Actual practice of Kochi oxydol radiation therapy for unresectable carcinomas by intra-tumoral administration of hydrogen peroxide as a radiosensitizer.

Kochi oxydol radiation therapy for unresectable carcinomas (KORTUC) is a novel cancer treatment method developed in Japan. KORTUC targets resistance factors in cancer therapy, such as low-oxygen environments and excessive antioxidant enzymes. This may enhance the effects of conventional treatments. The present study reports the experience of the Nagasaki Prefecture Shimabara Hospital in using KORTUC treatment for a series of 210 patients between January 2010 and June 2019. When this radiosensitizer, a mixture of a dilute hydrogen peroxide solution (0.5 ml, 3%/unit) and sodium hyaluronate (2.5 ml, 0.83%/unit), is administered and applied directly to the cancer lesion, antioxidant enzymes are neutralized and degraded causing reoxygenation as a secondary by-product, thereby enhancing the cytotoxic effect of radiation. The radiosensitizer was administered twice per week before irradiation. Up to June 2019, KORTUC was administered to 210 patients. The most common disease stage was stage IV in 137 patients (65%), followed by stage III in 25 patients, stage I in 17 patients and stage II in 7 patients (unknown disease stage in 24 patients). Of the 186 patients who could be followed up after the treatment, 28 (15%) patients had a complete response (Response Evaluation Criteria in Solid Tumors version 1.1), 59 (32%) had a partial response, 73 (39%) had stable disease and 26 (14%) had progressive disease. No significant treatment-related adverse events were observed. The present study highlights the reports of 4 cases (3 cases from among the 28 patients with complete responses): i) A case of advanced, inoperable breast cancer; ii) a refractory patient with recurrence a decade after postoperative irradiation; iii) a patient with advanced, inoperable rectal cancer; and iv) a patient with lymph node metastases. Overall, KORTUC showed good efficacy and tolerable safety for various types of radioresistant tumors, and it has the potential for immediate worldwide use. Copyright: © Obata et al.

Introduction

Kochi oxydol radiation therapy for unresectable carcinomas (KORTUC) is a novel cancer treatment method developed in Japan (1). Although low-oxygen environments and excessive antioxidant enzymes are known to promote resistance to cancer therapy, elimination of these factors is difficult and has been rarely reported. If these treatment resistance factors can be removed, it is expected that the effects of conventional therapies, such as radiation therapy and chemotherapy, will be enhanced. Tumor cells are resistant to X-ray irradiation due to their high peroxidase and catalase activities. Therefore, by providing exogenous hydrogen peroxide before irradiation, the activities of anti-oxidative enzymes can be blocked and oxygen molecules can be produced simultaneously, leading to oxidative damage to low-linear energy transfer (LET) radioresistant tumor cells. Through this mechanism, low-LET radioresistant tumor cells can be converted into highly radiosensitive cells (1-5) (Figs. 1 and 2). KORTUC was designed to accomplish this goal.

Figure 1

Method of Kochi oxydol radiation therapy for unresectable carcinomas, modified from Figure 4 published in reference (1).

Figure 2

Molecular mechanism of Kochi oxydol radiation therapy for unresectable carcinomas. Permission was obtained for reuse of this image (5). LET, low-linear energy transfer.

When a mixture of a dilute hydrogen peroxide solution and sodium hyaluronate is administered directly to a cancer lesion, antioxidant enzymes are neutralized and degraded, resulting in increased intratumor oxygen tension, thereby enhancing the cytotoxic effect of radiation (1,6).

To date, a Japanese clinical study of KORTUC in patients with breast cancer who refused surgery (6) and a phase I study of KORTUC in patients with locally advanced breast cancer in the United Kingdom (7) have been conducted, both of which demonstrated safety and showed indications of marked treatment effects.

The present study summarizes the outcomes of KORTUC therapy for a case series of 210 patients and provides the case reports of 4 patients who failed standard treatment and were successfully treated with KORTUC, including a case of advanced, inoperable breast cancer, a refractory patient with recurrence a decade after postoperative irradiation, a patient with advanced, inoperable rectal cancer and a patient with lymph node metastases.

Materials and methods

Target patients

In the hope that KORTUC would enhance the effects of existing treatments, from January 2010, following approval of the Nagasaki Prefecture Shimabara Hospital Ethics Committee (Shimabara, Japan; approval no. 21SH103 from January 14, 2010), Nagasaki Prefecture Shimabara Hospital included the following patients with difficult-to-control tumors as patients eligible for KORTUC: i) Patients resistant to radiotherapy; ii) patients with repeated recurrences; and iii) patients resistant to standard therapy. In September 2014, after confirmation of its efficacy and safety in 62 patients, the following further patient groups were added with approval from the Ethics Committee (additional approval no. 26SH185 from September 4, 2014): iv) Patients who refused surgery and v) patients requiring multidisciplinary therapy. The present study targets solid tumors of all cancer types in which a sensitizer can be administered intratumorally. Considering the desire of each patient for KORTUC and the need for the treatment, all patients provided written informed consent before being included in the study. The study was conducted following the Declaration of Helsinki of the World Medical Association.

Treatment method

The radiosensitizer consisted of 1 unit (0.5 ml) of a 3% hydrogen peroxide solution mixed with 2.5 ml of 0.83% sodium hyaluronate, resulting in a 0.5% hydrogen peroxide concentration. The actual injected dose was determined so that a reaction would occur as evenly as possible over the entire lesion. For example, for a lesion of 1 cm in diameter, the injected dose of the mixture was ~1 ml, and for a lesion 3 cm in diameter, the injected dose of the mixture was ~3 ml.

The addition of sodium hyaluronate stabilized the hydrogen peroxide and resulted in elevated intratumor oxygen tension even 48 h after injection (8). Thus, the radiosensitizer was administered twice per week. To maximize its sensitizing effect, the radiosensitizer was injected intratumorally immediately prior to radiation whenever possible; for example, on Monday and Wednesday or on Tuesday and Thursday, depending upon the radiation schedule (this injected form of KORTUC is known as KORTUC II). For a lesion located on the skin surface, the radiosensitizer was sprayed over the lesion, or a gauze pad soaked in the radiosensitizer was applied to the lesion just before radiation (this form of KORTUC is known as KORTUC I). For a deep-seated lesion, the radiosensitizer was injected slowly into the tumor with an 18- to 26-G needle under ultrasound or computed tomography (CT) guidance to avoid an accidental puncture of adjacent vessels or organs. As KORTUC II is a novel treatment, there have been no data on the risk of tumor cell dissemination. For this reason, a needle with the smallest possible diameter, depending on the conditions, was selected based on reports suggesting that the dissemination risk was 0.04% [10/25,000 cases (unclarified cancer type) in a systematic review of data up until the end of 1976] for a lung biopsy (9) under CT guidance and that a smaller puncture needle was associated with less frequent dissemination (10). The needle used most frequently was a 22-G spinal needle that was readily visible under imaging guidance and relatively flexible and hard to break. If a patient complained of severe pain, 1 ml of 1% lidocaine was mixed with 1 unit of the radiosensitizer after confirming that the patient had no Xylocaine allergy.

Treatment responses were assessed according to the Response Evaluation Criteria In Solid Tumors (RECIST), version 1.1(11). RECIST is a standard way to measure how well a patient with cancer responds to treatment; it is based on whether tumors shrink, stay the same size or increase in size. To use RECIST, there must be at least one tumor that can be measured on X-ray, CT or magnetic resonance imaging scans. The types of response a patient can have are a complete response (CR), a partial response (PR), progressive disease (PD) and stable disease (SD).

The survival period was calculated using the Kaplan-Meier method from the planned radiation therapy date to the date of death due to all causes or the date of the final follow-up of surviving patients (up to June 2019).

Adverse events were assessed according to the Common Terminology Criteria for Adverse Events (CTCAE), version 4(12). CTCAE is widely accepted as the standard classification and severity grading scale for adverse events in cancer therapy, clinical trials, and other oncology settings.

Results

Treatment results

Between January 2010 and June 2019, KORTUC was administered to 210 patients. Table I shows the responses of the patients according to cancer type and stage. The most common disease stage was stage IV in 137 patients (65%), followed by stage III in 25 patients, stage I in 17 patients and stage II in 7 patients (unknown disease stage in 24 patients). As most patients were in stage IV and radiotherapy was a local treatment, their post-treatment evaluation was assessed based on local effects and not on overall survival (OS) or disease-free survival. Of the 186 patients who could be followed up after the treatment, according to RECIST version 1.1, 28 (15%) patients had a CR, 59 (32%) had a PR, 73 (39%) had SD and 26 (14%) had PD. In addition, the median survival time of all 28 CR patients was 30 months (range, 2-96 months), and the 2-, 3-, and 5-year OS rates were 83.1, 76.2 and 66.7%, respectively. Table II shows the adverse events associated with KORTUC, which were assessed according to CTCAE version 4, and included the following: Radiation dermatitis, grade III in 6 patients and grade II in 76 patients; leukopenia, grade III in 2 patients (receiving concurrent chemotherapy); postoperative recurrence of perforation at the intestinal anastomotic site, grade IV in 1 patient; oral mucositis, grade III in 2 patients; radiation esophagitis, grade II in 22 patients; radiation enteritis, grade II in 3 patients; and pain during injection of the radiosensitizer, grade I in 20 patients.

Table I

Results of Kochi oxydol radiation therapy for unresectable carcinomas performed in Nagasaki Prefecture Shimabara Hospital.

			Clinical response[a] of patients at different diagnostic stages, n
			Stage I (n=17)				Stage II (n=7)				Stage III (n=25)				Stage IV (n=137)				Responders, n
Cancer type	Total treated, n	UD, n	CR	PR	SD	PD	CR	PR	SD	PD	CR	PR	SD	PD	CR	PR	SD	PD	CR+PR
Breast	49	8	8	1										1	5	11	11	4	25
Lung	46	2		1	1	1			1			1	3		5	12	17	2	19
Colon/rectum	36				1					1	1	2	1	2	2	6	17	3	11
Esophagus	29	3		2			1	1			2	5	1	1		5	5	3	16
Bone and soft tissue	11	4		1			1									2	2	1	4
Urinary system	8	2		1							1		2			2			4
Pancreas	7													1			4	2	0
Stomach	5	1															1	3	0
Head and neck	3	1													1			1	1
Lymphoma	6	1						1								3	1		4
Biliary system	4	1														1	2		1
Pleura	1																1		0
Ovary	1																1		1
Liver	2							1									1		0
Unknown primary	2	1									1								1
Total	210	24	8	6	2	1	2	3	1	1	5	8	7	5	13	42	63	19	87

aResponse Evaluation Criteria In Solid Tumors. CR, complete response; PR, partial response; SD, stable disease; PR, progressive disease. UD, undetermined (patient could not be followed due to transfer to another hospital).

Table II

Adverse events following Kochi oxydol radiation therapy for unresectable carcinomas according to Common Terminology Criteria for Adverse Events version 4 (n=210).

Adverse Events	Severity (Grade)	Number of cases
Radiation dermatitis	II	76
	III	6
Radiation esophagitis	II	22
Pain during injection of the radiosensitizer	I	20
Radiation enteritis	II	3
Leukopenia (receiving concurrent chemotherapy)	III	2
Oral mucositis	III	2
Postoperative recurrence of perforation at the intestinal anastomotic site	IV	1

Representative case reports

The following are case reports of 4 patients who had failed conventional therapy but maintained a CR following KORTUC.

Case 1: Advanced and inoperable breast cancer

A woman in her 50s noticed a lump in the right breast, which was left untreated. The patient presented to a local doctor 1 year later with gradually worsening shortness of breath and lower extremity edema accompanied by anemia, and was diagnosed with stage IV breast cancer [invasive ductal carcinoma, papillotubular to scirrhous carcinoma; lymph node, liver and lung metastases; immunohistochemical examination (IH) result: ER(3+), PgR(+) and HER2(3+)]. The patient responded inadequately to seven courses of 840 mg pertuzumab/420 mg trastuzumab/100 mg docetaxel, seven courses of 200 mg trastuzumab emtansine, 330 mg trastuzumab/1,800 mg gemcitabine and fulvestrant for ~3 years. The primary lesion gradually grew into a giant lesion, 15 cm along its major axis, and was elevated enough to break through the skin. The tumor was hemorrhagic, had white exudate on its surface and had an unusually offensive odor. The breast cancer was resistant to treatment, and an experienced radiation oncologist in the same hospital was consulted about administering radiation therapy to the patient. It was considered that radiotherapeutic efficacy against the tumor progression could not be expected either. The patient was then referred to Nagasaki Prefecture Shimabara Hospital for KORTUC in August 2019 at the age of 56. Standard therapy had previously been used, but no treatment resistance factors had been identified. Therefore, it was considered that previous treatments had not been used effectively.

The patient now received intensity modulated radiation therapy (IMRT) with 44 Gy in 16 fractions for 3 weeks to the breast and the regional lymph nodes, followed by boosts of 9 Gy in three fractions to the primary lesion and involved ipsilateral lymph nodes. In addition, twice weekly, the patient received radiosensitizer injected into the breast cancer and multiple regional metastatic lymph nodes within the irradiation field. Furthermore, a hydrogen peroxide solution was sprayed on the surface of the tumor (KORTUC I & II) (Fig. 3).

Figure 3

Case 1: Treatment flow of a patient with advanced and inoperable breast cancer. RT, radiation therapy (44 Gy in 16 fractions for 3 weeks and boosts of 9 Gy in 3 fractions for a week); RSI, radiosensitizer injection (into the primary and metastatic lymph nodes with ultrasonographic guidance); RSS, radiosensitizer spray (on the surface of the primary lesion); PER, pertuzumab; HER, trastuzumab; DOC, docetaxel; T-DM1, trastuzumab emtansine; GEM, gemcitabine.

No serious adverse events were observed. At 4 months after KORTUC, the large mass and swollen lymph nodes within the radiation field regressed. A concavity was present on the right chest wall where the lesion had been present, but the size of the concavity reduced over time (Fig. 4). After 14 months, the patient succumbed to cancer, but no regrowth of the right chest wall lesion was observed (however, it should be noted that this case is not included in the aforementioned data due to the collection period).

Figure 4

Images of the breast in case 1 prior to and at 4 months post-Kochi oxydol radiation therapy for unresectable carcinomas for treatment-resistant right-sided advanced breast cancer.

Case 2: A refractory patient with recurrence a decade after postoperative irradiation

A woman in her 40s noticed a lump in the left breast and underwent breast conserving surgery and axillary lymph node dissection for left breast cancer [invasive ductal carcinoma; n(+); IH: ER(+), PgR(+), HER2(2+); FISH unknown], and radiotherapy with 50 Gy in 25 fractions, at the Nagasaki Prefecture Shimabara Hospital. This was followed by adjuvant chemotherapy and endocrine therapy with tegafur/uracil and Nolvadex for the remaining breast tissue post-surgery. The patient voluntarily stopped visiting the Outpatient Department after 5 years. At 10 years after the first visit, irregular erosions and an ulcer, 10 cm long along its major axis and surrounded by multiple red nodules, developed in the remaining breast (Fig. 5). Metastasis was confirmed by skin biopsy [IH: ER(+), PgR(-), HER2(3+); Ki-67 34%]. Femara was administered and then substituted with 1 mg anastrozole per day, and 16 courses of trastuzumab therapy were administered, once every 3 weeks (first course of 342 mg and then 252 mg). Despite these treatments, the disease worsened, and KORTUC with irradiation of 45 Gy in 25 fractions was performed only at the site of recurrence in February 2015 at the age of 53.

Figure 5

Case 2: Images of the breast showing scar tissue in place of left breast cancer recurrence at 38 months after salvage Kochi oxydol radiation therapy for unresectable carcinomas.

Acute-phase grade III dermatitis was observed. The local lesion disappeared, with no serious adverse events after 6 years. During that time, bone metastasis and lung metastasis were observed, and adjuvant chemotherapy in the form of nine courses of 840 mg pertuzumab/252 mg trastuzumab and 152 mg trastuzumab emtansine (once every 3 weeks), and 4 mg zoledronic acid hydrate (once every 4 weeks) was administered. A solitary small cerebellar metastasis was treated with stereotactic brain irradiation. The re-irradiated left chest wall lesion showed partial ulcer formation 4.5 years after KORTUC, and was accompanied by secondary infection. Cytology was class III, but has since improved.

It has been reported that ~10% of patients have local recurrence after standard treatment (13), suggesting that re-irradiated KORTUC may become an important salvage therapy for patients with recurrent disease.

Case 3: Advanced and inoperable rectal cancer

A 57-year-old female who visited the Emergency Outpatient Department of Nagasaki Prefecture Shimabara Hospital for left abdominal pain, appetite loss and nausea was diagnosed with rectal cancer at stage IVA, T4bN2aM1a, as a result of an inpatient examination in August 2015. The Eastern Cooperative Oncology Group performance status (PS) (14) was 3. The patient was confined to bed, with decreased appetite, severe anemia (hemoglobin: 6.5 g/dl; normal range, 11.6-14.8 g/dl), and weight loss of 10 kg over half a year. The patient had a type 2 tumor (moderately differentiated adenocarcinoma), which bleed regularly and was covered with white exudate, invading the total circumference of the lower rectum and extending to the perineum beyond the anal canal (Fig. 6). A CT scan revealed a partially unclear border with the uterus, suggestive of infiltration, and multiple perirectal, left internal iliac, left obturator, left external iliac and left inguinal lymph nodes of various sizes up to 2 cm, strongly suggestive of lymph node involvement (Fig. 6). Based on these findings, the patient was informed that they had an inoperable cancer and a life expectancy of 2 weeks to 1 month, and it was recommended that best supportive care should be administered for symptomatic relief, instead of aggressive curative treatment. The patient was also reluctant to undergo curative therapy. However, the patient's family could not understand the sudden declaration of terminal cancer and consulted a gastroenterologist. This doctor also recommended palliative care, as chemotherapy could further shorten the lifespan of the patient. The family was still not satisfied with this recommendation and was eventually referred to the Department of Radiology and Radiotherapy, Nagasaki Prefecture Shimabara Hospital. Based on a discussion with the patient and their family, the patient was scheduled to receive KORTUC in combination with chemotherapy instead of standard treatment.

Figure 6

Case 3: Images and computed tomography scan of an inoperable case of advanced rectal cancer, stage IVA, modified from Figure 3 published in our previous study (15), with the consent of Jpn J Clin Radiol.

The patient underwent IMRT with 50.4 Gy in 30 fractions for 6 weeks to the primary lesion and regional lymph nodes, in the prone position using a belly board device. This was combined with twice-weekly injections and spray of the radiosensitizer on/into the perineal lesion, and use of both methods on/into the rectal lesion with endoscopic guidance. Two courses of modified FOLFOX6 at reduced doses (90% doses; 241 mg leucovorin and 103 mg oxaliplatin over 2 h of continuous intravenous infusion, respectively; 482 mg fluorouracil intravenously by slow bolus over 5 min, and 2,894 mg fluorouracil over 46 h of continuous intravenous infusion) were administered concomitantly with radiation therapy. In addition, immediately before treatment initiation, a central venous port was placed, and intravenous hyperalimentation was initiated to improve the poor general condition of the patient, to reduce adverse events and to increase the therapeutic effect. A colostomy was placed proximally to the descending colon to prepare for the development of ileus secondary to transient swelling caused by irradiation of the lower rectum.

At 9 months post-KORTUC, the rectal lesion had disappeared completely and an endoscopic rectal biopsy revealed no malignancy. The tumor extending to the perineum had disappeared. The perineal dermatitis was mild, possibly due to the low dose administered, and no serious adverse events were observed. The multiple lymph node metastases located on the left side of the pelvis had also regressed and could not be identified (Fig. 7). These included metastatic lymph nodes within the radiation field that had not been injected with the radiosensitizer.

Figure 7

Images and computed tomography scan of case 3 at 9 months after Kochi oxydol radiation therapy for unresectable carcinomas and mFOLFOX6, modified from Figure 5 published in our previous study (15), with the consent of Jpn J Clin Radiol.

This phenomenon has also been observed in other patients undergoing KORTUC. A possible explanation is that, due to its low molecular weight, the radiosensitizer injected into the primary lesion flows via the lymphatic drainage into the regional metastatic lymph nodes, similar to the way a dye or radioisotope is injected for sentinel lymph node identification in breast cancer, thereby sensitizing even lymph nodes that have not been injected. We named this phenomenon the ‘sentinel effect’ of KORTUC, as it is like the method of sentinel lymph node identification in breast cancer (15).

Elevated pre-treatment levels of carcinoembryonic antigen (264.5 ng/ml; normal range, 0-5 ng/ml) and carbohydrate antigen 19-9 (117 U/ml; normal range, 0-37 U/ml) returned to normal rapidly after KORTUC. Subsequently, the patient received adjuvant chemotherapy, 11 courses of mFOLFOX6 once every 3 weeks, and changing to 2nd line therapy (FOLFIRI, 90% dose; 300 mg levofolinate calcium and 230 mg irinotecan hydrochloride hydrate over 2 h of continuous intravenous infusion, respectively; 600 mg fluorouracil intravenously by slow bolus over 5 min, and 3,600 mg fluorouracil over 46 h of continuous intravenous infusion), periodically for 4.5 years until the appearance of adverse events in the form of skin ulcers. The patient achieved and has continued to achieve a CR, with normal weight and general overall condition for 6 years now without adjuvant cancer therapy. Currently, the patient is followed up once a month by the referral gastroenterologist.

Case 4: A huge lymph node metastasis

A 69-year-old male presented with advanced non-small cell lung cancer (NSCLC; RLL, adenocarcinoma, cT1bN3M1c, stage IVB; PS: 2) in September 2017. A left neck lesion appeared 1.5 months previously and increased in size rapidly to 12 cm along its major axis (Fig. 8). Due to the lesion, the patient complained of neck pain and numbness of the left upper extremity. The patient could not rotate their neck or elevate the ipsilateral upper arm, and developed Horner's syndrome. At first, the primary lesion was unknown; however, as a result of subsequent pathological findings, which suggested adenocarcinoma of the lung, and finding of a small nodule in the right lower lung on whole-body CT, this was considered to be the primary lesion. The tumor was consistent with lymph node metastasis and involved surrounding blood vessels, so was considered difficult to surgically resect. Radiation therapy could also have caused the rupture and collapse of blood vessels, and sudden changes. However, if left untreated, the tumor was expected to grow more rapidly and invade the surrounding tissues and blood vessels more widely, breaking through the skin, causing secondary infections and fatal bleeding. Impaired quality of life could then result through severe pain and motor dysfunction progression, followed by sudden death. Therefore, the patient was referred from the Department of Respiratory Medicine, Nagasaki Prefecture Shimabara Hospital, for palliative radiotherapy. It was decided that the patient should be treated using IMRT, with 40 Gy in 16 fractions for 3 weeks to the entire left neck lymph node lesion, followed by boosts of 9 Gy in three fractions to the shrinking lesion, in combination with twice-weekly injection of the radiosensitizer under ultrasound guidance, and 60 mg oral S-1 twice a day for 3 weeks, withdrawn for 2 weeks.

Figure 8

Case 4: Images and computed tomography scan (coronal image of dose distribution) of bulky lymph node metastases from non-small cell lung cancer prior to and at 8 months post-Kochi oxydol radiation therapy for unresectable carcinomas.

At 8 months after KORTUC initiation, the lesion disappeared, and concomitant conditions such as neck pain, motor dysfunction and Horner's syndrome subsided. Subsequently, the patient received adjuvant chemotherapy at the aforementioned dose periodically for 2 years, and no tumor regrowth was present before the patient succumbed to aspiration pneumonia.

Original abilities of radiation therapy

The adaptive size of lesions in stereotactic irradiation, which aims to have a therapeutic effect on cancer using large doses, is generally ≤5 cm, and it is difficult to expect a curative effect on lesions of larger sizes. The combined use of the new sensitizer has shown a marked improvement in lesions with a size of ≥10 cm without increasing the total dose of radiation.

Discussion

Tailor-made treatments that have selective effects on certain types of cancer have become popular, such as KYMRIAH (tisagenlecleucel) (16). KORTUC, which broadly eliminates the source of cancer, appears to swim against such current trends, as it sensitizes radiotherapy, so can be considered effective for basically any type of cancer. However, KORTUC does not require many biopsied tissue samples to determine potential selective treatment effects and has favorable cost performance, as it does not require the reagents and tests that would be needed for treatments with limited indications. These advantages reduce the financial burden on patients and healthcare providers, state healthcare systems, and ultimately, taxpayers.

As the pursuit of tailor-made treatments, in other words, the diversity concerning malignant transformation, is thought to be the same as the pursuit of the infinite, potential adaptability of organisms, the development of tailor-made treatments should overcome the complexity of malignant transformation. It might be beneficial to reconsider the use of a single approach to treat the underlying cause of all cancer types.

KORTUC mainly exerts its effects through reoxygenation. After reoxygenation has been achieved, almost all molecular-targeted drugs would theoretically show the same local effects as those observed when the drug was administered to the tumor. Although it is known that an improved low-oxygen environment or reoxygenation enhances treatment effects, attempts to achieve reoxygenation have failed for a long period. In an attempt to apply this approach to clinical settings, however, attention was paid to the tumor growth, invasion and metastasis, as well as to the growth factors involved in the acquisition of metastatic potential, such as vascular endothelial growth factor (VEGF), epidermal growth factor (EGF) and other molecules, which underlie the influence of hypoxia (17). Based on the assumption that inhibiting the action of these factors may at least put a brake on cancer progression, molecular-targeted therapy has been developed. VEGF, EGF and other molecules, which are targets for molecular-targeted therapy, are produced in response to stimulation by hypoxia-inducible factor (HIF)-1α. However, HIF-1α is rapidly ubiquitinated and deactivated if the underlying low-oxygen environment is improved. KORTUC can increase oxygen tension in hypoxic intratumor environments and thus KORTUC therapy could theoretically result in a halt to further production of target factors such as VEGF and EGF for molecular-targeted drugs. This means that KORTUC could eradicate the target molecules of molecular-targeted therapy. KORTUC not only provides local treatment, but also reduces the risk of tumor growth and metastasis. In the future, molecular-targeted therapy may only need to be used in patients who already have distant metastasis (M1) or are at a high risk for distant metastasis.

The threat that reoxygenation poses to cancer cells also involves the cancer cell cycle and cancer stem cells. Cancer stem cells are also called dormant cells, a number of which show treatment resistance in the G0 phase (quiescent stage). Once the cancer stem cells switch from the quiescent stage to the proliferation stage, radiotherapy and chemotherapy could exert the same effects as those observed in normal cancer cells (18-21). Since oxygen concentration appears to be involved in the transition from the quiescent stage to the proliferation stage, reoxygenation would enable this transition. This means that KORTUC can activate cancer stem cells and reduce the risk of recurrence after treatment.

In healthy conditions, reactive oxygen species (ROS) harm the body, and the presence of antioxidant enzymes that neutralize ROS is therefore essential. However, once a carcinogenic state occurs, the role is reversed and ROS are needed to eliminate the cancer, but the ROS become ineffective if neutralized by antioxidant enzymes. To survive and protect itself from ROS attack, cancer utilizes this neutralization reaction and uses transcription factors, thereby excessively producing antioxidant enzymes (22,23). In the process of achieving reoxygenation, KORTUC neutralizes the excessive antioxidant enzymes that interfere with treatment; therefore, it may enhance the effects of radiotherapy and chemotherapy (24). However, unlike radiotherapy, which has high penetrability, chemotherapy requires an angioarchitecture that can deliver anticancer drugs to cancer. The resistance factors of both radiation therapy and anticancer drugs may overlap, and it cannot be denied that sensitizers affect both. Furthermore, it is undeniable that sensitizers were intentionally used in anticipation of the sensitizing effects of both radiation therapy and chemotherapy, especially in refractory patients. A number of good outcomes have been recorded that were not achieved with conventional chemoradiotherapy. A number of patients with terminal diagnoses have been cured using KORTUC, and this is a fact that cannot be overlooked, as it suggests that KORTUC may exceed the limits of current treatments. Based on the present results, it is strongly hoped that clinical trials will be conducted and data will be gained at other facilities worldwide, and that a therapeutic effect will be achieved in patients who are suffering from intractable cancer. Hypoxia and excessive antioxidant enzymes are among the main factors conferring resistance to both radiotherapy and chemotherapy. By neutralizing excessive antioxidant enzymes in cancer cells with hydrogen peroxide, which is a readily available ROS, antioxidant enzymes disappear, and oxygen occurs as the end product. By combining the end product with the remaining excessive ROS, irradiation of this state acts as a devastating attack against cancer. This is the core principle of KORTUC action (25-27).

A common question asked is whether the damage to the surrounding normal tissues is increased by KORTUC. When the oxygen partial pressure is >30 mmHg, the influence of irradiation reaches a plateau (28). ROS produces water and oxygen as end products. Therefore, excessive ROS (unreacted dilute hydrogen peroxide) is the only factor that may increase adverse events, and no obvious increase in the incidence of adverse events was recorded in the present study following the addition of KORTUC to the general treatment.

In conclusion, the KORTUC radiosensitization method showed good efficacy and tolerable safety for various types of radioresistant tumors, and it has the potential for immediate worldwide use.