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01-12-2024 | Laser | Original Article

Fluorescent microscopy evaluation of diode laser effect on the penetration depth of turmeric (Curcuma longa) extract cream on skin tissues of Wistar rats

Authors: Suryani Dyah Astuti, Amiliyatul Mawaddah, Idha Kusumawati, Amalia Fitriana Mahmud, Aulia Muhammad Taufiq Nasution, Bambang Purwanto, Yunus Susilo, Ahmad Khalil Yaqubi, Ardiansyah Syahrom

Published in: Lasers in Medical Science | Issue 1/2024

Abstract

The study investigates the effect of diode laser exposure on curcumin’s skin penetration, using turmeric extraction as a light-sensitive chemical and various laser light sources. It uses an in vivo skin analysis method on Wistar strain mice. The lasers are utilized at wavelengths of 403 nm, 523 nm, 661 nm, and 979 nm. The energy densities of the lasers are 20.566 J/cm², 20.572 J/cm², 21.162 J/cm², and 21.298 J/cm², which are comparable to one another. The experimental animals were divided into three groups: base cream (BC), turmeric extract cream (TEC), and the combination laser (L), BC, and TEC treatment group. Combination light source (LS) with cream (C) was performed with 8 combinations namely 523 nm ((L1 + BC) and (L1 + TEC)), 661 nm ((L2 + BC) and (L2 + TEC)), 403 nm ((L3 + BC) and (L3 + TEC)), and 979 nm ((L4 + BC) and (L4 + TEC)). The study involved applying four laser types to cream-covered and turmeric extract–coated rat skin, with samples scored for analysis. The study found that both base cream and curcumin cream had consistent pH values of 7–8, within the skin’s range, and curcumin extract cream had lower viscosity. The results of the statistical analysis of Kruskal–Wallis showed a significant value (p < 0.05), which means that there are at least two different laser treatments. The results of the post hoc analysis with Mann–Whitney showed that there was no significant difference in the LS treatment with the addition of BC or TEC when compared to the BC or TEC treatment alone (p > 0.05), while the treatment using BC and TEC showed a significant difference (p < 0.05). Laser treatment affects the penetration of the turmeric extract cream into the rat skin tissue.

Bunker C, Watchorn R (2023) Skin disease. In Medicine for Finals and Beyond. CRC Press, pp 611–656

Lim JS, Park HS, Cho S, Yoon HS (2018) Antibiotic susceptibility and treatment response in bacterial skin infection. Ann Dermatol 30:186CrossRefPubMedPubMedCentral

Russo A, Concia E, Cristini F, De Rosa FG, Esposito S, Menichetti F, Bassetti M (2016) Current and future trends in antibiotic therapy of acute bacterial skin and skin-structure infections. Clin Microbiol Infect 22:S27–S36CrossRefPubMed

Astuti SD, Arifianto D, Drantantiyas ND, Nasution AM (2016) Efficacy of CNC-diode laser combine with chlorophylls to eliminate Staphylococcus aureus biofilm. In 2016 International Seminar on Sensors, Instrumentation, Measurement and Metrology (ISSIMM). IEEE Xplore 57–61.

Astuti SD, Drantaniyas ND, Putra APSP, Syarom A, Suhariningsih S (2018) Photodynamic effectiveness of laser diode combined with ozone to reduce Staphylicoccus aureus biofilm with exogenous chlorophyll of Dracaena angustifolia leaves. Biomedical Photonics 7:4–20

Astuti SD, Zaidan AH, Setiawati EM, Suhariningsih S (2016) Chlorophyll mediated photodynamic inactivation of blue laser on Streptococcus mutans. In AIP Conference Proceedings. 1718. AIP Publishing

Astuti SD, Mahmud AF, Putra AP, Setiawatie EM, Arifianto D (2020) Effectiveness of bacterial biofilms photodynamic inactivation mediated by curcumin extract, nanodoxycycline and laser diode. Biomed Photonic T9:4–14

Astuti SD, Kharisma DH, Kholimatussa'Diah S, Zaidan AH (2017) In vitro antifungal efficacy of diode laser-activated silver nanoparticles against Candida albicans, AIP Conference Proceedings. UNAIR

Astuti SD, Rulaningtyas R, Putra AP, Arifianto D (2020) The efficacy of photodynamic inactivation with laser diode on Staphylococcus aureus biofilm with various ages of biofilm. Infect Dis Rep 12:8736CrossRefPubMedPubMedCentral

10.

Astuti SD, Pratiwi WI, Tanassatha SA, Alamsyah KA, Susilo Y, Khasanah M (2021) Effect of ozone-induced diode laser of photodynamic inactivation on Pseudomonas aeruginosa. Mal J Med Health Sci 17:27–32

11.

Puspita PS, Putra AP, Zaidan AH, Fahmi MZ, Syahrom A, Suhariningsih, (2019) The antifungal agent of silver nanoparticles activated by diode laser as light source to reduce C. albicans biofilms: an in vitro study. Lasers Med Sci 34:929–937CrossRefPubMed

12.

Warrier A, Mazumder N, Prabhu S, Satyamoorthy K, Murali TS (2021) Photodynamic therapy to control microbial biofilms. Photodiagn Photodyn Ther 33:102090CrossRef

13.

Qiao Y, Ma F, Liu C, Zhou B, Wei Q, Li W, Zhou M (2018) Near-infrared laser-excited nanoparticles to eradicate multidrug-resistant bacteria and promote wound healing. ACS Appl Mater Interfaces 10:193–206CrossRefPubMed

14.

Fekrazad R, Sarrafzadeh A, Kalhori KA, Khan I, Giubellino APR, A, (2018) Improved wound remodeling correlates with modulated TGF-beta expression in skin diabetic wounds following combined red and infrared photobiomodulation treatments. Photochem Photobiol 94:775–779CrossRefPubMed

15.

Ash C, Dubec M, Donne K, Bashford T (2017) Effect of wavelength and beam width on penetration in light-tissue interaction using computational methods. Lasers Med Sci 32:1909–1918CrossRefPubMedPubMedCentral

16.

Astuti SD, Ma’rifah ZA, Fitriyah N, Zaidan AH, Arifianto D, Setiawatie EM (2019) The effectiveness of nano-doxycycline activated by diode laser exposure to reduce S. aureus biofilms: an in vitro Study. Photonic Diagnosis Treatment Infect Inflammatory Dis II 10863:180–191

17.

Mustafa FH, Jaafar MS (2013) Comparison of wavelength-dependent penetration depths of lasers in different types of skin in photodynamic therapy. Indian J Phys 87:203–209ADSCrossRef

18.

Astuti WD, Li K, Sato R, Matsukuma H, Shimizu Y, Gao W (2022) A second harmonic wave angle sensor with a collimated beam of femtosecond laser. Appl Sci 12:5211CrossRef

19.

Dias LD, Blanco KC, Mfouo-Tynga IS, Inada NM, Bagnato VS (2020) Curcumin as a photosensitizer: from molecular structure to recent advances in antimicrobial photodynamic therapy. J Photochem Photobiol, C 45:100384CrossRef

20.

Halevas E, Arvanitidou M, Mavroidi B, Hatzidimitriou AG, Politopoulos K, Alexandratou E, Sagnou M (2021) A novel curcumin gallium complex as photosensitizer in photodynamic therapy: synthesis, structural and physicochemical characterization, photophysical properties and in vitro studies against breast cancer cells. J Mol Struct 1240:130485CrossRef

21.

Hosseini A, Hosseinzadeh H (2018) Antidotal or protective effects of Curcuma longa (turmeric) and its active ingredient, curcumin, against natural and chemical toxicities: a review. Biomed Pharmacother 99:411–421CrossRefPubMed

22.

Popuri AK, Pagala B (2013) Extraction of curcumin from turmeric roots. Int J Innov Res Stud 2:289–299

23.

Im K, Kumar D, Ninan E (2015) Enhanced absorption and pharmacokinetics of fresh turmeric (Curcuma Longa L) derived curcuminoids in comparison with the standard curcumin from dried rhizomes. J Funct Foods 17:55–65. https://doi.org/10.1016/j.jff.2015.04.026CrossRef

24.

Yadav DK, Sharma K, Dutta A, Kundu A, Awasthi A, Goon A, Saha S (2017) Purity evaluation of curcuminoids in the turmeric extract obtained by accelerated solvent extraction. J AOAC Int 100:586–591CrossRefPubMed

25.

Sahne F, Mohammadi M, Najafpour GD, Moghadamnia AA (2016) Extraction of bioactive compound curcumin from turmeric (Curcuma longa L.) via different routes: a comparative study. Pakistan J Biotechnol 13:173–180

26.

Thangapazham RL, Sharad S, Maheshwari RK (2013) Skin regenerative potentials of curcumin. BioFactors 39:141–149CrossRefPubMed

27.

Shankar R, Sarangi B, Gupta R, Pathak K (2016) Formulation and characterization of polyherbal cream for skin manifestations. J Asian Assoc Schools Pharm 5:360–366

28.

Saraf S, Jeswani G, Kaur CD, Saraf S (2011) Development of novel herbal cosmetic cream with Curcuma longa extract loaded transfersomes for antiwrinkle effect. Afr J Pharm Pharmacol 5(8):1054–1062

29.

Nagata JY, Hioka N, Kimura E, Batistela VR, Terada RSS, Graciano AX, Hayacibara MF (2012) Antibacterial photodynamic therapy for dental caries: evaluation of the photosensitizers used and light source properties. Photodiagn Photodyn Ther 9:122–131CrossRef

30.

Lazzari G, Vinciguerra D, Balasso A, Nicolas V, Goudin N, Garfa-Traore M, Mura S (2019) Light sheet fluorescence microscopy versus confocal microscopy: in quest of a suitable tool to assess drug and nanomedicine penetration into multicellular tumor spheroids. Eur J Pharm Biopharm 142:195–203CrossRefPubMed

31.

Stelzer EH, Strobl F, Chang BJ, Preusser F, Preibisch S, McDole K, Fiolka R (2021) Light sheet fluorescence microscopy. Nat Rev Methods Primers 1:73CrossRef

32.

Dawson JB, Barker DJ, Ellis DJ, Cotterill JA, Grassam E, Fisher GW, Feather JW (1980) A theoretical and experimental study of light absorption and scattering by in vivo skin. Phys Med Biol 25:695CrossRefPubMed

33.

Gunjan J, Swarnlata S (2014) Topical delivery of Curcuma longa extract loaded nanosized ethosomes to combat facial wrinkles. J Pharm Drug Del Res 3:2–8

34.

Yaqubi AK, Astuti SD, Zaidan AH, Dezy ZIN (2024) Antibacterial effect of red laser-activated silver nanoparticles synthesized with grape seed extract against Staphylococcus aureus and Escherichia coli. Lasers Med Sci 39:47CrossRefPubMed

35.

Astuti SD, Utomo IB, Setiawatie EM, Khasanah M, Purnobasuki H, Arifianto D, Alamsyah KA (2021) Combination effect of laser diode for photodynamic therapy with doxycycline on a wistar rat model of periodontitis. BMC Oral Health 21:1–15CrossRef

36.

Astuti SD, Sulistyo A, Setiawatie EM, Khasanah M, Purnobasuki H, Arifianto D, Syahrom A (2022) An in-vivo study of photobiomodulation using 403 nm and 649 nm diode lasers for molar tooth extraction wound healing in wistar rats. Odontology 110:1–14.

37.

Al-Busaid MM, Akhtar MS, Alam T, Shehata WA (2020) Development and evaluation of herbal cream containing Curcumin from Curcuma longa. Pharm Pharmacol Int J 8:285–289CrossRef

Title: Fluorescent microscopy evaluation of diode laser effect on the penetration depth of turmeric (Curcuma longa) extract cream on skin tissues of Wistar rats
Authors: Suryani Dyah Astuti
Amiliyatul Mawaddah
Idha Kusumawati
Amalia Fitriana Mahmud
Aulia Muhammad Taufiq Nasution
Bambang Purwanto
Yunus Susilo
Ahmad Khalil Yaqubi
Ardiansyah Syahrom
Publication date: 01-12-2024
Publisher: Springer London
Keywords: Laser
Diode Laser
Published in: Lasers in Medical Science / Issue 1/2024
Print ISSN: 0268-8921
Electronic ISSN: 1435-604X
DOI: https://doi.org/10.1007/s10103-024-04020-3

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Fluorescent microscopy evaluation of diode laser effect on the penetration depth of turmeric (Curcuma longa) extract cream on skin tissues of Wistar rats

Abstract

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Abstract

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