and tumor ROIs. Parameters for the liver are only an index of perfusion and V_d because the liver has a dual blood supply from the hepatic artery and portal vein, and are thus only approximated by the one compartment blood flow model (36). Cardiac output (L/min) was calculated from the recorded on-line arterial blood [¹⁵O]H₂O curve, as described elsewhere (37).

Statistical analyses. Data were analyzed using the nonparametric paired Wilcoxon signed rank and Mann-Whitney tests for group comparison. Correlations were calculated using Pearson's correlation coefficient. All statistical tests were two sided and a 0.05 significance level was used.

	Results

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Patients. Eight patients were enrolled, four male and four female, with a mean age of 65 years (range 59-78 years). The mean injected activity of [¹⁸F]5-FU was 345 MBq (range 136-403 MBq) and the mean injected dose of 5-FU was 380 mg/m² (range 300-400 mg/m²). One of the eight patients did not tolerate carbogen, and another patient did not have a second scan due to disease progression. In the remaining six patients (three male, three female), no side effects were recorded after oral nicotinamide but two patients complained of minor difficulty with the tightness of the mask during carbogen inhalation. A total of 15 metastases in the six patients were scanned. Table 1 outlines the data obtained in six patients. Incomplete data were obtained on one liver metastasis that responded to treatment and became too small for measurement of flow and V_d and in two liver and two lymph node metastases of <2 cm size, which were subsequently found to be too small for spectral analysis.

View larger version (9K): [in this window] [in a new window]   Fig. 1. Effect of nicotinamide and carbogen on arterial blood partial pressure of oxygen (pO2). Points, mean from six patients; bars, SE. During the second scan, patients received nicotinamide and carbogen. Measurements were made over 95 minutes and for the second scan started 5 minutes before the start of carbogen inhalation.

View larger version (37K): [in this window] [in a new window]   Fig. 2. Typical transabdominal computed tomography (A), [15O]H2O (B), and [18F]5-FU (C) images for a patient with metastatic colorectal cancer. Arrows, analyzed tissues.

View larger version (24K): [in this window] [in a new window]   Fig. 3. Effect of nicotinamide and carbogen on regional perfusion (left column) and volume of distribution of water (Vd; right column) in tumor, spleen, kidney (right and left), and liver. Data for 12 liver and 2 lymph node (LN) metastases analyzed in six patients (1 to 6, individual patients; a to d, separate metastases analyzed). Black columns, without nicotinamide and carbogen; dotted columns, with nicotinamide and carbogen. Measurements were not obtained for all metastases (Table 1).

Effect of nicotinamide and carbogen on 5-FU pharmacokinetics. Administration of nicotinamide and carbogen increased the early uptake of [¹⁸F]5-FU to the colorectal liver metastases, seen as an increase in tumor SUV_3.75 (mean change 40%, range –39% to 196%, P = 0.064). There were no significant changes in either spleen or liver SUV_3.75, but a significant decrease was seen in kidney (mean change –25%, range –71% to 12%, P = 0.043; Table 4 ). Figure 4 outlines the changes in SUV_3.75 in the 12 liver metastases and normal tissue. No statistically significant effects of nicotinamide and carbogen were seen on 5-FU exposure measured as AUC_{0-90 minutes}.

View larger version (20K): [in this window] [in a new window]   Fig. 4. Effect of nicotinamide and carbogen on 5-FU uptake (measured as SUV3.75) in different tissues. Data for 14 metastases in six patients. Black columns, without nicotinamide and carbogen; dotted columns, with nicotinamide and carbogen. Measurements were not obtained for all metastases (see Table 1).

View larger version (17K): [in this window] [in a new window]   Fig. 5. Effect of nicotinamide and carbogen on 5-FU delivery (measured as K1) in tumor and spleen. Data for 10 metastases in six patients. Black columns, without nicotinamide and carbogen; dotted columns, with nicotinamide and carbogen. Measurements were not obtained for all metastases (see Table 1).

View larger version (13K): [in this window] [in a new window]   Fig. 6. Correlations between SUV3.75 and perfusion (top left), AUC and perfusion (bottom left), SUV3.75 and Vd water (top right), and AUC and Vd water (bottom right) in 12 liver and 2 lymph node metastases before intervention.

	Discussion

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As expected, arterial pO₂ rose rapidly in response to carbogen administration and returned to normal within a few minutes after discontinuation of the inhalation. This finding agrees with data from a nonclinical study where arterial pO₂ returned to pretreatment levels 10 minutes after discontinuation of hyperoxia (38). In addition, in both studies, the blood pH remained unchanged. However, in the animal model, there was a 36% increase in arterial pCO₂ in response to carbogen, which remained elevated for at least 10 minutes after the cessation of carbogen inhalation. As there was a lack of change in arterial pCO₂ in our study, it remains unclear whether the observed changes in blood flow are indeed due to the significant temporary increase of arterial pO₂ and question the contribution of the inspired CO₂ fraction. However, further work is needed to clarify the complex physiologic changes that might occur in response to nicotinamide and carbogen administration in man.

Using PET, we were able to investigate concurrently a number of normal tissues, namely kidney, liver, and spleen. Tissue type–dependent changes in perfusion were seen, consistent with a study in an experimental tumor model, where perfusion of the liver and kidney significantly decreased and an increase in perfusion in the spleen was noted after carbogen inhalation (17). In the animal study, the increase in splenic perfusion was further attenuated by the addition of nicotinamide and largest in treatment with nicotinamide only. We saw a dramatic decrease in renal flow in response to nicotinamide and carbogen. This reduction in kidney perfusion, and corresponding decrease in water V_d, suggests that in man renal blood vessels shut down in response to nicotinamide and carbogen. A reduction of flow index was also seen in the liver where there was also a tendency for V_d to decrease (Fig. 3). As cardiac output was maintained, the effect on kidney and liver perfusion indicate mechanisms of autoregulation in these organs. Acute local blood flow control is normally achieved by rapid changes in local constriction of arterioles to maintain a constant supply of oxygen to the tissue (39). As there was no significant increase of pCO₂ in this study, the changes seen in normal tissue are likely to stem from the local effects of hyperoxia. This suggestion is further supported by the lack of changes in liver or kidney perfusion with nicotinamide only in the animal model. In analogy with the animal study, the lack of change in blood flow in the spleen could be explained by suspension of any improvement in flow with nicotinamide by the vasoconstricting effect of the increased pO₂; however, evaluation of the exact mechanism would have required separate studies with either nicotinamide or carbogen inhalation.

Our study confirms the inferior blood flow in colorectal liver metastases compared with normal tissues, such as spleen, kidney, and liver. This finding, together with the significant correlation between tumor perfusion and tissue exposure of 5-FU before carbogen and nicotinamide administration, supports the theory that impaired tumor perfusion contributes to the poor response of colorectal cancer metastases to chemotherapy (6). As noted in previous studies, the effects of nicotinamide and carbogen on tumor perfusion seem to be site dependent (40). We saw a 32% increase in perfusion of the liver metastases in response to nicotinamide and carbogen administration, whereas perfusion of the two lymph node metastases decreased. A 22% increase was measured by laser Doppler probes in skin metastases and s.c. nodes in advanced human tumors (12), but no changes in perfusion were found in human glioblastoma or normal brain when evaluated with single photon emission computed tomography (41).

The changes in perfusion observed in normal tissues and tumor in this study suggests an augmentation of blood flow in tissues less capable of local vascular control mechanisms, such as tumor. This finding is consistent with the theory that the steal, or in this case better described as "gain" phenomenon, is the dominant mechanism for redistribution of host blood flow to tumor (42). The V_d of water in tumors did not alter in response to nicotinamide and carbogen administration, suggesting that there was no recruitment of previously nonfunctioning vessels in the liver metastases. In animal models, vasoconstrictor-induced increase in the mean blood pressure has led to increases in tumor blood flow but also interstitial fluid pressure (42). High interstitial fluid pressure may also explain the lack of correlation between tumor blood flow and 5-FU delivery measured as K₁ at baseline. However, the tumor is likely to be responding in a complex and heterogeneous manner. Parts of the tumor might be responding by an increase in flow with an increase in 5-FU extraction, whereas others might respond with an increase in V_d but no changes in flow. For example, in one tumor, there was a large increase in K₁, no change in flow, but an increase in V_d and, therefore, more of tumor tissue being perfused. In another patient, there was a large increase in flow and V_d, but only a modest increase in K₁, which is likely to be due a reduction in the single-pass extraction fraction due to the very high flow (43). The available data suggest that in humans, perfusion of liver metastases increases in response to nicotinamide and carbogen, with the underlying mechanisms requiring further research.

The early uptake of [¹⁸F]5-FU (measured as SUV_3.75) was higher in the normal tissues studied than in the liver metastases, a finding that mirrored the higher normal tissue perfusion. This observation, together with a significant correlation between tumor perfusion and SUV_3.75 before intervention, suggests that [¹⁸F]5-FU uptake is related to tissue perfusion in liver metastases. The data show that nicotinamide and carbogen can increase tumor perfusion, although the effect on [¹⁸F]5-FU uptake and delivery varied between individual metastases. These findings are similar to changes observed in mice, where only large tumors showed increased uptake of 5-FU in response to carbogen (20). In our study, all five liver metastases larger than 4 cm had increased K₁ and SUV_3.75 values. In contrast, the effect of carbogen on 5-FU uptake and delivery in tumors <4 cm in size was variable and was not consistent with changes in regional tumor perfusion.

The tissue exposure and retention of [¹⁸F]5-FU (measured as AUC_{0-90 minutes} or FRF, respectively) was unaffected by nicotinamide and carbogen, even in the larger tumors studied. This finding contrasts with that of McSheehy et al. (20) who showed a carbogen-induced increase in 5-FU retention measured using MRS in murine RIF-1 tumors. The group related the increase in 5-FU retention to a differential increase in extracellular versus intracellular pH, thus creating a proton pump gradient favoring intracellular retention of 5-FU in tumors (44). The lack of change in intratumoral retention of [¹⁸F]5-FU may be due to the 20-minute shorter duration of carbogen breathing in our study, the lack of change in blood pH, or a cancellation of the increased delivery because of an increased rate of washout. Indeed, we have not evaluated the transport out of the intracellular volume of the metastases (k_out) and it has previously been shown that trapping of 5-FU with an increase in AUC can only be expected if the transport into the metastases (k_in) outweighs k_out (23). In our study, a significant correlation between K₁ and AUC_{0-90 minutes} before, but not after, nicotinamide and carbogen (data not shown) suggests that the increased flow may also lead to an increased washout. However, further study is required to examine the effects of nicotinamide and carbogen on 5-FU extraction from tissues. Future studies with MRS would also be of interest to identify any chemical species for which there might be an increased exposure or retention.

An important criterion to be considered is the potential effect of nicotinamide and carbogen on normal tissue toxicity. A recent paper highlighted an unexpected MRS detection of 5-FU anabolites in the metastasis-free liver of a patient, raising the issue of increased hepatocellular toxicity with concurrent carbogen breathing (45). However, studies in rats did not find any carbogen-induced change in the liver or small intestine levels of 5-fluoro-2'-deoxyuridine-5'-monophosphate measured using MRS. Our own study has corroborated the rat studies and indicates a lack of increased delivery and retention of [¹⁸F]5-FU in kidney, spleen and liver.

In summary, this study provides evidence that manipulation of tumor perfusion by nicotinamide and carbogen can increase [¹⁸F]5-FU delivery in liver metastases. A significant reduction in renal blood flow and hepatic perfusion index in response to nicotinamide and carbogen suggests an indirect effect on colorectal cancer metastases in the liver, possibly via redistribution of blood from vascular normal liver parenchyma to tumor. The methodologies developed here should be useful for the assessment of other approaches being developed to improve the delivery of chemotherapeutic drugs to human tumors, and for the appraisal of the effects of nicotinamide and carbogen on other compounds such as molecularly targeted agents. The lack of effect of nicotinamide and carbogen on 5-FU exposure and retention in tumors and the dramatic effect on renal perfusion suggest further studies are required.

	Footnotes

 
Grant support: Medical Research Council grant and Cancer Research UK grants C153/A1797 and C153/A1802. This research was supported by EC FP6 funding (Contract no. LSHC-CT-2004-505785). This publication does not necessarily reflect the views of the EC. The Community is not liable for any use that may be made of the information contained herein.

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Note: The protocol for this project was developed by Azeem Saleem, at the III workshop on "Methods in Clinical Cancer Research", jointly organized by federation of European Cancer Societies, American Association for Cancer Research and American Society of Clinical Oncology in Flims, Switzerland, 2001.

Received 3/ 7/05; revised 11/28/05; accepted 12/ 9/05.

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