Combined photothermal and photodynamic therapy explained

See also: Photodynamic therapy and Photothermal therapy.

Photodynamic/photothermal combination therapy involves the usage of a chemical compound or nanomaterial that, when irradiated at a certain wavelength, converts light energy into reactive oxygen species (ROS) and heat. This has shown to be highly effective in the treatment of skin infections, showing increased wound healing rates and a lower impact on human cell viability than photodynamic (PD) or photothermal (PT) therapies. The compounds involved often employ additional mechanisms of action or side effect reduction mechanisms, further increasing their efficacy.^{[1] [2] [3]}

Phototherapies are minimally invasive, with the primary toxicity issues surrounding phototoxicity and the nonspecific ROS and heat mechanisms of action affecting healthy human cells (albeit in lower amounts than the target cells). In skin wound infections, multiple phototherapeutic approaches have observed increased rates of wound closure over nontreated controls. This is typically due to an upregulation of vascular endothelial growth factor (VEGF) and hypoxia-inducible factor (HIF). Phototherapies are also active against both gram-positive and gram-negative bacteria, with photodynamic therapy having some exceptions.^[4]

To apply this technique, a photosensitizer is localized to the wound or tumor site, either topically or intravenously. Once localized, the target area is exposed to a laser of a selected wavelength and intensity for a predetermined irradiation time. The wavelength, localization technique, laser intensity, and irradiation period are determined based on the individual phototherapeutic agent, as these factors can vary greatly from compound to compound. Topical applications may be through the incorporation of the phototherapeutic agent with a hydrogel that will slowly leech the compound into the wound, allowing for a more controlled production of ROS and/or heat.^{[5] [6]}

Phototherapy Types

See main article: articles and Photodynamic therapy.

Photodynamic Therapy

Photosensitizers and approved treatments

See also: Light therapy. A photosensitizer is a chemical compound or nanomaterial capable of capturing light energy and using this energy to generate ROS. Currently, there are 6 photosensitizers that are clinically-approved or undergoing clinical trials for the treatment of cancers and 1 approved for the treatment of eye disorders and diseases.^[7] Photodynamic therapy (PDT) is also often used for acne treatment as well as various dermatological conditions such as psoriasis, atopic dermatitis, and vitiligo.^[8] It is highly unlikely that bacteria would gain resistance to a photosensitizer or PDT treatment, as the photosensitizers can generate ROS within or outside of the target cell, both of which damage the membrane^[9]

Mechanism of action

A photosensitizer generates ROS through one of two processes. Type I involves a redox reaction that results in the creation of superoxides (O₂•⁻), hydroxyl radicals (OH•), and radical peroxides, whereas Type II generates singlet oxygen directly through an electron transfer from the photosensitizer. These ROS go on to nonspecifically damage a variety of cellular components, including proteins, DNA, and lipids as they seek to remove the radical.

Limitations

Due to the necessity of oxygen for PDT, these treatments do not work as well in hypoxic environments, including in developed tumors and some deep wounds. Dental infections tend to also respond better to photothermal therapy than photodynamic therapy, though both have a strong effect.^{[10] [11] [12]} The efficacy of PDT for antimicrobial usage is limited by the properties of the membrane of the target cell such as the electrical gradient (membrane potential) and lipid composition. Whereas high cell death is observed for Escherichia coli and Staphylococcus aureus, other bacterial species such as Klebsiella pneumoniae and Acinetobacter baumannii tend to see very low impact from PDT due to these factors. This limits potential as a broadband antibiotic, but may also allow for specificity in targeting the pathogenic cells over human and skin microbiome cells.

Photothermal Therapy

See main article: articles and Photothermal therapy. Indocyanine green is an FDA-approved photothermal agent that is primarily used in imaging techniques, but also displays anticancer and antimicrobial activity through photothermal therapy (PTT) treatments. Photothermal agents are active against diseased cells by accumulating in or around target cells, then converting light energy directly to heat, killing the target through heat-related damage.

PTT has a low level of selectivity beyond the accumulation stage, in which it tends to preferentially accumulate within diseased and bacterial cells. This increases broadband antibiotic activity and decreases the likelihood of resistance development, but also raises the impact on human cells. Human cells experience irreversible damage in the range of 46-60 °C, which is below temperatures reached by some photothermal agents during photothermal therapy.^[13] Human cell viability may be maintained through low temperature PTT (≤ 45 °C), which is typically only possible in combination with an additional antibiotic or photodynamic activity.^[14]

Combination Therapy - Antibacterial

Photodynamic/photothermal combination therapy combines the mechanisms of ROS production and heat generation into one treatment for a heightened effect on the target bacterial cells. In many cases, this can be done with a single compound or nanomaterial (phototherapeutic agent) and wavelength.

Advantages over monotherapy

Increased antibiotic efficacy

Due to the presence of both ROS and excess heat, target cells are less able to resist each effect. Increased heat corresponds to heightened cell membrane permeability,^[15] allowing the generation of ROS within the target cell. This also removes/reduces the selectivity observed for PDT, as it is able to enter the cell unhindered.

Lower side effects

Both photosensitizers and photothermal agents have some degree of selectivity for target cells over healthy human cells, but in utilizing both of these mechanisms this selectivity is bolstered. Increased antibiotic efficacy indicates a lower likelihood of requiring follow-up treatments, so the damage is minimal. In addition, some of these combination phototherapeutic agents have antioxidant/reactive oxygen scavenging properties, reducing the amount of collateral damage sustained by the surrounding human cells.

Incorporation of tertiary mechanisms

Many phototherapeutic agents that display both PD and PT activity come with added effects, such as antibiotic metal ions,^{[16] [17]} physical antibiotic mechanisms, or peroxidase-like activity.^[18] These added effects further increase antibiotic activity, often demonstrating broadband activity with 99% cell death or above regardless of strain or drug resistance.

Notes and References

1. Zhang . Xiangyu . Zhang . Guannan . Chai . Maozhou . Yao . Xiaohong . Chen . Weiyi . Chu . Paul K. . 2020-07-24 . Synergistic antibacterial activity of physical-chemical multi-mechanism by TiO2 nanorod arrays for safe biofilm eradication on implant . Bioactive Materials . en . 6 . 1 . 12–25 . 10.1016/j.bioactmat.2020.07.017 . 32817910. 7417618 .
2. Du . Ting . Xiao . Zehui . Cao . Jiangli . Wei . Lifei . Li . Chunqiao . Jiao . Jingbo . Song . Zhiyong . Liu . Jifeng . Du . Xinjun . Wang . Shuo . 2022-06-01 . NIR-activated multi-hit therapeutic Ag2S quantum dot-based hydrogel for healing of bacteria-infected wounds . Acta Biomaterialia . en . 145 . 88–105 . 10.1016/j.actbio.2022.04.013 . 35429669 . 248191429 . 1742-7061.
3. Ding . Qiuyue . Sun . Tingfang . Su . Weijie . Jing . Xirui . Ye . Bing . Su . Yanlin . Zeng . Lian . Qu . Yanzhen . Yang . Xu . Wu . Yuzhou . Luo . Zhiqiang . Guo . Xiaodong . 2022-02-19 . Bioinspired Multifunctional Black Phosphorus Hydrogel with Antibacterial and Antioxidant Properties: A Stepwise Countermeasure for Diabetic Skin Wound Healing . Advanced Healthcare Materials . en . 11 . 12 . 2102791 . 10.1002/adhm.202102791 . 35182097 . 246974402 . 2192-2640.
4. Nie . Xiaolin . Jiang . Chenyu . Wu . Shuanglin . Chen . Wangbingfei . Lv . Pengfei . Wang . Qingqing . Liu . Jingyan . Narh . Christopher . Cao . Xiuming . Ghiladi . Reza A. . Wei . Qufu . 2020 . Carbon quantum dots: A bright future as photosensitizers for in vitro antibacterial photodynamic inactivation . Journal of Photochemistry and Photobiology B: Biology . en . 206 . 111864 . 10.1016/j.jphotobiol.2020.111864. 32247250 . 214794593 .
5. Xu . Yinglin . Chen . Haolin . Fang . Yifen . Wu . Jun . 2022-06-25 . Hydrogel Combined with Phototherapy in Wound Healing . Advanced Healthcare Materials . en . 11 . 16 . 2200494 . 10.1002/adhm.202200494 . 35751637 . 250021788 . 2192-2640.
6. He . Yuanmeng . Liu . Kaiyue . Guo . Shen . Chang . Rong . Zhang . Chen . Guan . Fangxia . Yao . Minghao . 2023-01-01 . Multifunctional hydrogel with reactive oxygen species scavenging and photothermal antibacterial activity accelerates infected diabetic wound healing . Acta Biomaterialia . en . 155 . 199–217 . 10.1016/j.actbio.2022.11.023. 36402298 . 253659280 .
7. Baskaran . Rengarajan . Lee . Junghan . Yang . Su-Geun . 2018-09-26 . Clinical development of photodynamic agents and therapeutic applications . Biomaterials Research . 22 . 1 . 25 . 10.1186/s40824-018-0140-z . 2055-7124 . 6158913 . 30275968 . free .
8. Web site: Photodynamic Therapy (PDT): Procedure, Uses & Recovery . 2023-04-29 . Cleveland Clinic . en.
9. Cao . Changyu . Zhang . Tingbo . Yang . Nan . Niu . Xianghong . Zhou . Zhaobo . Wang . Jinlan . Yang . Dongliang . Chen . Peng . Zhong . Liping . Dong . Xiaochen . Zhao . Yongxiang . 2022-03-28 . POD Nanozyme optimized by charge separation engineering for light/pH activated bacteria catalytic/photodynamic therapy . Signal Transduction and Targeted Therapy . en . 7 . 1 . 86 . 10.1038/s41392-022-00900-8 . 2059-3635 . 8958166 . 35342192.
10. Fekrazad . Reza . Khoei . Farzaneh . Bahador . Abbas . Hakimiha . Neda . 2020-08-17 . Comparison of different modes of photo-activated disinfection against Porphyromonas gingivalis: An in vitro study . Photodiagnosis and Photodynamic Therapy . en . 32 . 101951 . 10.1016/j.pdpdt.2020.101951. 32818643 . 221221714 .
11. Böcher . Sarah . Wenzler . Johannes-Simon . Falk . Wolfgang . Braun . Andreas . 2019-07-14 . Comparison of different laser-based photochemical systems for periodontal treatment . Photodiagnosis and Photodynamic Therapy . en . 27 . 433–439 . 10.1016/j.pdpdt.2019.06.009. 31319164 . 197663815 .
12. Shim . Sang Ho . Lee . Si Young . Lee . Jong-Bin . Chang . Beom-Seok . Lee . Jae-Kwan . Um . Heung-Sik . 2022-02-13 . Antimicrobial photothermal therapy using diode laser with indocyanine green on Streptococcus gordonii biofilm attached to zirconia surface . Photodiagnosis and Photodynamic Therapy . en . 38 . 102767 . 10.1016/j.pdpdt.2022.102767. 35182778 . 246926124 .
13. Zhang . Xingyu . Zhang . Guannan . Zhang . Hongyu . Liu . Xiaoping . Shi . Jing . Shi . Huixian . Yao . Xiaohong . Chu . Paul K. . Zhang . Xiangyu . 2020 . A bifunctional hydrogel incorporated with CuS@MoS2 microspheres for disinfection and improved wound healing . Chemical Engineering Journal . en . 382 . 122849 . 10.1016/j.cej.2019.122849. 203938686 .
14. Zhu . Hao . Cheng . Xuedan . Zhang . Junqing . Wu . Qiang . Liu . Chaoqun . Shi . Jiahua . 2023 . Constructing a self-healing injectable SABA/Borax/PDA@AgNPs hydrogel for synergistic low-temperature photothermal antibacterial therapy . Journal of Materials Chemistry B . en . 11 . 3 . 618–630 . 10.1039/D2TB02306G . 36537180 . 254439160 . 2050-750X.
15. Blicher . Andreas . Wodzinska . Katarzyna . Fidorra . Matthias . Winterhalter . Mathias . Heimburg . Thomas . 2009 . The Temperature Dependence of Lipid Membrane Permeability, its Quantized Nature, and the Influence of Anesthetics . Biophysical Journal . 96 . 11 . 4581–4591 . 10.1016/j.bpj.2009.01.062 . 0006-3495 . 2711498 . 19486680. 0807.4825 . 2009BpJ....96.4581B .
16. Zhang . Zhen-Yu . An . Yan-Lin . Wang . Xiao-Shi . Cui . Lan-Yue . Li . Shuo-Qi . Liu . Cheng-Bao . Zou . Yu-Hong . Zhang . Fen . Zeng . Rong-Chang . 2022 . In vitro degradation, photo-dynamic and thermal antibacterial activities of Cu-bearing chlorophyllin-induced Ca–P coating on magnesium alloy AZ31 . Bioactive Materials . en . 18 . 284–299 . 10.1016/j.bioactmat.2022.01.050 . 8961461 . 35387161.
17. Cong . Xin . Mu . Yuzhi . Qin . Di . Sun . Xiaojie . Su . Chang . Chen . Tongtong . Wang . Xiaoye . Chen . Xiguang . Feng . Chao . 2022 . Copper deposited diatom-biosilica with enhanced photothermal and photodynamic performance for infected wound therapy . New Journal of Chemistry . en . 46 . 5 . 2140–2154 . 10.1039/D1NJ05283G . 245301085 . 1144-0546.
18. Zhang . Yan . Li . Danxia . Tan . Jinshan . Chang . Zhishang . Liu . Xiangyong . Ma . Weishuai . Xu . Yuanhong . 2021 . Near‐Infrared Regulated Nanozymatic/Photothermal/Photodynamic Triple‐Therapy for Combating Multidrug‐Resistant Bacterial Infections via Oxygen‐Vacancy Molybdenum Trioxide Nanodots . Small . en . 17 . 1 . 2005739 . 10.1002/smll.202005739 . 33284509 . 227520383 . 1613-6810.