Oliveira Rafaela F, Marquiore Larissa F, Gomes Cristopher B S, de Abreu Priscila T R, Ferreira Luiza A Q, Diniz Luiza A, Gomes Natália A, Jácome-Santos Humberto, Moreno Amália, Macari Soraia, Mesquita Ricardo A, Silva Tarcília A, Marques Márcia M, Diniz Ivana M A
Department of Restorative Dentistry, School of Dentistry, Universidade Federal de Minas Gerais, Belo Horizonte, Brazil.
Department of Oral Pathology and Surgery, School of Dentistry, Universidade Federal de Minas Gerais, Belo Horizonte, Brazil.
Wound Repair Regen. 2022 May;30(3):345-356. doi: 10.1111/wrr.13010. Epub 2022 Apr 15.
Photobiomodulation therapy (PBMT) has been widely used to promote tissue repair. However, PBMT's critical roles in the epithelial and mesenchymal tissues interactions are still barely known. Herein, we investigated light parameters on challenged keratinocytes (KC)-i.e., cultivated under oxidative stress-solely or associated with fibroblasts (FB) in a co-culture system. Cells were treated with PBMT at the wavelength of 660 nm, at 20 mW and 0.71 W/cm . Three different energy densities were primarily evaluated on KC: 1 (1.4 s), 5 (7 s), and 50 J/cm (70 s). Next, KC and FB were co-cultured and assessed at 5 J/cm . This energy density was also tested in ex vivo murine skin samples. Our main data suggest that PBMT can increase cellular proliferation at low doses and cell migration in a biphasic mode (1 and 50 J/cm ), both further confirmed by the epidermal growth factor receptor ligand-amphiregulin-upregulation. IL-1RA mRNA-the IL-1β (interleukin-1β) receptor antagonist recognized to fasten wound repair-was upregulated in the co-culture system. Upon PBMT, the ex vivo findings showed a progressive increase in the epidermal thickness, although presenting qualitatively less differentiated epithelium than the control group. In conclusion, PBMT effects are dependent on the cellular interactions with the surrounding microenvironment. Ultimately, PBMT is anti-inflammatory and contributes to the expression of critical mediators of wound repair.
光生物调节疗法(PBMT)已被广泛用于促进组织修复。然而,PBMT在上皮组织和间充质组织相互作用中的关键作用仍鲜为人知。在此,我们研究了光参数对受挑战的角质形成细胞(KC)的影响,即在氧化应激下单独培养或与成纤维细胞(FB)在共培养系统中联合培养的KC。细胞在波长660nm、功率20mW和0.71W/cm的条件下接受PBMT处理。主要在KC上评估了三种不同的能量密度:1J/cm²(1.4秒)、5J/cm²(7秒)和50J/cm²(70秒)。接下来,将KC和FB共培养,并在5J/cm²的条件下进行评估。该能量密度也在离体小鼠皮肤样本中进行了测试。我们的主要数据表明,PBMT在低剂量时可增加细胞增殖,并以双相模式(1J/cm²和50J/cm²)促进细胞迁移,这两者均通过表皮生长因子受体配体-双调蛋白的上调得到进一步证实。IL-1RA mRNA(已知可加速伤口修复的IL-1β(白细胞介素-1β)受体拮抗剂)在共培养系统中上调。经PBMT处理后,离体研究结果显示表皮厚度逐渐增加,尽管定性地看,其上皮分化程度低于对照组。总之,PBMT的作用取决于细胞与周围微环境的相互作用。最终,PBMT具有抗炎作用,并有助于伤口修复关键介质的表达。
