Revealing the therapeutic effects of aminolevulinate mediated femtosecond laser induced photo-chemotherapy in different cancer cells

It has been proven more than 15 years ago that, rapid laser technology can be used to micro-structure materials by laser pulses very accurately (1). Femtosecond (fs) laser source develops very low thermal and physical deterioration to the neighboring material and tissue. This property leads the adaptation of fs laser technology to medicine. The usage of fs technology has been demonstrated in cornea shaping, photodynamic therapy, dental and ear surgery (2). The advantages of fs lasers in PDT include deep penetration of long laser wavelengths, the potential to reach the location of the tissue to be treated and decreased photo-bleaching of the photosensitizing agent (3). Photodynamic therapy has been proven to be an effective therapeutic way in dentistry for the treatment of periodontal pockets and osteo-necrosis in jaw (4). Photofrin (Porfimer Sodium) is a United States Food and Drug Administration (U.S. FDA) approved photosensitizing agent commonly used to treat esophageal cancer and non-small cell lung cancer by red laser induced PDT (5). So, PDT seems one of the novel therapeutic strategies deserving of work on for optimizing the parameters (6).

The therapy strategies for cancer patients with solid tumors have been developing through improvement of new generation drugs and therapeutic regimens (7). On the other hand, resistance acquired by tumor cells during chemotherapy develops demand to find other therapy protocols (8). One of the effective therapy protocols may be photodynamic therapy that the light source and photosensitizing agent stimulates the oxidative damage in tumor cells (9). PDT is a type of photo-chemotherapy which is based on the application of photosensitizer through systemic or topical ways and irradiation of the region by light sources. Photosensitizer and light interaction will develop reactive oxygen radicals in the cells. Porphyrin derivatives or porphyrin precursors may be used as photosensitizer and laser or incoherent light may be used as light source during PDT. Because malignant cells accumulate photosensitizer more than normal cells do, irradiation of the target region by light source will cause destruction of cancer cells preferentially due to highly reactive singlet oxygen accumulation and increased oxidative stress (9, 10). This feature makes PDT, a good targeted therapeutic strategy for cancer treatment. Photodynamic therapy provides the advantages like: tumor tissue specificity, prevention of resistance, multi PDT application on to the same tumor (10). ALA-PDT therapy is not developed very recently however the intensions of researchers for investigating the suitable photosensitizing material and its optimal concentration, light source and its effective intensity, and optimum wavelength, are going on. (11). Aminolevulinate (Aminolevulinic acid, 5-ALA) is metabolized to PpIX through heme pathway (12). PpIX activation induces the generation of singlet oxygen species in mitochondria and cell death is experienced (13, 14, 15). 5-ALA has some potential advantages as photosensitizer as it is naturally occurring intermediate in the heme biosynthetic pathway, low amount of external ALA will be sufficient to induce PpIX. ALA also does not have intrinsic photosensitizer effect different from most of the photosensitizers and it has a more rapid photosensitizer clearance (16, 17). ALA-HCl has been approved by U.S. FDA as a drug to be used for brain tumor diagnosis on June 2017 (Gleolan, NX Development Corp.). Since 5-ALA is a naturally occurring metabolite not only in animal cells but also in some bacteria, it is produced by biotechnological methods in biorefinery concept (18). It is a potential valuable natural photosensitizing agent, so we focused on to establish the optimum wavelength for ALA-mediated fs-PDT to provide insight its usage as therapeutic tool and its dual function for cancer theranostics.

A Ti:Sapphire femtosecond (fs) pulsed facility was used to irradiate the tumor model cells. It provides the opportunity to work different wavelengths and to investigate the effects of altered wavelength on the efficacy of photodynamic therapy.

The aim of this study is to investigate the therapeutic effects of 5-ALA mediated and fs induced photodynamic therapy in breast cancer MCF-7, metastatic skin cancer SKMEL-30 and high grade bladder cancer UMUC-3 cells in time and wavelength dependent manner. The potential use of femtosecond laser at the most effective wavelength between Ultraviolet (UV, 230nm) –and Near Infrared (NIR, 800nm) in ALA-PDT in cancer therapy was evaluated. The use of fs laser provides the ease of working at varying wavelengths with single equipment for different photosensitizers having different absorbance features. The use of ALA- PDT by fs laser induction may lead a new theranostic tool for breast cancer, melanoma and high grade bladder cancer.

Efficacy of 5-ALA mediated photodynamic therapy with 30 different laser wavelengths in bladder, skin and breast cancer models was investigated in this study. The most effective PDT wavelength was determined by evaluating the cell viability analyses. Findings will provide new experimental biomedicinal results to the literature that were arisen from application of femto second laser at 30 different wavelengths on aminolevulinic acid treated bladder, skin and breast cancer cells. In our previous study we claimed that melanoma cells that were treated with fs induced ALA-phototherapy experienced apoptotic and necrotic cell death (11). In that work, the cells were excited by fs laser pulses (10-15 sec) to target the light route, andalso it is known that fs-PDT does not cause any adverse effects to the nearby tissue (22). This treatment protocol may be very similar to the targeted therapy strategy. Three different model cell lines were used in this study and high grade bladder cancer cells and breast cancer cells were more sensitive to ALAPDT when compared to metastatic melanoma cells.

The influence of ALA-PDT on bladder cancer cells is considerable and promising in terms of the applicability of the treatment procedure to clinic. Bogoeva and his group applied Ruthenium (II) Porphyrin (RuP) mediated PDT with continuous blue light laser for 10 minutes on bladder cancer cells (23). They have found that cell survival was dramatically reduced to 14% after illumination of 20 μM RuP with 15.6 J/cm² blue light. They declared that the high percentage of cell population experienced necrosis. However the effect was not due to light source or photo-activation but the major effect was due to the toxicity of photosensitizer ruthenium porphyrin alone. In our study we found promising results with application of very short fs laser durations (30s, 60s). In our study generally, exposure durations of 30s and 60s did not exerted any significant differences between each other for the analyzed wavelengths of 400nm and 600 nm bands. So we may propose that use the lowest exposure time as possible would be more advantageous. This would provide the low light toxicity for the normal surrounding cells and also short therapy periods. It may be proposed that, the 5-ALA mediated, fs laser PDT may be targeted therapy with early response for bladder cancer and breast cancer. On the other side, these suggestions need to be proven by in-vivo tests.

Cell death after ALA-PDT with continuous light for 125 and 500 seconds was proved to be occurred due to apoptosis originated from alterations in JAK/STAT pathway and Bcl-2, Bax gene expression levels in A431 and COLO-6 cells (24). Di Venosa et al. previously claimed that THP-ALA has a good systemic distribution to be used for brain tumors and they have also proved that ALA derivatives have high topical infusion rate and stability to be used for skin cancers (25). It is known that, activation of photosensitizer by any light source; continuous or pulsed; the reactive oxygen radicals develop in the presence of oxygen. These species oxidize cellular components, causing apoptosis and necrosis (26). It means that here the key factor is activating the photosensitizing molecule by any light source. On the other side, it would be preferred that duration of irradiation would be short, energy of the light is effective to cause cancer cell death and the conditions are safe for neighboring healthy cells. In this study we regarded the PDT conditions that allow cell viability at most 50-60% and at which the control cell viability is high as “the efficient condition”, additionally other parameters on real tissue experiments should be performed and optimization of the parameters for photo-chemotherapy may be considered in that more narrow range in future studies. Here the conditions that the cells from different cancer sources experience cell death through apoptosis and/or necrosis after the fs-PDT were reported. On the other hand, the molecular mechanisms of the PDT resistance, the responsible proteins and the genes should be investigated in detail in coming studies.

It was reported that, altered activities of heme biosynthesis enzymes, functions of mitochondria elements and activities of membrane transporters may be different in different cancer types (27). These parameters contribute to ALA mediated protoporphyrin accumulation in tumor cells. ALA mediated cancer diagnosis may be enhanced by molecular modulations. So, here our results revealed that ALA mediated PpIX accumulation may be used in diagnostic applications in skin, bladder and breast cancer in the experimental parameters used in our work. Barcessat et al. tested ALA mediated PDT with diode laser at a wavelength 660 nm, 40 mW power, 90 J/cm² fluency for 1.5 min in each point to treat oral lesions (28). They found that two sessions of ALA mediated PDT with indicated induction parameters was not enough for total remission of the lesion. They claimed that more PDT sessions must be applied to guarantee the total healing. The light source is important parameter in PDT; it is known that non-coherent light sources are easy to use and relatively cheap. However, lasers are useful as they produce mono-chromatic light of a predetermined wavelength, light dose can easily be calculated and the light can reach through the optical fiber to the target location (16). Hammer et al. claimed that femtosecond pulses are comparatively safe, having high threshold for laser-induced breakdown in aqueous matrix (29). Actually their results demonstrate that the predominating breakdown process of the fs pulse is multi-photon breakdown of water and this is not dependent to the existence of electrolytes. According to literature, pulsed light offers potential advantages since pulsed lasers can generate low heating in the target tissue and neighboring tissue. Sometimes delivering light to deeper tissue may be preferred, like in cases of breast cancer tumors. In such cases increased power is needed to develop required energy at tumor site and that much power may result in tissue at the surface layer of the target tissue. In such circumstances pulsed light may be more effective (30). Hashmi et al. claimed that the “quench period” when the laser pulse is off, reduces heating and allows the use of much higher power intensity that may be safely applied to tissue without pain. In this study, we used femtosecond laser as a light source. To sum up, fs-laser has potential to be used as a light source for cancer therapy by PDT in clinic.

According to our findings, all the cancer cells were not cleared with 100% cell death. By selecting the possible effective wave-lengths, we developed a background for the future studies. Accordingly, the parameters may be altered. Also it would be enlightening to focus on the gene expression analysis at the most effective parameters. The 400 nm and 630 nm ALA mediated fs-PDT should be deeply studied to exhibit the other cellular and molecular analysis. Collectively, 70% cell death was reached that may be assumed as a good beginning for a therapeutic strategy for the cancer types we worked in this paper. At this point another question will be if the melanoma cells have exhibited resistance to ALA mediated fs-PDT. This is the first report which evaluates the ALA mediated PDT in different cancer cells with different fs laser wavelengths as light source. The results demonstrate that ALA and femtosecond laser mediated PDT may be used together as therapeutic and diagnostic tool to target different cancer types. Here, it is confirmed that the wavelength of laser treatment and treatment duration are important parameters that determine the destiny of ALA mediated fs laser-photodynamic therapy.