Increasing evidence has indicated that ozone therapy is effective for treating numerous types of diseases featuring chronic pain, including osteoarthritis (1-4), neck and shoulder pain (5), lower back pain (6-9), myofascial pain syndrome (10), fibromyalgia (11), complex regional pain syndrome (12), zoster-associated pain (13,14) and other diseases, such as intractable headache and cardiovascular diseases (15,16). Medical ozone is administered in a flexible manner and may be applied externally or orally. It may also be administered locally or intravenously. Ozonated autohemotherapy (OAH) is widely used in the treatment of chronic pain (14,16,17). It has been reported that OAH alleviated pain of patients with post-herpetic neuralgia (14), intractable headache (16), as well as hyperuricemia and gout (17). Moderate concentrations of ozone (10 or 50 µg/ml) have been reported to increase deformability of red blood cells (18) and OAH is able to ameliorate renal ischemia-reperfusion injury in patients with kidney injury (19).

The specific mechanisms of action of ozone treatment in various diseases remain to be further studied. It is thought that the effects of ozone treatment are based on its strong oxidative and anti-pathogenic effects and immune regulation ability, as well as the increase of oxygen supply and reduction of oxidative stress (12,20-27). For instance, ozone was proven to relieve pain by causing the following effects: i) Release of endorphins (26); ii) inhibition of the activation of microglia via adenosine monophosphate (AMP)-dependent protein kinase signaling (28); iii) inhibition of the expression of purinergic receptors P2X3 and P2X7 in the spinal dorsal horn (29); iv) promoting phosphodiesterase 2A-cyclic guanosine monophosphate/cyclic AMP/NFκB-p65 signaling (30); v) inhibition of autophagy (31,32); vi) reduction of the expression of pro-inflammatory/pro-apoptotic caspases (33); and vii) increase of oxygen supply in tissues and cells (22).

OAH comprises the drawing of blood and blood transfusion through a steel needle, which causes vascular damage. To prevent infection, the blood transfusion operation requires strict aseptic conditions in the operating room. Furthermore, OAH is time-consuming and cumbersome. Therefore, clinicians are exploring novel techniques for systemic ozone delivery. It has been proposed that ozonated saline infusion may be able to replace OAH. Compared to OAH, ozonized saline infusion is easy to perform and does not require the drawing of blood or blood transfusions. Furthermore, the requirements for the operating room are easy to fulfill and the cost is relatively low, making ozonated saline infusion a possible alternative to OAH therapy. Compared to the OAH, the ozonated saline is more convenient and more operable, however there is controversial about clinical application of ozonated saline. A comparison of the two types of infusion is presented in Table I.

Intravenous infusion of ozonated saline has been used in the clinic to treat a variety of diseases. A clinical study suggested that intravenous infusion of ozonated saline contributes to the elimination of macrophages from wounds, mainly through regulating genetically programed cell death (apoptosis), which has a significant role in the inflammatory process (34). Intravenous infusion of ozonated saline may improve symptoms of ischemia and hypoxia in the lower limbs of patients with occlusive atherosclerosis by stabilizing lysosomal hydrolase activity (35). Intravenous infusion of ozonized saline may also reduce the viscosity of blood and the aggregation of red blood cells, as well as enhance the deformability of red blood cells (36).

Animal studies have indicated that intravenous injection of 5 ml/kg ozonized saline bubbled with 4 µg/ml ozone in dogs increased the number of polymorphonuclear neutrophilic leukocytes, as well as their ability to capture bacteria for 2 days. In addition, this treatment led to an increase in the adaptability and compensatory capacity of the body (37). Intravenous infusion of ozonated saline may relieve liver injury induced by CCl₄ via its effects on reactive oxygen species (ROS) and the Kelch-like ECH-associated protein 1/nuclear factor, erythroid 2-like 2/ARE signaling pathway in rats (38).

With the development of ozonated saline infusion, it has been suggested that ozonated saline may contain toxic substances, including hypochlorite, chlorite, chlorate or even perchlorate (39). However, it was reported that ozone interacts neither with Na⁺ nor with Cl^- and no sodium hypochlorite or other chlorine-containing oxygen ions were detected (40). The possible reaction mechanisms include the following: i) Chloride ions in normal saline are first oxidized by ozone to form chlorine atoms, initiating a chain reaction. The chlorine atoms are then oxidized by ozone to form harmful substances including chlorite, chlorate and perchlorate; ii) chloride ions are directly oxidized by ozone to form hypochlorite and oxygen, and hypochlorite is then oxidized by ozone to form chlorite, chlorate and perchlorate (39). These suggestions bring the clinical safety of ozonated saline infusion therapy into question (41).

In the present study, the safety of ozonated saline that may be used for intravenous infusion therapy was investigated. Ion chromatography-mass spectrometry (IC-MS) was used to determine the presence and content of chlorite, chlorate and perchlorate in ozonated saline at various time-points following preparation.

The results of the present study indicated that ozone is able to oxidize chloride ions in saline to form chlorate and the chlorate content gradually increased with time. In addition, higher ozone concentrations result in increased chlorate levels. Importantly, ozone may react with its container and thereby increase the levels of toxic substances in the ozone solution.

In the present study, when 100 ml of 20-60 µg/ml ozone was mixed with an equal volume of saline, the content of chlorate in the ozonated saline was between 0.90±0.14 and 207.6±15.63 µg/l. A low level (<0.4 µg/l) of chlorate was detected in the absence of ozone in the blood bag, this could be a result of detection errors of the machine, or from the material of the blood bag. To the best of our knowledge, no study has reported the toxic dose of intravenously infused chlorate, although the World Health Organization Guidelines for drinking-water quality stipulated that the maximum permitted concentration of chlorate in drinking water is 0.7 mg/l (43). One study observed the effect of intravenous or oral sodium chlorate administration on the fecal shedding of Escherichia coli in sheep. Sodium chlorate (150 mg/kg) was infused over 3 h or less (a volume of 0.9% physiological saline containing 150 mg/kg sodium chlorate in a total volume of 250 ml), whilst the control group was administered the same dose of sodium chlorate orally. The content of NaClO₃ in the serum of sheep was measured at 4, 8, 16, 24 and 36 h after administration. The highest concentration of NaClO₃ in the serum was observed at 4 h of infusion (194.1±28.4 µg/l). The same dose (150 mg/kg NaClO₃) was given orally, which also indicated a peak serum level after 4 h, reaching 138.9±13.2 µg/l (44). According to the results of the present study, the chlorate content in 100 ml ozonized saline was between 0.90±0.14 µg/l and 207.6±15.63 µg/l; this was much lower than the aforementioned toxic dose of chlorate and the maximum limit of the drinking-water standard setting after metabolism in the serum. However, since the chlorate in the ozone-saline solution is administered intravenously, its toxicity requires careful re-evaluation.

On the 3rd, 6 and 15th day, no chlorite was detected in any of the groups. It is speculated that the ozonated saline did not form any chlorite or the chlorite that had been formed within 3 days continued to be oxidized by ozone, turning into chlorate. On the 3rd, 6 and 15th day, no perchlorate was detected in the two groups. It appears that ozone mixed with normal saline does not produce perchlorate within the observed timeframe (15 days) in the present study. Since hypochlorite is formed instantaneously and decomposes rapidly, no hypochlorite was detected in the present study.

In order to simulate the ozone and saline reaction scenarios in the clinic, the present study used two ozone-saline containers that are commonly used in clinical settings: Saline bottles (polypropylene) and ozone-resistant blood transfusion bags [medical polyvinyl chloride, di(2-ethyl) hexyl phthalate plasticized]. The results suggested that under the same conditions, the chlorate content in ozonated saline in the blood bag made of ozone-resistant material was much lower than that in the saline bottle. As the reaction time went on, the chlorate content increased significantly. It may therefore be indicated that the material of the infusion container is able to affect the content of the toxic substances in the solution. The saline bottle material (polypropylene) may be oxidized by ozone, resulting in an increase of the chlorate content. These results suggested that the syringe and reaction container used for ozone therapy should consist of ozone-resistant materials, which would be effective in reducing the production of chlorate or any other toxic substances.

Previous studies indicated that oral administration of chlorate has multiple toxic effects. Ali et al (45) reported that a single oral dose of 100-750 mg/kg sodium chlorate in rats caused intestinal DNA damage through the production of ROS. Another study from the same group suggested that the same dose of sodium chlorate caused acute kidney injury in rats by producing an imbalance of redox reactions (46). Furthermore, different doses of sodium chlorate (0.106-1.06 mg/ml) not only induced oxidative stress in human red blood cells in vitro, leading to extensive damage to the cell membrane and reducing the anti-oxidant response, but also changed the morphology of red blood cells, increasing osmotic fragility. At the same time, exposure to different concentrations of sodium chlorate (0-10 nM) may lead to dose-dependent hemolysis (47). Chlorate and perchlorate affect the function of the thyroid gland. Following short-term (7 days) exposure to perchlorate (10 mg/l) and chlorate (100 mg/l) in rats, serum T4 was significantly lower than that in the control group (48). The incidence of thyroid follicular cell hypertrophy in male and female rats administered sodium chlorate was higher and the incidence of thyroid cancer was higher in the 2,000 mg/l chlorate group compared with that in the control group; furthermore, a small amount of islet cell tumors were produced in female rats exposed to sodium chlorate (49). As intravenous infusion therapy with ozonated saline usually requires repeated administrations in the short-term, further basic and clinical research is required to determine whether the accumulation of chlorate is able to affect blood, kidney and thyroid function.

According to Bocci et al (41), intravenous infusion of ozonated saline is potentially toxic and therefore, they do not support the systemic administration of ozone in this way. The specific reasons are as follows: i) Ozonated saline may contain toxic substances including H₂O₂, hypochlorous and hypochlorous acid; ii) ozonation of saline is an unstable process and if it is not injected on time, O₃ will completely decompose within 60 min; iii) during the infusion, the blood flow rate in the vein affects the concentration of H₂O₂-O₃, suggesting that there may be a variable biological oxidation process. Therefore, the therapy does not meet the therapeutic principles of clinical drugs, namely stability and clearly defined active components (41).

The present study suggests that there may be toxic substances, e.g. chlorate, in ozonated saline, and the toxic dose of these substances in the human body remains to be determined. As such, the outcome of long-term intravenous infusion of ozonized saline remains uncertain.

Of note, the present study has several limitations. The content of chlorite, chlorate and perchlorate in ozonated saline was only measured after 3 days in the present study, and it remains elusive whether any chlorite was present in the ozonated saline at earlier stages. In the clinic, ozonated saline is prepared upon its use. In addition, chlorate and perchlorate are relatively stable; therefore, their concentrations in the first 3 days should be less than that detected on the third day. As such, the current data are instructive for clinical work. Usually, 100 ml of ozonated saline is infused within half an hour during clinical treatment. Bocci et al (41) reported that ozone totally decomposed within 60 min and that intravenous infusion of ozone solutions should be completed within one hour; therefore, detection of chlorite, chlorate and perchlorate in ozonated saline as soon as possible would provide results that are more representative of the clinical scenario. However, in the present study, differences between 3, 6 and 15 days observed indicate that there may have still been some ozone present, that may have led to the generation of chlorate beyond several days.

In conclusion, ozonated saline solution contains chlorate and the ozone may react with the polypropylene of the saline bottle to increase the chlorate content in the solution. Although studies have reported that intravenous infusion of ozonated saline is safe and effective, due to the lack of blood chlorate toxicology studies, it remains elusive whether the levels of chlorate detected in the ozonated saline in this present study (0.90±0.14-207.6±15.63 µg/l) are safe for the solution to be given intravenously. Therefore, clinical intravenous infusion of ozonated saline should be used with caution. Importantly, ozone reacts with various containers and an ozone-resistant container for ozonated solution infusion is recommended.