Review

Nature Clinical Practice Oncology (2007) 4, 86-100
doi:10.1038/ncponc0714  
Received 20 March 2006 | Accepted 18 September 2006

The concurrent chemoradiation paradigm—general principles

Tanguy Y Seiwert*, Joseph K Salama and Everett E Vokes  About the authors

Correspondence *University of Chicago, 5841 South Maryland Avenue, MC 2115, Chicago, IL 60637–1470, USA

Email tseiwert@medicine.bsd.uchicago.edu

Summary

During the past 20 years, the advent of neoadjuvant, primary, and adjuvant concurrent chemoradiotherapy has improved cancer care dramatically. Significant contributions have been made by technological improvements in radiotherapy, as well as by the introduction of novel chemotherapy agents and dosing schedules. This article will review the rationale for the use of concurrent chemoradiotherapy for treating malignancies. The molecular basis and mechanisms of action of combining classic cytotoxic agents (e.g. platinum-containing drugs, taxanes, etc.) and novel agents (e.g. tirapazamine, EGFR inhibitors and other targeted agents) with radiotherapy will be examined. This article is part one of two articles. In the subsequent article, the general principles outlined here will be applied to head and neck cancer, in which the impact of concurrent chemoradiotherapy is particularly evident.

Review criteria

The information for this Review was compiled using the PubMed and MEDLINE databases for articles published until 15 June 2006. Electronic early-release publications were also included. Only articles published in English were considered. The search terms used included "chemoradiotherapy" or "chemoradiation" in association with the following search terms: "reviews", "radiosensitizer", "concurrent", "mechanism", "molecular", "cell cycle", "cytotoxic chemotherapy", "hypoxia", "targeted therapies", "radioresistance", "cisplatin", "tirapazamine", "carboplatin", "oxaliplatin", "5-FU", "gemcitabine", "capecitabine", "pemetrexed", "paclitaxel", "mitomycin C", "hydroxyurea", "temozolomide", "amifostine", "palifermin", "EGFR", "Met", "STAT 1", and "VEGF". Full articles were obtained and references were checked for additional material when appropriate. References were chosen based on the best clinical or laboratory evidence, especially if the work had been corroborated by published work from other centers. Priority was given to studies in high impact factor journals when available.

Keywords:

chemoradiation, cytotoxic, radiation, resistance, synergistic

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Introduction

Three clinical rationales support the use of chemotherapy delivered concurrently with radiation. First, concomitant chemoradiotherapy can be used with organ-preserving intent, resulting in improved cosmesis and function compared with surgical resection with or without adjuvant treatment. Second, chemotherapy can act as a radiosensitizer, improving the probability of local control and, in some cases, survival, by aiding the destruction of radioresistant clones (Table 1). Third, chemotherapy given as part of concurrent chemoradiation may act systemically and potentially eradicate distant micrometastases.

Table 1 Overview of disease entities and indications in which concurrent chemoradiotherapy is used.a
Table 1 - Overview of disease entities and indications in which concurrent chemoradiotherapy is used.a
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Clinical application—disease entities

Currently, concomitant chemoradiotherapy is widely used in the treatment of solid tumors. In almost all malignancies in which locoregional control is necessary, concurrent chemoradiotherapy is either an established treatment modality or is actively being investigated. The optimum schedules, synergistic combination of agents, and integration of targeted therapies are also areas of active investigation. Chemoradiotherapy combinations for individual diseases with their specific indications and limitations are beyond the scope of this article; however, an overview of the most common uses is shown in Table 1. In the next issue of this journal, the application of chemoradiotherapy in head and neck cancer will be detailed, exemplifying some of the principles outlined here.

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Theoretical framework for therapy—the 'steel paradigm'

In 1979, Steel and Peckham introduced a theoretical framework to describe the interaction of cytotoxic chemotherapy and radiotherapy.1 The term spatial cooperation is used to describe the scenario whereby radiotherapy acts locoregionally, and chemotherapy acts against distant micrometastases, without interaction between the agents (Figure 1). This cooperative effect requires the agents to have non-overlapping toxicity profiles in order that both modalities can be used at effective doses without increasing normal tissue effects. When combined concurrently with radiotherapy, however, few chemotherapeutic agents meet this criterion, because limited single-agent activity or toxicity-driven dose reductions preclude the delivery of systemic dosing schedules. Many trials of concomitant chemoradiotherapy, however, have demonstrated decreased incidence of distant metastases compared with radiation alone. This evidence could indicate that chemotherapy delivered at radiosensitizing doses has some systemic spatial cooperative effect, or that the improved local control of chemoradiotherapy decreases subsequent metastases.

Figure 1 Rationale for adding chemotherapy to radiation.
Figure 1 : Rationale for adding chemotherapy to radiation. Unfortunately we are unable to provide accessible alternative text for this. If you require assistance to access this image, or to obtain a text description, please contact npg@nature.com

Spatial and in-field cooperation are the two idealized types of cooperation between radiation and chemotherapy. Both mechanisms can contribute synergistically to clinical benefit. aUsually not desirable as this could protect the tumor.

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The second interaction between radiation and chemotherapy is radiation 'sensitization', which is either additive or supra-additive: the interaction within the radiation field leads to increased killing of cells (cytotoxic activity) either to the same degree as (additive) or more than (supra-additive) using both modalities sequentially (Figures 1 and 2). Strictly speaking, radiosensitizers shouldn't have inherent cytotoxic activity. The hypoxic cell sensitizers (e.g. misonidazole), and thymidine analogs (e.g. bromodeoxyuridine) are examples of 'true' radiosensitizers; however, the radiosensitizers most commonly used today (cisplatin, 5-fluorouracil [5-FU], and taxanes) do have inherent cytotoxic activity and can increase damage to normal tissues, with a 'true' benefit achieved only if the increase in antitumor effect is larger than the normal tissue damage (Figure 3).

Figure 2 Schematic example of an isobologram depicting the combination of radiation and a systemic agent.
Figure 2 : Schematic example of an isobologram depicting the combination of radiation and a systemic agent. Unfortunately we are unable to provide accessible alternative text for this. If you require assistance to access this image, or to obtain a text description, please contact npg@nature.com

The x and y axes show the isoeffective levels for radiation and drug. The thick line is the line of additivity, and the additivity envelope is based on the combined standard errors. Curves above the envelope represent antagonistic effects and curves below the envelope represent 'synergistic' effects.1, 41 Abbreviation: RT, radiotherapy.

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Figure 3 Schematic dose–response curves for tumor and normal tissue damage with radiation.
Figure 3 : Schematic dose|[ndash]|response curves for tumor and normal tissue damage with radiation. Unfortunately we are unable to provide accessible alternative text for this. If you require assistance to access this image, or to obtain a text description, please contact npg@nature.com

The offset between the two curves indicates the therapeutic range. Chemoradiotherapy leads to a shift of both curves to the left, ideally with a stronger shift of the tumor curve (as indicated by the longer arrow), increasing overall efficacy of treatment (radiation enhancement).120

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Infra-additive drugs possess radioprotective properties that lessen the cytoxic effect of radiation on the tumor and/or normal tissue. Ideally, such agents should be selective for normal tissue to allow administration of higher radiation doses. Several agents are being investigated and have shown promising early results with radiation alone, but for concurrent chemoradiotherapy definitive phase III evidence does not currently support their routine use. One such agent, amifostine—an organic thiophosphate—might decrease cisplatin-induced or radiation-induced toxicity by acting as a scavenger of free radicals, as well as by binding to and neutralizing organoplatinums and alkylating agents, thereby preventing DNA adduct formation. Although decreased incidence of xerostomia in patients with head and neck cancer treated with radiotherapy alone was convincingly demonstrated in a large trial,2 the benefit with concurrent chemoradiotherapy remains unclear, as demonstrated by a phase III study showing no significant difference in xerostomia or mucositis rates.3 Although a single-institution trial of patients with advanced lung cancer randomized to receive concurrent cisplatin, etoposide, and twice-daily radiation demonstrated a decrease in grade 1–2 esophagitis, grade 3 pneumonitis, and neutropenic fever, an increase in sneezing, dysgeusia (loss of taste), and more importantly hypotension, was observed.4 In a larger phase III trial conducted by the Radiation Therapy Oncology Group, addition of amifostine to radiotherapy did not demonstrate any difference in grade 3 or greater esophagitis, although patients had a statistically significant, although small (1.3%) decrease in weight loss.3 Concerns that radiation protectors might have a tumor protective effect has limited their use; however, two large meta-analyses did not confirm this concern.5, 6 At doses lower than those used for normal tissue protection, amifostine has been shown to have antimutagenic properties.7

The agent palifermin, a recombinant human keratinocyte growth factor, reduces oral mucositis in patients undergoing radiation and chemotherapy for autologous stem-cell transplant and in metastatic colorectal cancer treated with 5-FU.8, 9 This drug is currently undergoing phase III testing with concurrent chemoradiotherapy in patients with advanced head and neck cancer.

Determination of additive effects between chemotherapy and radiation

The type of interaction between chemotherapy and radiotherapy within the radiation field (supra-additivity, additivity, or infra-additivity) can be determined. For this purpose, Steel and Peckham described the isobologram analysis, which is based on an isoeffect concept for chemoradiotherapy interaction (Figure 2).1 Independent dose–response curves for chemotherapy and radiotherapy are necessary to create a plot, called an isobologram. The isobologram is generated by plotting the dose of each agent (i.e. chemotherapy and radiotherapy) against each other, which produces a cytotoxic effect (isoeffect) on the axes of increasing dose of each agent. Two curves, named 'mode 1' and 'mode 2', can then be generated (Figure 2). The mode 1 curve results from the assumption that radiation and chemotherapy act independently, and is created by plotting a given dose of radiation against the dose of chemotherapy needed to produce an effect equal to the difference between the chosen cytotoxic effect and the effect of the current dose of radiation. The mode 2 curve assumes that radiation and chemotherapy have identical mechanisms of action. Points on this curve are generated by plotting doses of radiation against the doses of chemotherapy needed to increase the effect of the dose of radiation to the chosen cytotoxic effect. Multiple points on both of these lines are obtained by varying the radiation dose and calculating the appropriate doses of chemotherapy. Finally, the true (empiric) survival curve is generated for radiation and chemotherapy given in combination. The doses of each agent needed to produce the chosen cytotoxic effect are plotted. Points that fall below the envelope between mode 1 and 2 curves indicate supra-additivity, data points occurring within the envelope (between the two curves) indicate additivity, and data points above the envelope indicate infra-additivity. Further details and sample calculations are provided elsewhere.10, 11

Other methods exist to determine types of additivity, including the median effect principle and the response surface approach, both of which are described in detail elsewhere.12, 13, 14, 15 Unfortunately, the concept of additivity is of limited use in clinical practice, as preclinical prediction of additivity does not translate well into clinical outcomes. The use of this method is, therefore, limited to forming hypotheses, which need to be confirmed empirically.

Quantification of the chemotherapy and radiation interaction

The radiosensitizing ability of a drug can be expressed by the therapeutic ratio. This ratio is derived from sigmoid-shaped dose–response curves, calculated by plotting the response of tissues (both normal and tumor) on the ordinate axis versus the chemotherapy or radiation therapy dose on the abscissa (Figure 3). The therapeutic ratio is defined as the quotient of the dose that produces a 50% tumor control rate and the dose that produces a 50% normal tissue toxicity rate. When chemotherapy is combined with radiation, both normal tissue and tumor control curves produced by radiation alone shift to the left because of the chemotherapy-induced sensitization of cells. Ideally, radiation sensitizers should influence the tumor response curve more than the normal tissue curve, thus resulting in a greater than one therapeutic ratio. Similar to the concept of additivity, therapeutic ratios are mainly hypothesis-forming and need to be tested empirically in phase I and II studies. Such preclinical data may help in the initial dose schedule selection for phase I trials.

Mechanisms of radiation resistance or failure

Tumors have developed multiple strategies to resist radiation damage. Table 2 gives an overview of the most widely accepted mechanisms. Simplistically, larger tumors have a stochastic chance that some cells will survive radiotherapy. Moreover, hypoxic tumor cells have increased resistance to radiation; multiple studies have demonstrated that hypoxic cells exhibit 2.5–3.0 times the resistance to radiotherapy damage compared with normoxic cells.16, 17, 18, 19, 20 As shown in Figure 4, the phases of the cell cycle significantly influence the radiosensitivity of cells.21

Figure 4 Cell-cycle schematic and respective sensitivity to chemotherapeutic agents.
Figure 4 : Cell-cycle schematic and respective sensitivity to chemotherapeutic agents. Unfortunately we are unable to provide accessible alternative text for this. If you require assistance to access this image, or to obtain a text description, please contact npg@nature.com

 

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One of the most commonly invoked underlying mechanisms in treatment failure22, 23 is tumor cell repopulation, which results in a rapid growth between radiation fractions. Although incompletely understood, the stimulation of growth factors and the selection of resistant clones lead to rapid emergence of treatment resistance.22, 24, 25 In addition, rapidly proliferating tumors contain a high proportion of radioresistant cells in the S phase of the cell cycle. For further information on repopulation, readers should refer to the excellent review by Schmidt-Ullrich et al.26

Certain tumors are intrinsically radioresistant, while others acquire mechanisms of radioresistance during treatment. Intrinsic radioresistance is seen when there is an increased surviving fraction of tumor cells after 2 Gy radiotherapy; this result is often depicted in a clonogenic radiation cell survival curve assay. Small increases in radioresistance lead to large, logarithmic decreases in final cell kill after radiotherapy. In some tumors, such evaluation in radioresistance in pretreatment biopsies predicts for radiosensitivity and clinical outcome, although these findings have so far not been widely reproducible.27, 28 Activation of certain prosurvival pathways that prevent apoptosis can induce treatment resistance. Among the many pathways implicated are mutated p53,29 amplification of DNA repair genes, increased levels of reactive oxygen species scavengers, and activation of prosurvival/poor-prognosis oncogenes such as EGFR,30, 31 or c-MET (also known as MST1R).32, 33 Recently, gene-expression profiling has identified that radiation-resistant tumors overexpress many genes related to interferon pathways or induced by interferon itself, especially STAT1. Radiosensitive cells transfected with STAT1 demonstrated radioprotection after exposure to 3.0 Gy radiation.34

General mechanisms of chemotherapy and radiotherapy interaction

Seven major interactions between chemotherapy and radiation will be explained here and are listed in Table 3. For most chemotherapeutic agents several interactions apply at the same time. First, DNA damage can be induced by both chemotherapy and radiotherapy and synergy is possible. Ionizing radiation induces DNA base damage, alkali-labile sites, single-strand breaks, and double-strand breaks (DSBs). All of these errors can be rapidly repaired except for DSBs, which if not repaired are considered lethal.35, 36 The integration of cisplatin into DNA or RNA in close proximity to a radiation-induced single-strand break can act synergistically to make the defect significantly more difficult to repair (Figure 5).37, 38 Second, chemotherapy can inhibit post-radiation damage repair. DNA synthesis and repair share common pathways, which provide the rationale for using DNA synthesis inhibitors with radiation as a means of inducing cytotoxic damage to tumor cells. Agents affecting nucleoside and nucleotide metabolism can inhibit the repair of radiation-induced DNA damage in patients, and are among the most potent radiation sensitizers. Examples of such agents include the fluoropyrimidines, thymidine analogs, gemcitabine, and hydroxyurea. Third, administered concurrently, radiotherapy and chemotherapy often target different phases of the cell cycle and may cooperate to produce an additive effect (i.e. cytokinetic cooperation/synchronization). The radiosensitivity of a cell is dependent on the phase of the cell cycle; cells in the S phase are the most radioresistant, and cells in the G2–M phase of the cell cycle are the most radiosensitive (Figure 4).39, 40 In addition, cytokinetic cooperation of S-phase-specific agents (e.g. camptothecins, 5-FU, hydroxyurea) is seen if cells are exposed in close temporal proximity to radiation.41 Some drugs (e.g. taxanes) are able to synchronize with the cell cycle of tumor cells to allow increased efficacy of subsequent radiotherapy (called synchronization or cell-cycle pooling). This process was successfully shown in vitro, although the concept—especially its applicability in vivo—remains controversional.11, 42, 43 Fourth, the increased resistance of hypoxic cells to radiation (Table 2) means that hypoxic cell sensitizers may be beneficial.18, 44

Figure 5 Increased DNA damage by addition of cisplatin to radiation.
Figure 5 : Increased DNA damage by addition of cisplatin to radiation. Unfortunately we are unable to provide accessible alternative text for this. If you require assistance to access this image, or to obtain a text description, please contact npg@nature.com

aRadiation can also induce other DNA damage, of which double-strand breaks are considered lethal.

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Table 3 Mechanisms of chemotherapy and radiotherapy interaction.
Table 3 - Mechanisms of chemotherapy and radiotherapy interaction.
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Hypoxia is common in many cancers and was shown to be a marker of aggressive clinical behavior and poor prognosis.45 Chemotherapy can help eliminate these resistant cells and increase the efficacy of radiotherapy via multiple mechanisms (Table 3). Tirapazamine, and potentially mitomycin C, preferentially kill hypoxic cells. Additionally, paclitaxel,46 and EGFR inhibitors,24 were shown to shrink tumors, thereby increasing perfusion and oxygenation and reducing radioresistant hypoxic areas. This hypoxic effect might be applicable for many other agents. Fifth, repopulation of rapidly proliferating tumors is usually mediated by overexpression of growth factors and growth factor receptors, as well as increased activity of downstream signaling pathways, and the presence of activating mutations in genes involved at all levels of the signaling pathways. Agents that target the S phase of the cell cycle, such as 5-FU, irinotecan, and hydroxyurea, as well as those that inhibit proliferation and/or growth factor pathways, such as EGFR inhibitors, may be effective in preventing tumor cell repopulation, thereby radiosensitizing tumor cells.24, 47

In addition to their antiproliferative effects that prevent tumor cell repopulation, EGFR inhibitors and antiangiogenic agents can block signaling pathways that are responsible for aggressive tumor biology, poor prognosis, and radioresistance. Although the exact mechanisms of various targeted therapies vary and are generally poorly understood, preclinical48 and clinical49 data support the rationale for radiosensitizing properties as a consequence of inhibiting the detrimental effects of the agents' targets. Finally, some tumors resistant to 'standard' chemoradiotherapy respond to alterations in radiation fractionation. This phenomenon, termed hyperradiation sensitivity, is observed at radiation doses greater than 1 Gy. Preclinically, for both paclitaxel and docetaxel, low-dose fractionated radiation can overcome radioresistance.50 Clinical trials evaluating this technique are currently underway.

Specific mechanisms of chemotherapy and radiotherapy interaction

Platinum analogs

Cisplatin is one of the most commonly used drugs for concurrent chemoradiotherapy. Through interactions with nucleophilic sites on DNA and RNA, cisplatin introduces intrastrand and interstrand cross-links, thereby distorting the DNA structure, and blocking nucleotide replication and transcription. Active in both hypoxic and well-oxygenated cells,51 several potential mechanisms for cisplatin-mediated radiation sensitization were reported and summarized by Wilson and co-workers.41 It has been proposed that radiation induces free radicals and subsequently the formation of toxic platinum intermediates, which increase cell killing.52 Moreover, ionizing radiation can increase cellular uptake of platinum.53 Damage to DNA by ionizing radiation that typically would be repairable can become fixed and lethal through cisplatin's free-electron-scavenging capacity. This inhibition of DNA repair (Figure 5)54 leads to an increased incidence of cell-cycle arrest and apoptotic cell death after radiation.41, 55

In vitro studies have shown that the most synergistic combination of cisplatin and radiation involves low doses of each, either of which would be insufficient to cause cell death if administered alone. Cisplatin would seem to inhibit the sublethal damage repair process implicated in the recovery of insufficiently radiated cells.41 Radiosensitization by cisplatin and carboplatin may be limited to cells with an intact homologous recombination repair system,41, 56 but radiosensitization is not impacted by hypoxia. Oxaliplatin, a cisplatin-related compound, has been shown to have activity in cisplatin-resistant systems and unaltered sensitivity in mutated mismatch-repair systems.49 Although less well studied, oxaliplatin is postulated to have similar radiosensitization mechanisms to those of cisplatin.41

Antimetabolite-based chemoradiotherapy

5-fluorouracil

The halogenated pyrimidine nucleoside analog 5-FU is used extensively with radiation.57, 58 This analog impedes nucleic acid synthesis through thymidylate synthase inhibition, depleting the pool of nucleotide triphosphates, leading to cell-cycle changes, DNA fragmentation, and ultimately cell death.59 When 5-FU is incorporated into RNA and DNA it inhibits not only DNA synthesis, but also transcription and protein synthesis. Optimal 5-FU radiosensitization requires continuous administration of the agent during radiation because of the need for continuous thymidylate synthase inhibition, the short half-life of plasma 5-FU and intracellular phosphorylated 5-FU metabolites.

5-FU radiosensitization is postulated to occur by the agent's effect on the proportion of cells in the radioresistant S phase of the cell cycle. When given in standard doses, 5-FU is able to kill cells in the S phase. Additionally, at sublethal concentrations, 5-FU pre-incubation is hypothesized to radiosensitize tumor cells through changes in the S-phase cell-cycle checkpoint, which allow inappropriate progression out of the S phase into the G2 phase. This conjecture is supported by the fact that blocking the entry of cells into S phase prevents radiosensitization for a similar pyrimidine analog, fluorodeoxyuridine.57, 58 Impaired repair of radiation-induced DSBs might also contribute to 5-FU cytotoxicity and radiosensitization.57, 58

Capecitabine

Capecitabine is an oral prodrug that is converted to 5-FU via thymidine phosphorylase. Radiation has been shown to preferentially increase tumor thymidine phosphorylase levels via induction of tumor necrosis factor. In a colon cancer fluoropyrimidine-resistant xenograft model, exposure to capecitabine before irradiation demonstrated a supra-additive effect compared with radiation alone.60 Clinical trials are actively exploring the role of the combination of capecitabine and radiation therapy.

Gemcitabine

Gemcitabine is a widely used S-phase cell-cycle-specific pyrimidine analog that hinders DNA synthesis and repair through depletion of deoxynucleoside triphosphates that are required by two enzymes: DNA polymerase and ribonucleotide reductase. Gemcitabine has shown activity in many solid tumors, either alone or in combination with other agents (e.g. cisplatin or carboplatin).61 Initial clinical studies of pancreatic and lung cancer demonstrated marked toxicity of gemcitabine-based chemoradiotherapy and dampened enthusiasm for the efficacy of this drug, since only doses much lower than those used without radiation could be administered safely. Recent data from multi-institutional studies have shown that full doses of gemcitabine can be delivered with aggressive conformal radiation techniques.62, 64

In preclinical models, the potent radiosensitizing properties of gemcitabine were most pronounced with exposure to low doses of the agent at least 24 h before irradiation. Interestingly, sensitization persisted for up to 48 h, and radiation exposure before exposure to gemcitabine did not lead to sensitization. These observations are consistent with the time needed to deplete deoxynucleoside triphosphates (dATP) and transition through the S phase of the cell cycle.65, 66, 67 It seems that incorporation of incorrect bases secondary to deoxynucleoside triphosphate depletion and S-phase accumulation are the basis of the radiosensitizing properties of gemcitabine.65

Pemetrexed

This compound is a novel multitargeted antifolate that inhibits thymidylate synthase, dihydrofolate reductase, and glycinamide ribonucleotide formyl-transferase, all of which are key enzymes involved in nucleotide synthesis. Preclinical data suggest synergistic antitumor activity of pemetrexed and concurrent radiotherapy, and interference with DNA synthesis is thought to be the primary cytotoxic mechanism.68 Pemetrexed is not cell-cycle-specific as it shows equal efficacy in the G1 and S phases of the cell cycle.69 Although the exact interaction of pemetrexed with radiation is not fully understood, it has been postulated that prolongation of the S phase by radiation increases the intracellular drug exposure time and toxicity. Pemetrexed-based chemoradiotherapy is in phase I clinical testing in several tumor types.70

Hydroxyurea

Hydroxyurea acts as a radiation enhancer in vitro and in vivo51 and is useful for the treatment of head and neck cancer.71 This drug was previously used for squamous-cell carcinoma of the cervix (replaced by cisplatin)72 and gliomas (replaced by temozolomide),73 and was proposed for the treatment of pancreatic cancer (replaced by 5-FU and potentially gemcitabine).74 Ribonucleotide-reductase inhibition prevents radiation-induced DNA damage repair during nucleotide excision. Furthermore, hydroxyurea might also synchronize cancer cells at the G1–S checkpoint.74 The double action of hydroxyurea of cell-cycle synchronizing and DNA damage repair inhibition has been suggested as a mechanism for its more efficacious action as a radiation sensitizer at doses lower than for the ribonucleotide-reductase inhibitors gemcitabine and trimidox.74 Antimetabolites such as hydroxyurea are selectively cytotoxic to cells that are in the relatively radioresistant S phase of the cell cycle, which might contribute to overcoming radioresistance.

Taxane-based chemoradiotherapy

Paclitaxel and docetaxel form high-affinity bonds with microtubules, promoting tubulin polymerization and stabilization. At high doses, these drugs block prophase to metaphase progression, disrupting the centrosome network and thereby causing cell death.75 Despite the structural similarities of these two agents, differences in excretion and cell-cycle tropism instigate differing temporal interactions of paclitaxel and docetaxel with radiation.76

Two mechanisms for paclitaxel and docetaxel radiosensitization have been proposed. The standard explanation is that cells remain in the G2–M phase of the cell cycle, leading to synchronization (cell-cycle pooling) of tumor cells at a point of maximum radiosensitivity,11, 42 but it is still unclear whether cell-cycle redistribution occurs, especially in vivo.43 True synchronization in large tumors seems unlikely, and may not increase the therapeutic index as normal cells are also affected.77 Alternatively, taxanes can induce tumor shrinkage, improving perfusion and subsequent reoxygenation. As hypoxic areas of the tumor are reoxygenated they become more sensitive to radiation-induced cell kill.46 Paradoxically, low doses of taxanes may induce protection against radiation via possible alterations in signal transduction pathways. Pretreatment of a human laryngeal squamous cell line with 7.5 nmol/l paclitaxel 6 h before irradiation induced subadditive effects via G2 blockade.78 Extensive single-agent and chemoradiotherapy taxane mechanisms are reviewed by Hennequin and Favaudon.11

Mitomycin-C-based chemoradiotherapy

Mitomycin C inhibits DNA and RNA synthesis by interfering with DNA cross-linking, primarily at the guanine and cytosine pairs. Although mitomycin C is not cell-cycle-specific, this agent is known to induce marked cell-cycle arrest at the G2–M transition.79, 80 In combination with radiation, mitomycin C acts as a hypoxic cell sensitizer and is thought to prevent repopulation, although the exact mechanism remains elusive.81

Tirapazamine-based chemoradiotherapy

Tirapazamine is the lead compound in a class that has selective cytotoxic activity under hypoxic conditions (hypoxic cell cytotoxic).82 Hypoxic tumor cells that are relatively resistant to radiotherapy exhibit aggressive growth behavior, and portend a poor prognosis. Although widely recognized in its ability to enhance radiation,83 debate exists as to whether tirapazamine's effects are additive or supra-additive.84, 85 Regardless, theoretical models show that the killing of hypoxic cells might improve outcomes compared with standard radiosensitizers.86

Tirapazamine's approximately 100-fold increased potency under anoxic conditions occurs via electron donation, which causes formation of transient oxidizing radicals. In normoxic tissue these radicals quickly bind available molecular oxygen, re-establishing the nontoxic parent compound. In the absence of oxygen, however, these oxidizing radicals induce the formation of DNA radicals by extracting a proton from the C4 location of the deoxyribose ring on the DNA.87 This process can lead to cytotoxic DNA-strand breaks. Additionally, unknown mechanisms decrease topoisomerase II activity in tirapazamine-treated cells.88 Although little or no cell killing is observed in normoxic cells, systemic side effects including fatigue, muscle cramps, and reversible ototoxicity were observed during the clinical administration of tirapazamine, and have been attributed to a loss of mitochondrial membrane potential.89

Temozolomide-based chemoradiotherapy

Temozolomide is an orally administered cytotoxic alkylating agent, which readily crosses the blood–brain barrier; 30% of plasma concentrations are achieved in the cerebrospinal fluid.90 Commonly used to treat gliomas, temozolomide causes DNA damage by methylation of the O-6 position of guanine and activates the p53-controlled DNA damage response pathway.91 Tumors with methylation of the O-6-methylguanine DNA-methyltransferase (MGMT), a p53 DNA damage repair enzyme, are preferentially radiosensitized.92, 93 Temozolomide also inhibits signaling of radiation-triggered cell migration and invasiveness94 and decreases tumor cell repopulation.

The aim of combining temozolomide with radiation is the use of an intrinsically active agent that has a different toxicity profile to radiation.95 In a study by Wedge et al.,96 a glioblastoma cell line with no MGMT activity was compared with a colorectal cancer cell line with high repair activity. Temozolomide and radiation were additive in the glioblastoma line, whereas antagonism was observed in the colorectal cancer line. This finding is probably attributable to radiation induction of MGMT. Additionally, temozolomide and radiation showed additive and supra-additive activity.97

Advances in radiotherapy

While most advances in concurrent chemoradiotherapy have focused on the integration of novel systemic agents, recent technological improvements in radiotherapy have impacted directly on concurrent chemoradiotherapy. Intensity-modulated radiation therapy (IMRT) has allowed better delivery of radiation to the target volumes, allowing sharp dose gradients between targets and normal tissues. After clinical implementation of IMRT, decreased acute gastrointestinal, skin, hematologic, and salivary toxicity rates were reported, which improved the therapeutic index of radiation.98 These decreases in normal tissue toxicity could also improve the therapeutic index of chemoradiation. Additionally, implementation of image-guided radiotherapy via linear accelerator-based kilovoltage techniques, and gating radiation delivery with the respiratory cycle, will improve day-to-day targeting and potentially decrease acute and chronic toxicities of chemoradiotherapy.

Molecular-targeted therapies in combination with chemoradiotherapy

In the past decade, the promises of molecular-targeted agents have increasingly come to fruition, and these agents have been combined with radiotherapy in an effort to optimize the therapeutic index of drug dosing. Molecular-targeted therapies are an attractive option combined with chemoradiotherapy because they are more specific for the target and can inhibit radioresistance pathways. An extensive review of molecular-targeted agents and their interaction with radiotherapy has been published by Ma et al.99

EGFR-targeted therapies and chemoradiotherapy

The membrane-bound receptor tyrosine kinase EGFR is activated upon binding of the ligand (transforming growth factor alpha, epidermal growth factor), which induces dimerization and subsequent phosphorylation of the intracellular EGFR tyrosine residues. Upon activation, intracellular signaling cascades mediate various cellular responses important for tumor survival and growth—namely, increased proliferation, invasion, angiogenesis, and metastasis, and concomitant decreased apoptosis.

EGFR (erbB1) and the EGFR family members erbB2–4 are deregulated in head and neck, lung, breast, and colorectal cancers. Increased EGFR protein expression correlates with increased tumor size, recurrence risk, and radioresistance, and with decreased survival.100, 101 Cell culture experiments of radiation-induced EGFR expression and increased radioresistance, demonstrated by the addition of exogenous EGF, indicated a causal link between EGFR and radioresistance.102

Preclinical studies with the EGFR inhibitors cetuximab, gefitinib, and erlotinib show enhanced radiosensitivity leading to supra-additive efficacy both in vitro and in vivo.49, 100, 103 Proposed mechanisms for radiosensitization via EGFR inhibitors include inhibition of cell proliferation, impairment of DNA damage repair,104 attenuation of tumor neo-angiogenesis, inhibition of radiation-induced EGFR nuclear import,105 and promotion of radiation-induced apoptosis.106, 107 In particular, the antiproliferative effects of EGFR inhibition most likely prevent repopulation,100 a major mechanism implicated in radioresistance. The other mechanisms may well have a role in the supra-additivity of the anti-EGFR radiation combination.

Antiangiogenic and anti-VEGF therapy in combination with radiation

Angiogenesis is essential for sustained tumor growth, and many new cancer therapies are directed against modification of the tumor vasculature.108, 109 The process of angiogenesis is mediated by multiple proangiogenic and antiangiogenic factors, with VEGF having a central role.108, 109 Anti-VEGF agents fall into two broad categories: those that target the VEGR ligand, such as bevacizumab, and those that target the receptor, such as PTK787 (an antibody to VEGFR-2). Other antiangiogenic strategies include antiangiogenic factor administration to counterbalance proangiogenic stimuli, inhibition of extracellular matrix degradation enzymes, integrin antagonists, and therapies with direct endothelial cell toxicity.

Two mechanisms for radiosensitization with antiangiogenic agents have been proposed and could exist in parallel.109, 110 The traditional view is that antiangiogenic destruction of tumor vessels leads to hypoxia and starvation, which paradoxically could also increase tumor resistance.111 Increasingly, however, findings show that increases in blood flow, oxygen, and drug delivery (i.e. a transient normalization of the abnormal structure and function of tumor vessels) is seen as the underlying mechanism of antiangiogenic therapies.109

Radiosensitizing properties were first reported for angiostatin when Weichselbaum and colleagues demonstrated that the combination of angiostatin and radiation was synergistic and decreased radioresistance.112 These results have also been confirmed for antiangiogenic small-molecule tyrosine kinase inhibitors.113 Additionally, endostatin showed additivity with radiation regarding tumor regression, growth inhibition, angiogenesis, and enhanced apoptosis.114 These mechanisms could be caused by enhancement of tumor oxygenation, leading to increased radiosensitivity, as well as direct tumor growth delay.110, 112

Novel targeted therapies with radiosensitizing properties

Receptor tyrosine kinases other than EGFR are also potential targets for novel radiosensitizers. Overexpression of c-Met has been linked to poor prognosis in many cancers,115 and synergism with radiation has been described in glioblastoma cell lines.116 Other receptor tyrosine kinases such as insulin-like growth factor receptor or ephrin receptors are additional candidates. Another innovative strategy that has been tested in phase I clinical trials is radiation-induced activation of gene transcription. For example, TNFerade™ (GenVec, Gaithersburg, MD) is a replication-deficient adenovirus vector with an early growth response protein 1 (EGR1) radiation-inducible promoter leading to intratumoral human tumor necrosis factor production. Initial applications of this agent in esophageal, rectal, and pancreatic cancer, as well as in sarcomas, have shown proof of principal, with extensive tumor necrosis as a sign of activity.117 Additional studies in head and neck cancer are ongoing.

With the increasing understanding of cancer biology, hundreds of novel targeted agents are scheduled to come into preclinical and clinical development in the next decade. Among these agents proteasome inhibitors, and agents that target mammalian target of rapamycin, have shown promising results when combined with radiotherapy.118, 119 For further information on the interaction of targeted agents with radiation, readers are referred to the excellent review by Ma and coauthors.99

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Conclusion

In summary, concurrent chemoradiotherapy is a highly efficacious locoregional treatment option for solid tumors, which can be used alone or combined with surgery or induction/consolidation chemotherapy. Through our increased understanding of the molecular basis of chemotherapy and radiation interactions, we have gained insights into how to best use and potentially combine agents with radiation, with benefits beginning to be seen in patients. Novel targeted therapies and agents specific for hypoxic or radiated cells hold promise for further significant improvement of therapeutic ratios. Concurrent chemoradiotherapy already offers excellent locoregional control with an acceptable toxicity profile for the treatment of many locoregional advanced tumors. In the final article of this two-article series we will examine—using the example of head and neck cancer—specific concurrent chemoradiotherapy treatment options and the underlying clinical evidence. Head and neck cancer is often a locoregionally confined disease, and this is exemplified by the profound impact and benefit that concurrent chemoradiotherapy can have for patients.

Key points

  • Concurrent chemoradiotherapy has improved cancer care during the past two decades in multiple diseases, and can be used in the neoadjuvant, primary (definitive), or adjuvant setting
  • Chemotherapy or targeted agents can increase the efficacy of radiation
  • Radiosensitizing effects (interaction within the radiation field) can be additive or supra-additive
  • Multiple mechanisms underlie radiosensitizing properties of chemotherapeutic agents and include increased radiation damage, inhibition of DNA repair, cell-cycle synchronization, increased cytotoxicity against hypoxic cells, inhibition of prosurvival pathways, and abrogation of rapid tumor cell repopulation
  • Radioresistance occurs through multiple mechanisms, such as a large tumor burden, hypoxia, rapid tumor cell repopulation, as well as the constitutive or acquired activation of radioresistance signaling pathways
  • In addition to the classic chemotherapeutic agents with radiosensitizing properties (i.e. cisplatin and paclitaxel), several novel agents show promising interactions with radiation (e.g. EGFR inhibitors, pemetrexed, tirapazamine, and potentially several other targeted therapies)

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Acknowledgments

The authors would like to acknowledge the generous help of Dr Blase Polite and Dr Samir Undevia in reviewing organ-specific data.

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References

  1. Steel GG and Peckham MJ (1979) Exploitable mechanisms in combined radiotherapy-chemotherapy: the concept of additivity. Int J Radiat Oncol Biol Phys 5: 85–91 | PubMed | ISI | ChemPort |
  2. Brizel DM et al. (2000) Phase III randomized trial of amifostine as a radioprotector in head and neck cancer. J Clin Oncol 18: 3339–3345 | PubMed | ISI | ChemPort |
  3. Buentzel J et al. (2006) Intravenous amifostine during chemoradiotherapy for head-and-neck cancer: a randomized placebo-controlled phase III study. Int J Radiat Oncol Biol Phys 64: 684–691 | Article | PubMed | ChemPort |
  4. Komaki R et al. (2004) Effects of amifostine on acute toxicity from concurrent chemotherapy and radiotherapy for inoperable non-small-cell lung cancer: report of a randomized comparative trial. Int J Radiat Oncol Biol Phys 58: 1369–1377 | Article | PubMed | ChemPort |
  5. Malik R et al. (2005) Meta-analysis of the effect of amifostine on response rates in advanced non-small cell lung cancer patients treated on randomized trials. Int J Radiat Oncol Biol Phys 63 (Suppl 1): S117 | Article |
  6. Sasse AD et al. (2006) Amifostine reduces side effects and improves complete response rate during radiotherapy: results of a meta-analysis. Int J Radiat Oncol Biol Phys 64: 784–791 | Article | PubMed | ISI | ChemPort |
  7. Grdina DJ et al. (2002) Radioprotectants: current status and new directions. Oncology 63 (Suppl 2): S2–S10 | Article |
  8. Stiff PJ et al. (2006) Palifermin reduces patient-reported mouth and throat soreness and improves patient functioning in the hematopoietic stem-cell transplantation setting. J Clin Oncol [doi: doi: 10.1200/JCO.2005.02.8340] | Article | PubMed | ISI | ChemPort |
  9. Rosen LS et al. (2006) Palifermin reduces the incidence of oral mucositis in patients with metastatic colorectal cancer treated with fluorouracil-based chemotherapy. J Clin Oncol 24: 5194–5200 | Article | PubMed | ChemPort |
  10. Giocanti N et al. (1993) DNA repair and cell cycle interactions in radiation sensitization by the topoisomerase II poison etoposide. Cancer Res 53: 2105–2111 | PubMed | ChemPort |
  11. Hennequin C and Favaudon V (2002) Biological basis for chemo-radiotherapy interactions. Eur J Cancer 38: 223–230 | Article | PubMed | ISI | ChemPort |
  12. Chou TC and Talalay P (1984) Quantitative analysis of dose-effect relationships: the combined effects of multiple drugs or enzyme inhibitors. Adv Enzyme Regul 22: 27–55 | Article | PubMed | ISI | ChemPort |
  13. Reynolds CP and Maurer BJ (2005) Evaluating response to antineoplastic drug combinations in tissue culture models. Methods Mol Med 110: 173–183 | PubMed | ChemPort |
  14. Teicher BA (2003) Assays for in vitro and in vivo synergy. Methods Mol Med 85: 297–321 | PubMed | ChemPort |
  15. White DB et al. (2003) A new nonlinear mixture response surface paradigm for the study of synergism: a three drug example. Curr Drug Metab 4: 399–409 | Article | PubMed | ChemPort |
  16. Coleman CN (1988) Hypoxia in tumors: a paradigm for the approach to biochemical and physiologic heterogeneity. J Natl Cancer Inst 80: 310–317 | Article | PubMed | ChemPort |
  17. Gray LH et al. (1953) The concentration of oxygen dissolved in tissues at the time of irradiation as a factor in radiotherapy. Br J Radiol 26: 638–648 | PubMed | ISI | ChemPort |
  18. Kumar P (2000) Tumor hypoxia and anemia: impact on the efficacy of radiation therapy. Semin Hematol 37: 4–8 | Article | PubMed | ChemPort |
  19. Overgaard J et al. (1989) Misonidazole combined with split-course radiotherapy in the treatment of invasive carcinoma of larynx and pharynx: report from the DAHANCA 2 study. Int J Radiat Oncol Biol Phys 16: 1065–1068 | PubMed | ChemPort |
  20. Moulder JE and Rockwell S (1984) Hypoxic fractions of solid tumors: experimental techniques, methods of analysis, and a survey of existing data. Int J Radiat Oncol Biol Phys 10: 695–712 | PubMed | ISI | ChemPort |
  21. Terasima T and Tolmach LJ (1963) X-ray sensitivity and DNA synthesis in synchronous populations of HeLa cells. Science 140: 490–492 | Article | PubMed | ISI | ChemPort |
  22. Fowler JF and Lindstrom MJ (1992) Loss of local control with prolongation in radiotherapy. Int J Radiat Oncol Biol Phys 23: 457–467 | PubMed | ISI | ChemPort |
  23. Trott KR and Kummermehr J (1985) What is known about tumour proliferation rates to choose between accelerated fractionation or hyperfractionation? Radiother Oncol 3: 1–9 | PubMed | ChemPort |
  24. Krause M et al. (2005) Decreased repopulation as well as increased reoxygenation contribute to the improvement in local control after targeting of the EGFR by C225 during fractionated irradiation. Radiother Oncol 76: 162–167 | Article | PubMed | ChemPort |
  25. Grillo-Ruggieri F and Mantello G (2004) Is one Gy equal to one Gy after treatment interruptions? Rays 29: 275–278 | PubMed |
  26. Schmidt-Ullrich RK et al. (1999) Molecular mechanisms of radiation-induced accelerated repopulation. Radiat Oncol Investig 7: 321–330 | Article | PubMed | ISI | ChemPort |
  27. West CM et al. (1997) The independence of intrinsic radiosensitivity as a prognostic factor for patient response to radiotherapy of carcinoma of the cervix. Br J Cancer 76: 1184–1190 | PubMed | ISI | ChemPort |
  28. Deacon J et al. (1984) The radioresponsiveness of human tumours and the initial slope of the cell survival curve. Radiother Oncol 2: 317–323 | Article | PubMed | ISI | ChemPort |
  29. Dey S et al. (2003) Low-dose fractionated radiation potentiates the effects of paclitaxel in wild-type and mutant p53 head and neck tumor cell lines. Clin Cancer Res 9: 1557–1565 | PubMed | ISI | ChemPort |
  30. Nix PA et al. (2004) Radioresistant laryngeal cancer: beyond the TNM stage. Clin Otolaryngol Allied Sci 29: 105–114 | PubMed | ChemPort |
  31. Smith BD and Haffty BG (1999) Molecular markers as prognostic factors for local recurrence and radioresistance in head and neck squamous cell carcinoma. Radiat Oncol Investig 7: 125–144 | Article | PubMed | ChemPort |
  32. Aebersold DM et al. (2001) Involvement of the hepatocyte growth factor/scatter factor receptor c-met and of Bcl-xL in the resistance of oropharyngeal cancer to ionizing radiation. Int J Cancer 96: 41–54 | Article | PubMed | ChemPort |
  33. Uchida D et al. (2001) Role of HGF/c-met system in invasion and metastasis of oral squamous cell carcinoma cells in vitro and its clinical significance. Int J Cancer 93: 489–496 | Article | PubMed | ISI | ChemPort |
  34. Khodarev NN et al. (2004) STAT1 is overexpressed in tumors selected for radioresistance and confers protection from radiation in transduced sensitive cells. Proc Natl Acad Sci USA 101: 1714–1719 | Article | PubMed | ChemPort |
  35. Bennett CB et al. (1993) Lethality induced by a single site-specific double-strand break in a dispensable yeast plasmid. Proc Natl Acad Sci USA 15: 13–17
  36. Ward JF (1998) Nature of lesions formed by ionising radiation. In DNA damage and repair: DNA repair in higher eukaryotes, 65–84 (Eds Nickoloff JA and Hoekstra MF). Totowa, NJ: Humana Press
  37. Begg AC (1990) Cisplatin and radiation: interaction probabilities and therapeutic possibilities. Int J Radiat Oncol Biol Phys 19: 1183–1189 | PubMed | ChemPort |
  38. Yang LX et al. (1995) Production of DNA double-strand breaks by interactions between carboplatin and radiation: a potential mechanism for radiopotentiation. Radiat Res 143: 309–315 | Article | PubMed | ChemPort |
  39. Sinclair WK and Morton RA (1966) X-ray sensitivity during the cell generation cycle of cultured Chinese hamster cells. Radiat Res 29: 450–474 | Article | PubMed | ISI | ChemPort |
  40. Terasima T and Tolmach LJ (1961) Changes in x-ray sensitivity of HeLa cells during the division cycle. Nature 190: 1210–1211 | Article | PubMed | ISI | ChemPort |
  41. Wilson GD et al. (2006) Biologic basis for combining drugs with radiation. Semin Radiat Oncol 16: 2–9 | Article | PubMed |
  42. Hei TK et al. (1994) Taxol and ionizing radiation: interaction and mechanisms. Int J Radiat Oncol Biol Phys 29: 267–271 | PubMed | ChemPort |
  43. Stromberg JS et al. (1995) Lack of radiosensitization after paclitaxel treatment of three human carcinoma cell lines. Cancer 75: 2262–2268 | Article | PubMed | ChemPort |
  44. Vaupel P (2004) Tumor microenvironmental physiology and its implications for radiation oncology. Semin Radiat Oncol 14: 198–206 | Article | PubMed |
  45. Semenza GL (2003) Targeting HIF-1 for cancer therapy. Nat Rev Cancer 3: 721–732 | Article | PubMed | ISI | ChemPort |
  46. Milas L et al. (1995) Tumor reoxygenation as a mechanism of taxol-induced enhancement of tumor radioresponse. Acta Oncol 34: 409–412 | Article | PubMed | ChemPort |
  47. Kim JJ and Tannock IF (2005) Repopulation of cancer cells during therapy: an important cause of treatment failure. Nat Rev Cancer 5: 516–525 | Article | PubMed | ISI | ChemPort |
  48. Liang K et al. (2003) The epidermal growth factor receptor mediates radioresistance. Int J Radiat Oncol Biol Phys 57: 246–254 | Article | PubMed | ChemPort |
  49. Bonner JA et al. (2006) Radiotherapy plus cetuximab for squamous-cell carcinoma of the head and neck. N Engl J Med 354: 567–578 | Article | PubMed | ISI | ChemPort |
  50. Spring PM et al. (2004) Low dose fractionated radiation potentiates the effects of taxotere in nude mice xenografts of squamous cell carcinoma of head and neck. Cell Cycle 3: 479–485 | PubMed | ChemPort |
  51. Vokes EE and Weichselbaum RR (1990) Concomitant chemoradiotherapy: rationale and clinical experience in patients with solid tumors. J Clin Oncol 8: 911–934 | PubMed |