Surgical Outcome of Potassium-Titanyl-Phosphate (KTP) Laser Photocoagulation for Vocal Fold Vascular Lesions.

INTRODUCTION: Laser technology is used in microscopic direct laryngeal surgery for a variety of indications. Lasers are categorized broadly as photoangiolytic or cutting/ablating lasers, based on the chromophores that absorb their energy. Photoangiolytic lasers such as the 532 nm Potassium-Titanyl-Phosphate (KTP) laser are absorbed selectively by the chromophore hemoglobin, facilitating controlled intravascular coagulation, with preservation of the overlying epithelium and adjacent tissue. Efficacy of the KTP laser has been demonstrated for incision, coagulation, and ablation in vocal fold (VF) surgery. OBJECTIVE: The purpose of the present study was to examine surgical outcomes following KTP laser photocoagulation for the management of VF vascular lesions. METHODS: Adult patients with sufficient data who had undergone KTP laser photocoagulation in the operating room for the treatment of VF vascular lesions were included in this retrospective study. Strobovideolaryngoscopy (SVL) video footage from all preoperative visits and all available postoperative visits was compiled and de-identified. Patients were followed up at days 1-7, 8-14, 30-60, and greater than 60 days after surgery. Three blinded physician evaluators reviewed and evaluated the SVL footage independently for postoperative outcome parameters. Postoperative SVL video footage was evaluated on a 5-point scale for surgical success (surgical objective score; 1 = failure and 5 = complete success). The average surgical objective score was 4.36, 4.04, 4.25, and 4.46 (out of 5) at postoperative visits 1-4, respectively. RESULTS: There were 60 cases (19 male and 41 female) included in the retrospective cohort. The average age was 42.42 ± 15.51 (range = 18-74). Fifty-one-point six seven percent of subjects were professional voice users (singers, teachers, public speakers, and others). All subjects were diagnosed preoperatively with VF vascular malformations and had undergone pulsed KTP laser photocoagulation. There were 40 bilateral cases and 20 unilateral cases, for a total of 100 VFs included in the study. Vascular malformation recurrence was identified in 3.00% and 10.00% of subjects at the third and fourth postoperative visits, retrospectively. The formation of new vascular malformations was identified in 0.00%, 1.00%, 6.00%, and 7.00% of subjects at postoperative visits 1-4, respectively. CONCLUSION: KTP laser photocoagulation is highly effective for the management of vocal fold vascular lesions. Presence of hemorrhage or edema does not affect the long-term surgical outcome. In relatively few cases, vascular lesion recurrence or formation of new vascular lesions may occur.

Effects of 445-nm Laser on Vessels of Chick Chorioallantoic Membrane with Implications to Microlaryngeal Laser Surgery.

OBJECTIVE: Previous research has shown that effective application of angiolytic lasers in microlaryngeal surgery is determined by wavelength, pulse width (PW), and fluence. Recently, a 445-nm (blue) laser (BL) has been developed with a potentially greater hemoglobin absorption than previous lasers. The chick chorioallantoic membrane (CAM) represents a suitable model for testing various settings to find out the most optimal settings of this laser. This study used the CAM model to examine whether successful photoangiolytic effects could be obtained using BL. METHODS: Seven hundred and ninety three third-order vascular segments of viable CAM were irradiated using BL via 400-µm diameter fiber, 1 pulse/second, with PW and power varied systematically at standardized fiber-to-vessel distances of 1 and 3 mm. Outcome measures including vessel ablation rate (AR), rupture rate (RR), and visible tissue effects were analyzed using Chi-square test. RESULTS: Energy levels of 400, 540, and 600 mJ (per pulse) were most effective for vessel ablation. A working distance of 3 mm resulted in higher ablation and less vessel rupture compared with 1 mm at these optimal energy levels. At 3 mm, a longer PW resulted in higher AR. At 1 mm, AR increased with shorter PW and higher power. The 1-mm working distance resulted in lower tissue effects than 3 mm. CONCLUSION: Findings in this study showed that BL was effective in vessel ablation using relevant combination of working distance, PW, and energy levels. To obtain high AR, longer working distance plus longer PW was required and if working distance was reduced, shorter PW should be set. LEVEL OF EVIDENCE: NA Laryngoscope, 131:E1950-E1956, 2021.

Value of pre- and intraoperative diagnostic methods in suspected glottic neoplasia.

PURPOSE: To evaluate the individual and combined ability of videostroboscopy (VS), high-speed digital imaging (HSDI), enhanced endoscopy (EE) and saline infusion (SI) to predict neoplasia, defined as glottic precursor lesion (GPL) or T1a glottic cancer, in patients suspected for glottic neoplasia. METHODS: A nationwide prospective cohort study of patients treated by cordectomy for suspected GPL or T1a glottic cancer from August 1st 2016 to October 31st 2018 was conducted in the five Danish University Departments of Head and Neck surgery. Sensitivity, specificity, negative and positive predictive values, and area under Receiver Operating Curves (AUC-ROC) were calculated with 95% confidence intervals with respect to the histological diagnosis. Logistic regression with an imputation model for missing data was applied. RESULTS: 261 patients aged 34-91 years participated; 79 (30.3%) with non-neoplasia (i.e., inflammation, papilloma, hyperkeratosis) and 182 (69.7%) neoplasia, hereof 95 (36.4%) with GPL and 87 (33.3%) with T1a glottic cancer. Data from 188 VS, 60 HSDI, 100 preoperative EE, 209 intraoperative EE, and 234 SI were analyzed. In the complete case analysis the AUC-ROC of each diagnostic test was low, but increased when the tests were combined and especially if the combination included EE. However, multinomial logistic regression with imputation showed significant association (p < 0.05) only between age, male gender, and perpendicular vasculature in intraoperative EE, and the endpoint neoplasia. CONCLUSIONS: Intraoperative EE was the most accurate diagnostic method in detecting neoplasia. The prediction ability of methods applied preoperatively was more limited, but improved when test modalities were combined.

Microvascular density and hypoxia-inducible factor in intraepithelial vocal fold lesions.

OBJECTIVE: The promotion of neovascularisation is a crucial aspect of carcinogenesis. The study evaluates the microvascular density (MVD) and expression of hypoxia-induced factor (HIF-1α) in hypertrophic vocal fold (VF) lesions of different histopathological states including non-dysplastic, low-grade, high-grade dysplasia and invasive glottic cancer. MATERIALS AND METHODS: Histological specimens collected from patients diagnosed and treated in a single centre with different histological grades were immunohistochemically stained with CD31, CD34 and HIF-1α. Of the total number of 77 analysed VF specimens, 20 were non-dysplastic, 20 had low-grade dysplasia, 17 high-grade dysplasia and 20 were invasive cancers. RESULTS: The highest mean value for MVD evaluated with expression of CD31 (MVD CD31) was 21.23 ± 14.46 and identified in the low-grade dysplasia group. The average MVD CD31 was 13.74 ± 5.56 and 20.11 ± 9.28 in the high-grade dysplasia and invasive cancer group, respectively. The highest MVD evaluated with CD34 (MVD CD34) was revealed for invasive cancer 35.64 ± 17.21. The MVD CD34 was higher for low-grade than in high-grade dysplasia (25.87 ± 12.30 vs 24.65 ± 15.92, respectively). The expression of HIF-1α was strong or very strong in 60% of non-dysplastic lesions, 100% of low-grade dysplasia cases, 53% of high-grade dysplasia cases and 50% of invasive cancer cases. The comparison of MVD CD31 with MVD CD34 revealed a strong positive correlation (ρ value 0.727). The comparison of both MVD CD31 and MVD CD34 with HIF-1α resulted in no linear relationship (ρ value of 0.143 and 0.165, respectively). CONCLUSION: The stage of low-grade dysplasia in intraepithelial vocal fold lesions is related to significant advancement of angiogenesis together with the highest hypoxia level.

Visible Vessels of Vocal Folds: Can they have a Diagnostic Role?

BACKGROUND: Challenges in visual identification of laryngeal disorders lead researchers to investigate new opportunities to help clinical examination. This paper presents an efficient and simple method which extracts and assesses blood vessels on vocal fold tissue in order to serve medical diagnosis. METHODS: The proposed vessel segmentation approach has been designed in order to overcome difficulties raised by design specifications of videolaryngostroboscopy and anatomic structure of vocal fold vasculature. The limited number of medical studies on vocal fold vasculature point out that the direction of blood vessels and amount of vasculature are discriminative features for vocal fold disorders. Therefore, we extracted the features of vessels on the basis of these studies. We represent vessels as vascular vectors and suggest a vector field based measurement that quantifies the orientation pattern of blood vessels towards vocal fold pathologies. RESULTS: In order to demonstrate the relationship between vessel structure and vocal fold disorders, we performed classification of vocal fold disorders by using only vessel features. A binary tree of Support Vector Machine (SVM) has been exploited for classification. Average recall of proposed vessel extraction method was calculated as 0.82 while healthy, sulcus vocalis, laryngitis classification accuracy of 0.75 was achieved. CONCLUSION: Obtained success rates showed the efficiency of vocal fold vessels in serving as an indicator of laryngeal diseases.

Pericytes in the Human Vocal Fold Mucosa.

1. The human vocal fold is a vibrating tissue and vascular structures in organs which have the capacity to vibrate require a specific structure suitable for vibration. 2. The structure of the blood vessels is unique at the vocal fold edge as a vibrating tissue, where only small vessels, including arterioles, venules, and capillaries, are present. The capillaries are distributed in the superficial layer of the lamina propria (Reinke's space). 3. The blood vessels enter the vocal fold edge from the anterior or posterior end of the membranous vocal fold and run essentially parallel to the vocal fold edge. 4. Many pericytes can be seen around the capillaries in the human vocal fold mucosa. The cell bodies of the pericytes attach to capillary endothelial cells, and the branching processes encircle the capillaries and attach to the capillary endothelial cells at the tips. The processes of pericytes are in close contact with endothelial cells, sharing a common basement membrane with them. The tips of the processes form intercellular tight junctions with endothelial cells. 5. The pericytes in the vocal fold mucosa appear to provide mechanical support and protection to the capillary walls, particularly during phonation. The pericytes also appear to regulate the diameter of the capillary during and after phonation. Pericytes are also thought to be critical cells in vascular biology and angiogenesis, especially in revascularization following vocal fold tissue injury. 6. At birth, pericytes have already encircled the capillaries in the newborn vocal fold mucosa. The pericytes appear ready to provide support and protection of the blood vessels just after birth. 7. Vascular structures and their permeability are related to the specific structures and specific diseases of the human vocal fold mucosa as a vibrating tissue.

Permeability and Weibel-Palade Bodies of the Blood Vessels in the Human Vocal Fold Mucosa.

OBJECTIVES: Transendothelial exchange and permeability of the capillaries in Reinke space (the superficial layer of the lamina propria) of the vocal fold mucosa affect physiological and pathological conditions of the human vocal fold mucosa. The mechanism of permeability and Weibel-Palade bodies of the blood vessels in the human vocal fold mucosa were investigated using electron microscopy. STUDY DESIGN: Histologic analysis of the human vocal fold. METHODS: Six normal human vocal folds (three adults and three newborns) obtained from autopsy cases and three human vocal folds with Reinke edema from surgical specimens were investigated under transmission electron microscopy. RESULTS: There were three possible capillary wall transport systems related to the permeability of the blood vessels in the vocal fold mucosa: 1) Fenestra transport, plasma exuded from the capillaries into surrounding tissue via the fenestration with or without a diaphragm; 2) vesicular transport (transcellular transport via vesicles), the use of vesicles to ferry fluid and solutes across endothelial cells; and 3) junctional transport (intercellular transport), molecules passed through intercellular gaps between endothelial cells. Weibel-Palade bodies were present in the cytoplasm of endothelial cells both in adults and newborns. They were present in high numbers in the cytoplasm of endothelial cells, with intercellular transport in the vocal folds with Reinke edema. CONCLUSION: There were three types of mechanisms for the permeability of the blood vessels in the human vocal fold mucosa. Some physiologically active substances, such as histamine produced by Weibel-Palade bodies, may adversely influence the permeability of the blood vessels. LEVEL OF EVIDENCE: NA. Laryngoscope, 2588-2592, 2018.

Menstrual Cycle, Vocal Performance, and Laryngeal Vascular Appearance: An Observational Study on 17 Subjects.

OBJECTIVE: To assess the anatomical and functional features of the vocal folds during different phases of the female menstrual cycle. METHODS: An observational study of 17 healthy fertile female volunteers not using hormonal contraception was carried out. Each volunteer underwent two examinations: first, during the early days of the menstrual cycle when progesterone levels are low (p-depletion), and second, during premenstruation when progesterone levels are high (p-peak). The workup included blood hormone levels, Voice Handicap Index, acoustic analysis, rigid telescopy, stroboscopy, and narrow band imaging. The videos were evaluated by blinded observers. RESULTS: The participants' mean age was 31.7 ± 5.6 (range 23-43). Progesterone levels were 13- to 45-fold higher in p-peak relative to p-depletion. No significant differences were detected in Voice Handicap Index scores, stroboscopic reports, or acoustic analysis between p-peak and p-depletion examinations. Analyzing the rigid telescopy and narrow band imaging videos, the observers tended to estimate the different laryngeal subsites more vascularized during the p-peak examination. Moreover, this tendency was significantly correlated with blood progesterone levels during the p-depletion examinations; the lower the blood progesterone levels were during p-depletion, the higher the probability for the observers to estimate the p-peak examinations more vascularized (P value = 0.024). CONCLUSIONS: Alterations in laryngeal vascular characteristics are evident throughout the menstrual cycle and may suggest increased congestion during premenstrual days. Variations in progesterone levels during the menstrual cycle correlate with laryngeal vascular changes. Hormone-related alterations in vocal folds' vascularity may have a role in the variability of vocal performance in certain women.

Over-vibration induced blood perfusion and vascular permeability changes may lead to vocal edema.

OBJECTIVES/HYPOTHESIS: To observe blood perfusion and vascular permeability changes under varying vibration frequency exposures. STUDY DESIGN: Animal model. METHODS: Blood perfusion was measured using laser Doppler flowmetry in eight rabbit auricular vessels (four rabbits) under nonvibration, and 62.5-Hz/1-mm, 125-Hz/1-mm, and 250-Hz/0.5-mm vibration frequency/amplitude exposures. Another 12 rabbits were randomly divided into vibration only and vibration with histamine groups. After 3 hours of continuous 125-Hz, 1-mm amplitude vibration of the auricle, vascular permeability was analyzed by absorbance of Evans blue-albumin complex. RESULTS: Significantly lower blood perfusion was observed in the vibration group, compared with no vibration exposure controls. Blood perfusion decreased 29 ± 16% as the vibration frequency was increased from 62.5 Hz to 125 Hz with the vibration amplitude constant at 1 mm. When the frequency was increased from 125 Hz to 250 Hz, while the amplitude was decreased from 1 mm to 0.5 mm, blood flow perfusion further decreased 29 ± 29%, and the decline tendency in blood perfusion showed no significant difference (P = .992). Meanwhile, in the vibration with histamine group, vascular permeability of the vibrated ears increased significantly compared to the nonvibrated ears (P = .005). CONCLUSIONS: Overvibration of the vocal folds due to voice overuse or abuse may significantly reduce blood perfusion, and increase vascular permeability in the vocal fold in inflammatory situations, which may lead to the formation of vocal edema. LEVEL OF EVIDENCE: NA Laryngoscope, 127:148-152, 2017.

Objective quantification of the vocal fold vascular pattern: comparison of narrow band imaging and white light endoscopy.

No clinical standard procedure has yet been defined to quantify the vascular pattern of vocal folds. Subjective classification trials have shown a lot of promise. Narrow band imaging (NBI) as an endoscopic imaging tool is useful, because it shows the vascular structure clearer than white light endoscopy (WL) alone. Endoscopic images of 74 human vocal folds (NBI and WL) were semi-automatically evaluated after image processing with respect to pixels of vessels and mucosa by the software MeVisLab. The ratios of vessel/mucosa pixels were compared. Using NBI, more vocal fold vessels are visible compared with WL alone (p = 0.000). There may be a difference between the right and left vocal folds due to the handedness of the examiner (p = 0.033) without any interaction between the method (NBI/WL) and the side (right/left) (p = 0.467). MeVisLab is a suitable tool for the objective quantification of the vessel/mucosa ratio for NBI and WL endoscopic images. NBI is an appropriate endoscopic tool for examination of diseases of vocal folds with changes in the vascular pattern. There is evidence that the handedness of the examiner may have an influence on the quality of the examination between the right and left vocal folds.

Proposal for a descriptive guideline of vascular changes in lesions of the vocal folds by the committee on endoscopic laryngeal imaging of the European Laryngological Society.

In the last decades new endoscopic tools have been developed to improve the diagnostic work-up of vocal fold lesions in addition to normal laryngoscopy, i.e., contact endoscopy, autofluorescence, narrow band imaging and others. Better contrasted and high definition images offer more details of the epithelial and superficial vascular structure of the vocal folds. Following these developments, particular vascular patterns come into focus during laryngoscopy. The present work aims at a systematic pathogenic description of superficial vascular changes of the vocal folds. Additionally, new nomenclature on vascular lesions of the vocal folds will be presented to harmonize the different terms in the literature. Superficial vascular changes can be divided into longitudinal and perpendicular. Unlike longitudinal vascular lesions, e.g., ectasia, meander and change of direction, perpendicular vascular lesions are characterized by different types of vascular loops. They are primarily observed in recurrent respiratory papillomatosis, and in pre-cancerous and cancerous lesions of the vocal folds. These vascular characteristics play a significant role in the differential diagnosis. Among different parameters, e.g., epithelial changes, increase of volume, stiffness of the vocal fold, vascular lesions play an increasing role in the diagnosis of pre- and cancerous lesions.

[Evaluation of a Classification Model of Horizontal Vascular Lesions of the Vocal Folds]. / Evaluation eines Klassifikationsmodells horizontaler Gefäßveränderungen der Stimmlippen.

OBJECTIVE: There exists no valid classification of beginning vascular changes of the vocal folds. We tested an own classification model of visible beginning horizontal vascular changes. MATERIAL AND METHODS: 168 indirect endoscopic pictures (84 white light=WL and 84 Narrow Band Imaging=NBI) of vocal folds were presented to 3 different consultants for classification (graduation normal, slight, moderately, high-grade belonged to the vascular features ectasia, meander, convolute, frequency of the vessels, ramification, change in direction). The self-confidence was declared by the consultants with a numeric rating scale. RESULTS: A classification of beginning vascular changes of the vocal folds is possible, especially of ectasia, meander, convolute, frequency of the vessels, ramification, change in direction (p<0.0001). Significantly more vascular lesions can be detected by NBI than with white light endoscopy alone (p<0.0001). There are no significant differences (p=0.3529) in self-confidence of the classification. But it differs between the consultants highly significant (p<0.0001). The inexperienced classifier shows the highest growth in the learning curve. The intrarater- and interrater-variability differs only slightly between WL and NBI. CONCLUSIONS: Beginning horizontal changes of vocal fold vessels can be classified. Endoscopic NBI-pictures of the vocal folds demonstrate the beginning of vascular changes better compared to endoscopic white light pictures alone. The familiarity and expertise with the classification model and the endoscopic imaging technique affect the self-confidence of the evaluation.

Vocal fold varices and risk of hemorrhage.

OBJECTIVES/HYPOTHESIS: To establish risk of hemorrhage in patients with varices compared to those without, determine additional risk factors, and make evidence-based treatment recommendations. STUDY DESIGN: Retrospective cohort study. METHODS: Patients who were vocal performers presenting for care during a 24-month period were analyzed to determine incidence of hemorrhage. Patients with varices were compared to those without. Demographic information and examination findings (presence, location, character, and size of varices; presence of mucosal lesions or paresis) were analyzed to determine predictors of hemorrhage. RESULTS: A total of 513 patients (60.4% female, mean age 36.6 years ± 13.95 years) were evaluated; 14 patients presenting with hemorrhage were excluded. One hundred and twelve (22.4%) patients had varices; 387 (77.6%) did not. The rate of hemorrhage in patients with varices was 2.68% at 12 months compared to 0.8% in patients without. Cox proportional hazard regression analysis revealed a hazard ratio of 10.1 for patients with varix developing hemorrhage compared to nonvarix patients (P < 0.0001). The incidence rate of hemorrhage was 3.3 cases per 1,000 person-months for varix patients compared to 0.5 cases per 1,000 person-months in the nonvarix group. There was no significant difference in the incidence of paresis, mucosal lesions, location of varix (left or right side; medial or lateral), or varix morphology (pinpoint, linear, lake) between patients who hemorrhaged and those that did not. CONCLUSION: The presence of varices increases the risk of hemorrhage. Varix patients had 10 times the rate of hemorrhage compared to nonvarix patients, although the overall incidence is low. This data may be used to inform treatment of patients with varices. LEVEL OF EVIDENCE: 4. Laryngoscope, 126:1163-1168, 2016.

[Vascular Lesions of Vocal Folds - Part 2: Perpendicular Vascular Lesions]. / Gefäßveränderungen der Stimmlippen - Teil 2: Perpendikuläre Gefäßveränderungen.

The present work aims at a systematic pathogenetic description of perpendicular vascular changes in the vocal folds. Unlike longitudinal vascular changes, like ectasia and meander, perpendicular vascular changes can be observed in bening lesions. They predominantly occur as typical vascular loops in exophytic lesions, especially in recurrent respiratory papillomatosis (RRP), pre-cancerous and cancerous diseases of the larynx and vocal folds. Neoangiogenesis is caused by an epithelial growth stimulus in the early phase of cancerous genesis. In RRP the VVC impress by a single, long vessel loop with a narrow angle turning point in the each single papilla of the papilloma. In pre- and cancerous lesions the vascular loop is located directly underneath the epithelium. During progressive tumor growth, vascular loops develop an increasingly irregular, convoluted, spirally shape. The arrangement of the vascular loops is primarily still symmetrical. In the preliminary stage of tumor development occurs by neoangiogenesis to a microvascular compression. In advanced vocal fold carcinoma the regular vascular vocal fold structure is destroyed. The various stages of tumor growth are also characterized by typical primary epithelial and secondary connective tissue changes. The characteristic triad of vascular, epithelial and connective tissue changes therefore plays an important role in differential diagnosis.

Classification of laryngeal disorders based on shape and vascular defects of vocal folds.

Vocal fold disorders such as laryngitis, vocal nodules, and vocal polyps may cause hoarseness, breathing and swallowing difficulties due to vocal fold malfunction. Despite the fact that state of the art medical imaging techniques help physicians to obtain more detailed information, difficulty in differentiating minor anomalies of vocal folds encourages physicians to research new strategies and technologies to aid the diagnostic process. Recent studies on vocal fold disorders note the potential role of the vascular structure of vocal folds in differential diagnosis of anomalies. However, standards of clinical usage of the blood vessels have not been well established yet due to the lack of objective and comprehensive evaluation of the vascular structure. In this paper, we present a novel approach that categorizes vocal folds into healthy, nodule, polyp, sulcus vocalis, and laryngitis classes exploiting visible blood vessels on the superior surface of vocal folds and shapes of vocal fold edges by using image processing techniques and machine learning methods. We first detected the vocal folds on videolaryngostroboscopy images by using Histogram of Oriented Gradients (HOG) descriptors. Then we examined the shape of vocal fold edges in order to provide features such as size and splay portion of mass lesions. We developed a new vessel centerline extraction procedure that is specialized to the vascular structure of vocal folds. Extracted vessel centerlines were evaluated in order to get vascular features of vocal folds, such as the amount of vessels in the longitudinal and transverse form. During the last step, categorization of vocal folds was performed by a novel binary decision tree architecture, which evaluates features of the vocal fold edge shape and vascular structure. The performance of the proposed system was evaluated by using laryngeal images of 70 patients. Sensitivity of 86%, 94%, 80%, 73%, and 76% were obtained for healthy, polyp, nodule, laryngitis, and sulcus vocalis classes, respectively. These results indicate that visible vessels of vocal folds can act as a prognostic marker for vocal fold pathologies, as well as the vocal fold shape features, and may play a critical role in more effective diagnosis.

[Vascular lesions of vocal folds--part 1: horizontal vascular lesions]. / Gefäßveränderungen der Stimmlippen - Teil 1: Horizontale Gefäßveränderungen.

BACKGROUND: In recent decades, the endoscopic methods and technologies for laryngeal examination have improved so much that not only epithelial changes, but also vascular changes are recognizable at earlier stages. When comparing newer and older literature, the associated increasingly differentiated descriptions of such visible vascular changes of the vocal folds lead to terminological blurring and shifts of meaning. This complicates the technical-scientific discourse. The aim of the present work is a theoretical and conceptual clarification of early vascular changes of vocal folds. RESULTS: Horizontal changes of benigne vascular diseases, e. g. vessel ectasia, meander, increasing number and branching of vessels, change of direction may develop in to manifest vascular lesions, like varicosis, polyps and in case of ruptures to haemorrhages of vocal folds. These beginning and reversible vascular changes, when early detected and discussed basing on etiological knowledge, may lead to more differentiated prognostic statements and adequate therapeutic decisions, e. g. phonosurgery, functional voice therapy, voice hygiene and voice rest. Vertical vascular changes, like vessel loops, occur primarily in laryngeal papilloma, pre-cancerous and cancerous changes of the vocal folds. Already in small cancerous lesions of the vocal folds the vascular architecture is completely destroyed.