Morphological and histological changes in the urethra after intraurethral nonablative erbium YAG laser therapy: an experimental study in beagle dogs

According to the International Continence Society (ICS) and the International Urogynecology Association (IUGA), urinary incontinence (UI) is defined as involuntary loss of urine and is a common form of urinary dysfunction experienced by adult females [1]. UI is categorized as stress urinary incontinence (SUI), urgency urinary incontinence (UUI), and mixed-type urinary incontinence (MUI). Nearly 50% of adult women experience urinary incontinence,[2, 3] and approximately 37.5% of young women (30–50 years) complain of SUI [4], which can seriously affect the health and quality of life of women [3, 5]. Treatments for female SUI are mainly classified as conservative or surgical [3]. At present, for most patients with SUI, the initial treatment option is conservative treatment, such as pelvic floor muscle training (PFMT), electrical stimulation, biofeedback, or medications (e.g., duloxetine) [3, 6]. However, the effectiveness of these treatments relies on adherence to treatment [7‐9]. For patients with severe leakage symptoms or for whom conservative treatment fails, surgical treatment may be offered. Surgical treatment options include midurethral slings, Burch colposuspension, urethral bulking, and artificial urinary sphincter [3, 10]. Although surgical methods, especially midurethral sling, can be efficient, they can also lead to a range of adverse effects and complications, such as bleeding, infection, bladder perforation, mesh exposure, and groin pain [11, 12]. Due to the increasing number of reports of these adverse events, the number of sling procedures has obviously decreased in recent years [13‐15]. Thus, patients are seeking alternative less invasive or noninvasive procedures.

In the past decade, many clinical studies have reported that nonablative mode erbium:yttrium aluminum garnet (Er:YAG) laser therapy can effectively treat female SUI [16‐20]. The mechanism of this treatment is based on collagen remodeling and reconstruction, which strengthen the vaginal wall and improve SUI symptoms by enhancing urethral support [19‐21]. Recently, innovative intraurethral Er:YAG laser therapy in nonablative mode alone was reported to relieve female SUI symptoms, and the preliminary results showed that it is a promising treatment for this disease [16]. However, the safety of this treatment [16, 22, 23] and the mechanism of its effects have not yet been clarified.

This study aimed to investigate the morphological and histological changes in the urethra in beagle dogs after intraurethral Er:YAG laser irradiation in nonablative mode to confirm the safety of this therapy and to explore the therapeutic mechanism.

Er:YAG lasers are solid-state lasers that typically emit infrared light with a wavelength of 2940 nm. [21] The output of the laser is strongly absorbed by water, which is the major component of human tissue. Nonablative mode Er:YAG laser irradiation involves precisely controlled sequences of nonablative pulses that have the ability to achieve controlled heating of the deep mucosa layers to approximately 65℃ [21, 24]. At this temperature range, collagen contraction is promoted without induction of cell death, and collagen reconstruction and neocollagenesis are initiated in the treated area [21]. In this way, transvaginal nonablative mode Er:YAG laser treatment can alleviate SUI by providing reinforcement of vaginal support, which can then reduce urethral movement [19, 21, 25].SUI may be caused by an urethral hypermobility and internal sphincter deficiency (ISD). Clinically, Valsalva leak point pressure < 60 cm H₂O is a widely accepted standard definition of ISD. There are accumulating reports indicating that intraurethral nonablative mode Er:YAG therapy has a therapeutic effect in ISD [16]. Histological data related to the effect of nonablative mode Er:YAG laser therapy in other tissues, such as the vaginal mucosa [25, 26], bone [27], skin [28], oral tissues [29, 30], and peripheral nerves [31], is currently available. However, the morphological and histological alterations in the urethra induced by this intraurethral treatment modality, which play key roles in determining its safety (especially its potential to induce urethral stricture) and efficacy, are still unknown. Although the morphological structure of the urethra is not identical in female canines and women, the urethral cavity diameters of the two species are similar, meaning that a human urethral cannula can be inserted for Er:YAG laser treatment. The urethra of the beagle also has a thick mucosa and submucosa, limiting the penetration of the Er:YAG laser to the mucosa and submucosa, which is helpful for evaluating histological changes that occur after Er: YAG laser irradiation at clinically relevant parameters. Transurethral Er:YAG laser treatment requires an urethral cannula to be placed into the urethra. In order to rule out the influence of this operation on the experimental results, a sham treatment was designed as a control group in this experiment. Urethral stricture, which is a refractory disease, can seriously affect the patient’s voiding function and quality of life. The practitioners, such as the urologists, are always concerned about this caused by the transurethral laser therapy. Our imaging results showed that the caliber of the urethral lumen in the sham group and the irradiated group was roughly the same and that narrowing was not observed in any histological samples from the irradiated group. Given the above results, it can be implied that intraurethral nonablative Er:YAG laser irradiation does not cause urethral stricture at clinically relevant parameters.

Additionally, we found that the thickness of the urethral mucosa was significantly thicker in the irradiated group than in the sham group and that the expression of collagen under the mucosa was significantly increased as well. These results are consistent with the findings of previous studies in other organs. [25, 26]. A possible mechanism for this phenomenon is that nonablative Er:YAG laser up-regulates differentiation marker genes, down-regulates immune response–related genes, and induces the expression of collagen-encoding genes. [32] More interestingly, our results showed that the urethral mucosal folds also increased in the irradiated group compared with the control group. Because many reports have shown that the urethral mucosa has the capability to improve urinary incontinence,[33] we speculate that this increase in urethral mucosal folds may, to some extent, play a role in improving the ability of the urethra to control urine flow. Theoretically, these mucosal folds can increase the resistance of the urethral lumen and mucosal seal. Due to the small number of experimental animals, further studies are needed to confirm whether this urinary control mechanism exists. Urethral fibrosis is an important pathological feature of urethral stricture. TGF-β1 signaling has been reported as the critical pathway involved in the pathology of fibrosis. To further evaluate the histological changes related to scars, we analyzed the expression of α-SMA and TGF-β1 in urethral tissue. Currently, it is generally believed that the higher the expression of TGF-β1 is, the greater the degree of scar hyperplasia [34, 35]. Additionally, α-SMA serves as a typical marker of myofibroblasts, and its expression can be upregulated by TGF-β1. The expression of α-SMA in myofibroblasts is associated with wound contraction and extracellular matrix production, thus making it important in urethral wound healing research. [35, 36] In the present study, our results revealed that the expression of TGF-β1 and α-SMA in the urethral mucosa was not significantly increased in the transurethral Er:YAG laser irradiation group compared with the sham group. Previous studies revealed that the nonablative mode of the Er:YAG laser produces collagen hyperthermia, collagen remodeling, and the synthesis of new collagen fibers. The present study found that the TGF-β1 pathway was not significantly activated. This may suggest that collagen regeneration may be mediated by other signaling mechanisms. As shown in previous studies, Er:YAG laser can induce the expression of collagen-encoding genes as described by Huth et al. [32]

In summary, intraurethral nonablative Er:YAG laser irradiation at clinically relevant parameters does not cause urethral stricture in female beagle dogs. The thickening of the mucosa in the urethra and the proliferation of collagen fibers under the mucosa may be two of the mechanisms by which after erbium laser irradiation improves the symptoms of urine leakage, but further in-depth research is required.