Tracheal regeneration is very challenging clinical demand because the trachea is not a simple windpipe, but a multilayered, complex structure. The tissue-engineering technique is widely accepted as promising strategy in tracheal regeneration. For successful regeneration, a substitute for trachea should provide not only appropriate laterally rigidity and longitudinally flexibility for sustaining the luminal shape of the trachea, but also favorable environment for respiratory ciliated epithelium, smooth muscle and blood vessel cells to regenerate. To date, a variety of materials such as polyglycolic acid, poly (lactic-co-glycolic acid), polycarprolactone, nanocomposite polymers and many naturally-derived scaffolds have been investigated. With these investigations, several clinical attempt of tracheal replacement with artificial trachea have been tried, but clinical outcome has not been quite satisfying. This article reviews the regeneration of C-shaped cartilage, respiratory ciliated epithelium and neovascularization of artificial trachea, together with the difficulties, plausible options and future perspectives.
Blood Vessels ; Cartilage ; Epithelium ; Muscle, Smooth ; Nanocomposites ; Phenobarbital ; Pliability ; Polyglycolic Acid ; Polymers ; Regeneration* ; Regenerative Medicine ; Stem Cells ; Tissue Engineering ; Trachea

Three-dimensional (3D) printing is one of the most effective scaffold manufacturing techniques which might revolutionize the realm of tissue engineering and regenerative medicine. The scaffolds, one of the major elements of tissue engineering, along with growth factors and cells, are still one of the most promising approaches for developing organ regeneration. However, the applications of 3D-printed hard scaffolds might have limitations due to their poor surface properties, which play a crucial role in cell recruitment and infiltration, tissue-scaffold integration, and anti-inflammatory properties. Various prerequisites have been suggested for clinical applications of 3D-printed substitute for human body. Consequently, continuous amendment has been made to modify the surface properties, porosities and mechanical properties of these scaffolds. The techniques that modify the surfaces through chemical and material modifications can also be applied to facilitate the efficacy of these scaffolds. In this review, we summarized the characteristics of 3D printing technology and discuss the development direction of the latest 3D printing technology toward meeting the unmet needs in the clinic.

Three-dimensional (3D) printing is one of the most effective scaffold manufacturing techniques which might revolutionize the realm of tissue engineering and regenerative medicine. The scaffolds, one of the major elements of tissue engineering, along with growth factors and cells, are still one of the most promising approaches for developing organ regeneration. However, the applications of 3D-printed hard scaffolds might have limitations due to their poor surface properties, which play a crucial role in cell recruitment and infiltration, tissue-scaffold integration, and anti-inflammatory properties. Various prerequisites have been suggested for clinical applications of 3D-printed substitute for human body. Consequently, continuous amendment has been made to modify the surface properties, porosities and mechanical properties of these scaffolds. The techniques that modify the surfaces through chemical and material modifications can also be applied to facilitate the efficacy of these scaffolds. In this review, we summarized the characteristics of 3D printing technology and discuss the development direction of the latest 3D printing technology toward meeting the unmet needs in the clinic.

Three-dimensional (3D) printing is one of the most effective scaffold manufacturing techniques which might revolutionize the realm of tissue engineering and regenerative medicine. The scaffolds, one of the major elements of tissue engineering, along with growth factors and cells, are still one of the most promising approaches for developing organ regeneration. However, the applications of 3D-printed hard scaffolds might have limitations due to their poor surface properties, which play a crucial role in cell recruitment and infiltration, tissue-scaffold integration, and anti-inflammatory properties. Various prerequisites have been suggested for clinical applications of 3D-printed substitute for human body. Consequently, continuous amendment has been made to modify the surface properties, porosities and mechanical properties of these scaffolds. The techniques that modify the surfaces through chemical and material modifications can also be applied to facilitate the efficacy of these scaffolds. In this review, we summarized the characteristics of 3D printing technology and discuss the development direction of the latest 3D printing technology toward meeting the unmet needs in the clinic.

Three-dimensional (3D) printing is one of the most effective scaffold manufacturing techniques which might revolutionize the realm of tissue engineering and regenerative medicine. The scaffolds, one of the major elements of tissue engineering, along with growth factors and cells, are still one of the most promising approaches for developing organ regeneration. However, the applications of 3D-printed hard scaffolds might have limitations due to their poor surface properties, which play a crucial role in cell recruitment and infiltration, tissue-scaffold integration, and anti-inflammatory properties. Various prerequisites have been suggested for clinical applications of 3D-printed substitute for human body. Consequently, continuous amendment has been made to modify the surface properties, porosities and mechanical properties of these scaffolds. The techniques that modify the surfaces through chemical and material modifications can also be applied to facilitate the efficacy of these scaffolds. In this review, we summarized the characteristics of 3D printing technology and discuss the development direction of the latest 3D printing technology toward meeting the unmet needs in the clinic.

Three-dimensional (3D) printing is one of the most effective scaffold manufacturing techniques which might revolutionize the realm of tissue engineering and regenerative medicine. The scaffolds, one of the major elements of tissue engineering, along with growth factors and cells, are still one of the most promising approaches for developing organ regeneration. However, the applications of 3D-printed hard scaffolds might have limitations due to their poor surface properties, which play a crucial role in cell recruitment and infiltration, tissue-scaffold integration, and anti-inflammatory properties. Various prerequisites have been suggested for clinical applications of 3D-printed substitute for human body. Consequently, continuous amendment has been made to modify the surface properties, porosities and mechanical properties of these scaffolds. The techniques that modify the surfaces through chemical and material modifications can also be applied to facilitate the efficacy of these scaffolds. In this review, we summarized the characteristics of 3D printing technology and discuss the development direction of the latest 3D printing technology toward meeting the unmet needs in the clinic.

No abstract available.
Asthma ; Nebulizers and Vaporizers

PURPOSE: The treatment of a clinically node-positive (cN+) neck is important in the management of oral cavity squamous cell carcinoma (OSCC). However, the extent of neck dissection (ND) remains controversial. The purpose of our study was to evaluate whether level IV or V can be excluded in therapeutic ND for cN+ OSCC patients. MATERIALS AND METHODS: We performed a retrospective chart review of 92 patients who underwent a comprehensive or selective ND as a therapeutic treatment of cN+ OSCC from January 1993 to February 2009. RESULTS: The incidence rate of metastasis to level IV or V was 22% (16 of 72) on the ipsilateral neck. Of 67 cases without clinically suspicious nodes at level IV or V, 11 cases (16%, 11 of 67) had pathologically proven lymphatic metastasis to level IV or V. Only a nodal staging above N2b was significantly relevant with the higher rate of level IV or V lymph node metastasis (p=0.025). In this series, selective ND, combined with proper adjuvant therapy, achieved regional control and survival rates comparable to comprehensive ND in patients under the N stage of cN2a OSCC. CONCLUSION: In conclusion, level IV and V patients can avoid recurrence under cN2a OSCC.
Adult ; Aged ; Carcinoma, Squamous Cell/mortality/*pathology/*surgery ; Chemoradiotherapy ; Disease-Free Survival ; Female ; Humans ; Lymphatic Metastasis ; Male ; Middle Aged ; Mouth Neoplasms/mortality/*pathology/*surgery ; Neck/surgery ; *Neck Dissection ; Neoplasm Metastasis ; Radiotherapy, Adjuvant ; Retrospective Studies ; Treatment Outcome

OBJECTIVES: To develop a Korean version of VSSS-82 for measuring the multi-dimensional satisfaction with community-based mental health services in psychiatric patients and to investigate both the reliability and validity of the Korean version. METHODS: The VSSS-82 English version was translated and back-translated with some modification. Data from 68 psychosis patients using community-based mental health services in three Community Mental Health Centers (CMHCs) was collected through a personal interview survey regarding the satisfaction and suitability of service. Variability of satisfaction and internal consistency, discriminant validity, and concurrent validity of the VSSS-82 Korean version were evaluated. RESULTS: A higher number of dissatisfied subjects and significant pairwise differences for the dimensions were found. The Crohnbach's alpha coefficient, a measure of internal consistency, ranged from 0.56 (overall satisfaction) to 0.90 (skills and behavior) and significant differences in satisfaction was found in patients by the self-rated suitability of service. CONCLUSIONS: The VSSS-82 Korean version is a reliable and valid instrument for measuring multi-dimensional satisfaction with community-based mental health service.
Community Mental Health Centers ; Community Mental Health Services ; Humans ; Mental Health Services* ; Mental Health* ; Personal Satisfaction ; Psychotic Disorders ; Questionnaires ; Reproducibility of Results*

The treatment outcome of advanced squamous cell carcinoma involving the head and neck is well known to be dire and usually needs multimodality treatment even including optimal reconstruction after ablative surgery. When a significant area of the soft tissue is resected, reconstruction of oral cavity or pharynx needs to minimize morbidities while achieving adequate functional outcomes. For the better functional outcome, invasive approaching procedures such as lip and jaw splitting, or extensive floor of mouth or pharyngeal muscle ablation should be avoided. Without these surgical procedures, reconstructive surgeons may encounter technical difficulties in flap inset due to deep and narrow space after head and neck cancer resection. In a deep and narrow surgical defect, accurate approximation and suture is extremely difficult. Eventually, repeated flap manipulation and stretch might be inevitable, and even pedicle kinking or injury could happen. Herein, we suggested the “parachute” technique, which was generally used in blood vessels or aortic valve suturing in a narrow surgical field and for avoiding mismatched suture. We applied this “parachute” technique for free-flap inset to head and neck defect, and we herein report our successful outcomes.