Photochemical Tissue Passivation Prevents Contracture of Full Thickness Wounds in Mice.

BACKGROUND AND OBJECTIVES: Wound contracture formation from excessive myofibroblast activity can result in debilitating morbidities. There are currently no treatments to prevent contracture. Photochemical tissue passivation (PTP), an established, safe, and user-friendly treatment modality, crosslinks collagen by a light-activated process, thus modulating the wound healing response and scarring. We hypothesised that PTP treatment would reinforce wounds by blunting the fibrotic response thus limiting contracture. STUDY DESIGN/MATERIALS AND METHODS: Full-thickness, 1 cm × 1 cm excisional wounds were created on the dorsum of 32 C57BL/6 mice. Treated wounds were painted with photosensitizing dye and exposed to visible light. Wounds were serially photographed over 6 weeks to measure wound contracture. At 7, 14, 21, and 42 days after wound creation, mice were euthanized and wounds were harvested for histologic review by a dermatopathologist. RESULTS: By Day 7, control wounds had significantly more contracture than those treated with PTP (33.0 ± 17.1% and 19.3 ± 9.0%, respectively; P = 0.011). PTP-treated wounds maintained approximately 20% less contracture than controls from Day 14 and on (P < 0.05). By Day 42, wounds had contracted by 86.9 ± 5.5% in controls and 64.2 ± 3.2% in PTP-treated wounds (P < 0.03). Histologically, PTP wounds had earlier growth and development of dermal collagen, neovascularization, and development of skin appendages, compared with control wounds. CONCLUSIONS: PTP significantly limits contracture of full-thickness wounds and improves wound healing. PTP-treated wounds histologically demonstrate more mature structural organization than untreated wounds and closely resemble native skin. PTP treatment may be applicable not only for excisional wounds, but also for wounds with a high incidence of contracture and associated morbidity. Lasers Surg. Med. © 2019 Wiley Periodicals, Inc.

Light-activated sealing of skin wounds.

BACKGROUND AND OBJECTIVES: We have developed a light-activated technology for rapidly sealing skin surgical wounds called photochemical tissue bonding (PTB). The goals of this study were to evaluate parameters influencing PTB in order to optimize its clinical efficacy and to determine whether PTB can be used to seal wounds in moderately to highly pigmented skin. STUDY DESIGN/MATERIALS AND METHODS: Application of Rose Bengal (RB) followed by exposure to 532 nm was used to seal linear incisions (1.5 mm deep, 2 cm long) in lightly pigmented (Yorkshire) and darkly pigmented (Yucatan) swine skin. The force required to open the seal (the bonding strength) was measured by in situ tensiometry. Reflectance spectra, epidermal transmission spectra, and histology were used to characterize the skin. The relationships of RB concentration and fluence to bonding strength were established in Yorkshire skin. Surface temperature was measured during irradiations and cooling was used while sealing incisions in Yucatan skin. Monte Carlo simulations were carried out to estimate the effect of epidermal melanin on the power absorbed in the dermis at the incision interface. RESULTS: The lowest fluence, 25 J/cm(2), delivered at an irradiance of 0.5 W/cm(2) substantially increased the bonding strength (∼ 10-fold) compared to controls in Yorkshire swine skin. Increasing the fluence to 100 J/cm(2) enhanced bonding strength by a further 1.5-fold. Application of 0.1% RB for 2 minutes produced the greatest bonding strength using 100 J/cm(2) and limited the penetration of RB to an ∼ 50 µm band on the dermal incision wall. Reflectance spectra indicated that Yorkshire skin had minimal melanin and that Yucatan skin was a good model for highly pigmented human skin. In Yucatan skin, the bonding strength increased 1.7-fold using 0.1% RB and 200 J/cm(2) at 1.5 W/cm(2) with cooling and epinephrine. Monte Carlo simulation indicated that absorption of 532 nm light by epidermal melanin in dark skin decreased the power absorbed along the incision in the dermis by a factor of 2.7. CONCLUSIONS: These results suggest that in lightly pigmented skin the PTB treatment time can be shortened without compromising the bonding strength. Sealing incisions using PTB in moderately and highly pigmented skin will require a careful balance of irradiance and cooling.

Light-activated sutureless closure of wounds in thin skin.

BACKGROUND AND OBJECTIVES: Closing lacerations in thin eyelid and periorbital skin is time consuming and requires high skill for optimal results. In this study we evaluate the outcomes after single layer closure of wounds in thin skin with a sutureless, light-activated photochemical technique called PTB. STUDY DESIGN/MATERIALS AND METHODS: Dorsal skin of the SKH-1 hairless mouse was used as a model for eyelid skin. Incisions (1.2 cm) were treated with 0.1% Rose Bengal dye followed by exposure to 532 nm radiation (25, 50, or 100 J/cm(2); 0.25 W/cm(2)) for PTB. Other incisions were sutured (five 10-0 monofilament), exposed only to 532 nm (100 J/cm(2)), or not treated. Outcomes were immediate seal strength (pressure causing leakage through incision of saline infused under wound), skin strength at 1, 3, and 7 days (measured by tensiometry), inflammatory infiltrate at 1, 3, and 7 days (histological assessment), and procedure time. RESULTS: The immediate seal strength, as measured by leak pressure, was equivalent for all PTB fluences and for sutures (27-32 mmHg); these pressures were significantly greater than for the controls (untreated incisions or laser only treatment; P < 0.001). The ultimate strength of PTB-sealed incisions was greater than the controls at day 1 (P < 0.05) and day 3 (P < 0.025) and all groups were equivalent at day 7. Sutures produced greater inflammatory infiltrate at day 1 than observed in other groups (P = 0.019). The average procedure time for sutured closure (311 seconds) was longer than for the PTB group treated with 25 J/cm(2) (160 seconds) but shorter than the group treated with 100 J/cm(2) (460 seconds). CONCLUSION: PTB produces an immediate seal of incisions in thin, delicate skin that heals well, is more rapid than suturing, does not require painful suture removal and is easy to apply.

Photochemical tissue bonding: a potential strategy for treating limbal stem cell deficiency.

BACKGROUND AND OBJECTIVE: To determine the feasibility of attaching human amniotic membrane (HAM), pre-cultured with limbal stem cells (LSCs), to cornea using a novel, light-activated tissue bonding method. MATERIALS AND METHODS: LSCs were isolated from rabbit eyes, and then cultured on de-epithelialized HAM to create grafts (HAM/LSC). These were then transplanted onto rabbit eyes with surgically created limbal stem cell deficiency (LSCD). The grafts were secured either by sutures or by a light-activated method called photochemical tissue bonding (PTB). Outcomes included corneal opacity, inflammation, neovascularization, and collagen alignment. RESULTS: The isolated and cultured cells were verified to be LSCs based on their K19+/intergrin ß1+/P63+/K3 profile. Securing the HAM/LSC graft with PTB provided better outcomes. At 28 days post-surgery, the corneal opacity scores were significantly lower after securing the graft with PTB compared with suture attachment (0.8 ± 0.5 vs. 1.8 ± 0.5, P < 0.01). Similarly, neovascularization scores were lower after PTB (0.8 ± 0.5 vs. 1.5 ± 0.6, P < 0.01). Quantification of MPO and CD31 levels from immunofluorecent staining indicated that PTB stimulated less neutrophil infiltration (5.3 ± 2.2 vs. 13.3 ± 3.1, P < 0.01) and less new blood vessels formation (2.0 ± 0.8 vs. 6.3 ± 1.3, P < 0.01) at the wound site. The collagen alignment in PTB-treated corneas, as shown by immunofluorescence and second harmonic generation image, was better organized in the PTB-treated group than in the suture group. CONCLUSION: Bonding LSC grafts with PTB produced improved outcomes compared to suture attachment. This light-activated method is a promising modality for treating patients with LSCD.

Phototoxicity is not associated with photochemical tissue bonding of skin.

BACKGROUND AND OBJECTIVE: We have developed a light-activated method called photochemical tissue bonding (PTB) for closing wounds using green light and a photosensitizing dye (Rose Bengal-RB) to initiate photochemical crosslinking of wound surface proteins. These studies were designed to determine whether RB causes phototoxicity during closure of skin incisions with PTB. STUDY DESIGN/MATERIALS AND METHODS: RB phototoxicity was evaluated after sealing incisions in porcine skin ex vivo and rabbit skin in vivo using PTB (1 mM RB, 100 J/cm(2), 532 nm, 0.3 or 0.5 W/cm(2).) Dead cells were identified by pyknotic nuclei and eosinophilic cytoplasm on H&E-stained sections. The influence on RB phototoxicity of penetration of RB into the wound wall (by confocal microscopy), RB concentration in the tissue (by extraction), and fluence of 532 nm reaching depths in skin (calculated from skin optical properties) were investigated. RESULTS: No significant differences were found in the percent dead cells in PTB-treated and control incisions in porcine skin at 24 hours or in rabbit skin at 2 hours and 3 and 7 days after surgery. RB was retained in a approximately 100 microm wide band next to the wound wall. The mean RB concentration within this band was 0.42+/-0.03 mM. Monte Carlo modeling of light distribution indicated that the fluence rate decreased from the subsurface peak to 0.5 W/cm(2) in the mid-dermis (approximately 350 microm.) In vitro RB phototoxicity to dermal fibroblasts yielded an LD(50) of 0.50+/-0.09 J/cm(2) when the cells contained 0.46 mM RB. CONCLUSIONS: PTB does not cause phototoxicity when used to repair skin wounds even though the RB concentration and 532 nm fluence in the mid-dermis during PTB are much greater than the LD(50) for RB phototoxicity in vitro. These results indicate that phototoxicity is not a concern when using PTB for tissue repair.

Evaluation of photochemical tissue bonding for closure of skin incisions and excisions.

BACKGROUND AND OBJECTIVES: Photochemical tissue bonding (PTB) is a new non-thermal technique for tissue repair involving application of a photochemically active dye and irradiation with visible light. The objective was to compare PTB with standard sutures and the tissue adhesive, octyl cyanoacrylate, for closure of skin incisions and excisions. STUDY DESIGN/MATERIALS AND METHODS: Incisions and excisions made on the flanks of a Hanford mini-pig were secured with subcutaneous sutures. Superficial closure methods were 3-0 monofilament sutures, PTB (Rose Bengal and green light), tissue adhesive and the combination of tissue adhesive then PTB. Wounds were evaluated 2, 4, and 6 weeks postoperatively for cosmetic outcomes and histology. RESULTS: Cosmetic outcomes and histological scar width of incisions and excisions did not differ among the treatment groups at 2, 4, and 6 weeks. CONCLUSION: PTB is as effective as standard sutures for wound closure in porcine skin in terms of cosmetic outcomes and safety.

Photochemical keratodesmos as an adjunct to sutures for bonding penetrating keratoplasty corneal incisions.

PURPOSE: To evaluate the benefit of photochemical keratodesmos (PKD) in acute wound closure of penetrating keratoplasty (PKP) corneal incisions in vivo. SETTING: Massachusetts General Hospital and Massachusetts Eye and Ear Infirmary, Boston, Massachusetts, USA. METHODS: Penetrating keratoplasty incisions were performed in both eyes of 6 New Zealand white rabbits, followed by application of 1.5 mM rose bengal dye at the wound edges. The incision in 1 eye of each rabbit was irradiated with neodymium:YAG laser light at 532 nm and fluence of 40 J/cm2; the contralateral control eye was untreated. Intraocular pressure at which fluid leaked at the edges (IOPL) was determined immediately after surgery. RESULTS: The mean IOPL was 410 mm Hg +/- 70 (SD) in the PKD-treated eyes and 250 +/- 150 mm Hg in the unirradiated eyes. The difference was statistically significant by paired t test (P<.05). CONCLUSIONS: Photochemical keratodesmos may be a useful adjunct to sutures for approximating PKP corneal incisions in the immediate postoperative period. This process does not induce high temperature, and thus denaturation can be avoided and structural integrity restored.

Photochemical keratodesmos for bonding corneal incisions.

PURPOSE: To evaluate the immediate and long-term effectiveness of a dye-plus-laser irradiation treatment (photochemical keratodesmos [PKD]) for sealing corneal incisions. METHODS: Incisions (3.5 mm) in rabbit corneas were treated on the incision walls with rose bengal dye followed by exposure to 514-nm laser radiation. PKD was evaluated in three groups (n = 3-6) using laser fluences of 115, 153, or 192 J/cm(2) (180-, 240-, and 300- second exposures, respectively) compared with an untreated group (n = 8). The intraocular pressure at which leakage occurred (IOP(L)) during infusion of saline into the anterior chamber was determined. In a long-term study, treated and control corneas were observed weekly for 10 weeks for the appearance of neovascularization, anterior chamber inflammation, iridocorneal adhesion, corneal melting, and scarring. RESULTS: Immediately after treatment, the IOP(L) increased with increasing laser fluence, producing IOPs of 230 +/- 90, 370 +/- 120, and more than 500 mm Hg at 115, 153, and 192 J/cm(2), respectively, compared with 40 +/- 20 mm Hg in control eyes (P < 0.005). No reduction in the IOP(L) was observed up to 14 days after surgery. Corneal melting in PKD-treated or control eyes was not observed in the 10-week healing study. Neovascularization, which peaked at 4 weeks but resolved by 8 weeks, was detected around the incision in both PKD-treated and control eyes. CONCLUSIONS: Immediate and lasting sealing of corneal incisions was obtained in eyes treated with PKD, using short irradiation times. These results suggest that PKD has potential for improved corneal tissue bonding.