Glycolytic Metabolism of the Tissue Stem Cells in the Maculae Flavae of the Human Vocal Fold

OBJECTIVES

Metabolic programs in the stem cells are essential for maintaining homeostasis and protecting against stem cell aging. There is growing evidence that the tissue stem cells reside in the anterior and posterior maculae flavae of the human vocal fold mucosa. Our previous studies observed that the glycolysis of the cell in the human maculae flavae seems to rely more on anaerobic glycolysis for energy supply in comparison with oxidative phosphorylation. However, previous studies showed only the metabolic enzymes of glycolysis and functional morphology of the mitochondria, therefore, it has not yet been determined whether anaerobic glycolysis actually took place. The purpose of this study is to investigate the glycolytic metabolites of the cells in the maculae flavae of the human vocal fold in vitro.

METHODS

Four normal human vocal folds were used. After extraction of the anterior maculae flavae, cells in the maculae flavae were cultured and proliferated. Glucose transporter-1 was assessed using immunocytochemistry and metabolites of glycolysis (lactate and NADPH) were measured.

RESULTS

The cells in the maculae flavae expressed glucose transporter-1 in the cytoplasm and the cell membranes. In addition, the cultured cells produced lactate (metabolites of anaerobic glycolysis) and NADPH (metabolites of the pentose phosphate pathway).

CONCLUSIONS

The cells in the maculae flavae of the human vocal folds were found to undergo anaerobic glycolysis via the pentose phosphate pathway. This suggests that the cells in the maculae flavae of the human vocal fold have a metabolism that favors the maintenance of stemness and undifferentiated states.

Metabolic Roles of Colony-Forming Tissue Stem Cells in the Maculae Flavae of Newborn Vocal Fold In Vivo

OBJECTIVES

Tissue stem cells in the maculae flavae (a stem cell niche) of the human vocal fold form colonies in vivo like stem cells in vitro. However, the roles of colony-forming aggregated cells in the maculae flavae in vivo have not yet been determined. This study investigated the glycolysis, of the colony-forming aggregated cells in the maculae flavae of the human newborn vocal fold in vivo.

METHODS

Three normal newborn vocal folds were investigated under light microscopy with immunohistochemistry and transmission electron microscopy.

RESULTS

Colony-forming aggregated cells in the newborn maculae flavae strongly expressed glucose transporter-1 and glycolytic enzymes (hexokinase II, glyceraldehyde-3-phosphate dehydrogenase and lactate dehydrogenase A). The colony-forming aggregated cells did not express phosphofructokinase-1 (rate-limiting enzyme of regular glucose metabolism pathway) but expressed glucose-6-phosphate dehydrogenase (rate-limiting enzyme) indicating the cells relied more on the pentose phosphate pathway. The colony-forming aggregated cells' strong expression of lactate dehydrogenase A indicated that they rely more on anaerobic glycolysis in an anaerobic microenvironment. Mitochondrial cristae of the colony-forming aggregated cells in the newborn maculae flavae were sparse. Consequently, the microstructural features of the mitochondria suggested that their metabolic activity and oxidative phosphorylation were low.

CONCLUSIONS

The colony-forming aggregated cells in the maculae flavae of the newborn vocal fold seemed to rely more on anaerobic glycolysis using the pentose phosphate pathway for energy supply in vivo. Microstructural features of the mitochondria and the glycolytic enzyme expression of the colony-forming aggregated cells suggested that the oxidative phosphorylation activity was low. Already at birth, in the anaerobic microenvironment of the macular flavae in vivo, there is likely a complex cross-talk regarding metabolism between the colony-forming aggregated cells along the adhesion machinery and chemical signaling pathways which reduces toxic oxygen species and is favorable to maintaining the stemness and undifferentiated states of the tissue stem cells.

Vascularity in the macula flava of human vocal fold as a stem cell niche

OBJECTIVES

There is growing evidence that the maculae flavae of the human vocal fold are a stem cell niche, which is a microenvironment nurturing tissue stem cells. This study investigated the microenvironment, especially vascularity, in the maculae flavae of the human vocal fold.

METHODS

Three normal human adult, three normal newborn vocal folds obtained from autopsy cases and three surgical specimens of glottic carcinoma were investigated using light and electron microscopy. For scanning electron microscopy, a chemical digestion method (modified sodium hydroxide maceration method) was used to observe the inner 3-dimensional structure of the macula flava.

RESULTS

Capillaries ran around the anterior and posterior maculae flavae in adults and newborns. However, there was no vascularity in the maculae flavae of the vocal fold. The inner 3-dimensional electron microscopic structure of the macula flava showed there were no blood vessels in the maculae flavae of the vocal fold. Glottic carcinoma (squamous cell carcinoma) surrounded and was in contact with the macula flava, however, the carcinoma did not invade the macula flava indicating there was no vascular supply into the macula flava from the surrounding tissue.

CONCLUSIONS

There was no vascularity in the anterior and posterior maculae flavae in the human adult and newborn vocal folds. The present study is consistent with the hypothesis that the hypoxic microenvironment in the maculae flavae of the adult and newborn vocal fold as a stem cell niche is likely favorable to maintaining the stemness and undifferentiated states of the tissue stem cells in the stem cell system.

Three-dimensional fine structures of the maculae flavae of the human vocal fold using correlative light and electron microscopy

Objectives

To analyze various aspects of complex tissue, there is increasing demand to study each sample at different length scales in biology. Correlative light and electron microscopy (CLEM) is the latest technique to correlate two different types of information on the exact same histological area of interest: histology (from light microscopy) and ultrastructure (from electron microscopy). The three-dimensional fine structures of the maculae flavae (MFe) of the human vocal fold were investigated using CLEM.

Methods

Five normal human adult vocal folds as specimens embedded in paraffin, sectioned, and mounted on glass slides with/without a chemical digestion method (modified sodium hydroxide maceration method) were investigated. Observations using CLEM were performed.

Results

The fine structures of cells and extracellular matrices in the MFe and their peripheral regions were able to be observed on the exact same histological area of interest with the light microscope and field emission-scanning electron microscope. Cobblestone-like polygonal cells, vocal fold stellate cell-like cells, and fibroblast-like spindle cells were intermingled in the MFe of the human vocal fold. The extracellular matrices surrounding each three types of cell in the MFe differed, suggesting the cells were different in functional property.

Conclusion

CLEM is a useful technique to observe the three-dimensional fine structures of the human vocal fold mucosa. The results of the present study are consistent with the hypothesis that the cells in the MFe of the human vocal fold have heterogeneity and each three types of cell have different properties.

Glycolysis of Tissue Stem Cells in the Macula Flava of Newborn Vocal Fold

OBJECTIVES

There is growing evidence that the cells in the maculae flavae are tissue stem cells and the maculae flavae are a stem cell niche of the human vocal fold mucosa. This study investigated the metabolic activity, especially glycolysis, of the tissue stem cells in the maculae flavae of the human newborn vocal fold.

METHODS

Three normal human newborn vocal folds obtained from autopsy cases were investigated using immunohistochemistry.

RESULTS

Among the three phenotypes of cells (cobblestone-like polygonal cells, vocal fold stellate cell-like cells and fibroblast-like spindle cells) in the newborn maculae flavae, a small number of cobblestone-like polygonal cells strongly expressed glucose transporter-1. All three phenotypes of cells in the newborn maculae flavae expressed glycolytic enzymes (hexokinase II, glyceraldehyde-3-phosphate dehydrogenase and lactate dehydrogenase A). The cells did not express phosphofructokinase-1 (rate-limiting enzyme of regular glucose metabolism pathway) but sparsely express glucose-6-phosphate dehydrogenase (rate-limiting enzyme) indicating the cells relied more on the pentose phosphate pathway. The cells' expression of lactate dehydrogenase A suggests the maculae flavae of the newborn vocal fold is likely to be an anaerobic microenvironment where cells perform anaerobic glycolysis.

CONCLUSIONS

The present study is consistent with the hypothesis that the tissue stem cells in the maculae flavae of the newborn vocal fold seem to rely more on anaerobic glycolysis, especially by the pentose phosphate pathway, for energy supply. Already at birth, the metabolism of the tissue stem cells in the maculae flavae of the newborn vocal fold is likely to prevent the formation of toxic reactive oxygen species and is likely favorable to maintaining the stemness and undifferentiated states of the tissue stem cells in the stem cell system.

Energy metabolism of cells in the macula flava of the newborn vocal fold from the aspect of mitochondrial microstructure

OBJECTIVE

Cells in the vocal fold of maculae flavae are likely to be tissue stem cells. Energy metabolism of the cells in newborn maculae flavae was investigated from the aspect of mitochondrial microstructure.

METHOD

Five normal newborn vocal folds were investigated under transmission electron microscopy.

RESULTS

Mitochondria consisted of a double membrane bounded body containing matrices and a system of cristae. However, these membranes were ambiguous. In each mitochondrion, the lamellar cristae were sparse. Intercristal space was occupied by a mitochondrial matrix. Some mitochondria had fused to lipid droplets and rough endoplasmic reticulum, and both the mitochondrial outer and inner membranes had incarcerated and disappeared.

CONCLUSION

The features of the mitochondria of the cells in the newborn maculae flavae showed that their metabolic activity and oxidative phosphorylation were low. The metabolism of the cells in the newborn maculae flavae seems to be favourable to maintain the stemness and undifferentiation of the cells.

Distribution of Label-Retaining Cells and their Properties in the Newborn Vocal Fold Mucosa

OBJECTIVES

There is growing evidence that the cells in the maculae flavae (MFe) are candidates for tissue stem cells of the vocal fold mucosa and the MFe are a stem cell niche. Distribution of label-retaining cells and their properties in the postnatal vocal fold mucosa were investigated.

METHODS

Oral administration of bromodeoxyuridine (BrdU) was given to pregnant Sprague-Dawley rats and the label-retaining cells in the postnatal vocal fold mucosa were observed by immunohistochemistry. Immunoreactivity to antibodies directed to Ki-67 was studied to investigate the cell cycle.

RESULTS

At day 1 after birth, BrdU positive cells were identified in the MFe (60.1 ± 1.7%), epithelium (58.7 ± 10.6%) and lamina propria (52.4 ± 7.8%) of the vocal fold mucosa. At day 56 after birth, the number of BrdU positive cells in the epithelium (4.8 ± 2.2%) and lamina propria (32.3 ± 16.5%) were significantly lower compared to day 1 after birth (P < 0.05). However, the number of BrdU positive cells remaining in the MFe was still high (56.2 ± 2.5%). The label-retaining cells were distributed throughout the MFe. Few Ki-67 positive cells were identified in the MFe indicating they were resting cells.

CONCLUSIONS

The results of this study are consistent with the hypothesis that the cells in the postnatal MFe are candidates for tissue stem cells. At birth, these cells are already present in the MFe of the newborn vocal fold and they are likely ready to start the growth and development of the vocal fold mucosa.

Role of colony-forming tissue stem cells in the macula flava of the human vocal fold in vivo

Objectives

Our previous investigations showed that tissue stem cells in the maculae flavae (a stem cell niche) form colonies in vivo like stem cells in vitro. However, the roles of colony-forming cells in the maculae flavae in vivo have not yet been determined.This study investigated the metabolism of the colony-forming tissue stem cells in the maculae flavae of the human adult vocal fold.

Study design

Histologic analysis of the human vocal folds.

Methods

Three normal human adult vocal folds were investigated under transmission electron microscopy and light microscopy including immunohistochemistry.

Results

Mitochondrial cristae of the colony-forming cells in the maculae flavae were sparse. Hence, the microstructural features of the mitochondria suggested that their metabolic activity and oxidative phosphorylation were low. Colony-forming cells strongly expressed glucose transporter-1 and glycolytic enzymes (hexokinase II, glyceraldehyde-3-phosphate dehydrogenase and lactate dehydrogenase A). The colony-forming cells did not express phosphofructokinase-1 but did express glucose-6-phosphate dehydrogenase indicating the cells relied more on the pentose phosphate pathway. Since the colony-forming cells expressed lactate dehydrogenase A, cells seemed to rely more on anaerobic glycolysis in an anaerobic microenvironment.

Conclusions

The present study is consistent with the hypothesis that the colony-forming tissue stem cells in the maculae flavae of the human adult vocal fold seemed to rely more on anaerobic glycolysis using the pentose phosphate pathway for energy supply in vivo. Microstructural features of the mitochondria and expressed glycolytic enzymes of the colony-forming cells in the maculae flavae suggested that the oxidative phosphorylation activity was low.In an anaerobic microenvironment in vivo, there is likely a complex cross-talk regarding the metabolism between the colony-forming aggregated cells along the adhesion machinery and chemical signaling pathways, which reduces toxic oxygen species and is favorable to maintaining the stemness and undifferentiated states of the tissue stem cells.

Level of Evidence

NA.

Glycolytic activity of the tissue stem cells in the macula flava of the human vocal fold

OBJECTIVES

In our previous studies, the features of the mitochondria of tissue stem cells in the maculae flavae of the human vocal fold suggested that their metabolic activity and oxidative phosphorylation was low. This study investigated the metabolic activity, especially glycolysis of the tissue stem cells in the maculae flavae of the human adult vocal fold.

STUDY DESIGN

Histologic analysis of the human vocal folds.

METHODS

Three normal human adult vocal folds obtained from autopsy cases were investigated using immunohistochemistry.

RESULTS

Among the three phenotypes of cells in the human adult maculae flavae, the vocal fold stellate cell-like cells strongly expressed glucose transporter-1. Three phenotypes of cells in the human adult maculae flavae expressed glycolytic enzymes (hexokinase II, glyceraldehyde-3-phosphate dehydrogenase and lactate dehydrogenase A) indicating the tissue stem cells in the maculae flavae relied more on glycolysis. The cells did not express phosphofructokinase-1 but did express glucose-6-phosphate dehydrogenase indicating the cells relied more on the pentose phosphate pathway. The cells expressed lactate dehydrogenase A indicating the maculae flavae of the human adult vocal fold was likely to be an anaerobic microenvironment.

CONCLUSIONS

The present study is consistent with the hypothesis that the tissue stem cells in the maculae flavae of the human vocal fold seem to rely more on anaerobic glycolysis, especially by the pentose phosphate pathway, for energy supply. The metabolism of the tissue stem cells in the maculae flavae of the human adult vocal fold is likely to prevent toxic reaction oxygen species and be favorable to maintaining the stemness and undifferentiated states of the tissue stem cells in the stem cells system.

LEVEL OF EVIDENCE

NA.

Heterogeneity and hierarchy of the tissue stem cells in the human newborn vocal fold mucosa

OBJECTIVES

There is growing evidence that the cells in the maculae flavae (MFe) are tissue stem cells and the MFe are a stem cell niche of the human vocal fold mucosa. Heterogeneity and hierarchy of tissue stem cells in the MFe of newborn vocal fold were investigated in vivo.

STUDY DESIGN

Histologic analysis of the human vocal folds.

METHODS

Five normal human newborn vocal folds were investigated under transmission electron microscopy and light microscopy.

RESULTS

Cobblestone-like polygonal cells, vocal fold stellate cell-like cells, and fibroblast-like spindle cells were intermingled in the newborn MFe in vivo, indicating that the cells in the MFe had heterogeneity. However, cobblestone-like polygonal cells were predominant. Free ribosomes were well developed in the cytoplasm. The cells in some cases formed gap junctions with each other. The cells in some cases were attached to other cells and formed cell junctions with each other. These findings indicated cells in the newborn maculae flavae possessed features of mesenchymal cells (cells in mesenchyme). Colony-forming-unit-like cell aggregate was observed, indicating the cells in the newborn MFe had stemness. The cobblestone-like polygonal cells expressed SSEA-3 (a human pluripotent stem cell marker), indicating they were at the top of a cellular hierarchy in the stem cell system.

CONCLUSIONS

The cells in the MFe of the human newborn vocal fold mucosa had heterogeneity and hierarchy in the stem cell system in vivo. At birth, newborn maculae flavae are ready to start the growth of the vocal fold mucosa as a vibrating tissue.

Cytoskeleton of cells in vocal fold macula flava unphonated for a long period

Cells in the maculae flavae (MFe) are inferred to be involved in the metabolism of extracellular matrices of the human vocal fold mucosa. The latest research has supported the hypothesis that the tension caused by phonation (vocal fold vibration) regulates the behavior of these cells in the MFe of the human vocal fold. Tensile and compressive strains have direct effects on cell morphology and structure including changes in cytoskeletal structure and organization. Cytoskeletons are one of the structures which play a role as mechanoreceptors for the cells. The microstructure of the intermediate filaments and the expression of their proteins were investigated regarding the cells in the MFe of the human vocal fold unphonated over a decade. The adult vocal fold mucosa of a 64-year-old male with cerebral hemorrhage unphonated for 11 years was investigated by immunohistochemistry and electron microscopy. The intermediate filaments in the cytoplasm of the cells had become fewer in number. And the expression of their characteristic proteins (vimentin, desmin, GFAP) was also reduced. The results of this study are consistent with the hypothesis that mechanotransduction caused by vocal fold vibration could possibly be a factor in regulating the function and fate of the cells in the MFe.

Heterogeneity of Stem Cells in the Human Vocal Fold Mucosa

1. There is growing evidence to suggest that the cells in the maculae flavae are tissue stem cells of the human vocal fold and maculae flavae are a candidate for a stem cell niche. 2. The latest research shows that the cells in the human maculae flavae are involved in the metabolism of extracellular matrices that are essential for viscoelasticity in the human vocal fold mucosa as a vibrating tissue and are considered to be important cells in the growth, development, and aging of the human vocal fold mucosa. 3. Recent evidence has indicated that the cells including vocal fold stellate cells in the maculae flavae of the human vocal fold mucosa are a functionally heterogenous population. 4. The cells in the human maculae flavae possess proteins of all three germ layers, indicating that they are undifferentiated and have the ability of multipotency. 5. The cell division in the human adult maculae flavae is reflective of asymmetric self-renewal, and cultured cells form a colony-forming unit. Therefore, the phenomenon gives rise to the strong possibility that the cells in the human maculae flavae are putative stem cells. 6. Recent research has suggested that the cells in the human maculae flavae arise from the differentiation of bone marrow cells via peripheral circulation. 7. Cultured cell populations in the human maculae flavae are roughly divided into three groups by morphological features: cobblestone-like polygonal cells, vocal fold stellate cell-like cells, and fibroblast-like spindle cells. However, at the present state of our investigation, it is difficult to clarify the stem cell system and hierarchy of stem cells in the human maculae flavae. 8. Subpopulations of cells in the maculae flavae proliferate extremely slowly and retain stem cell properties. 9. Tension caused by phonation seems to regulate the behavior and heterogeneity of the cells (mechanical regulation) in the maculae flavae of the human vocal fold. 10. The putative stem cells in the maculae flavae appear to differentiate into other kind of cells in the surrounding tissue.

Metabolic activity of cells in the macula flava of the human vocal fold from the aspect of mitochondrial microstructure

Objectives

There is growing evidence to suggest that the cells in the maculae flavae of the vocal fold mucosa are tissue stem cells of the human vocal fold. This study investigated the metabolic activity of the cells in the maculae flavae of the human vocal fold from the aspect of mitochondrial microstructure.

Study Design

Histologic analysis of the human vocal folds.

Methods

Five normal human adult vocal folds obtained from autopsy cases were investigated under transmission electron microscopy.

Results

Mitochondria were randomly distributed in the cytoplasm of the cells. The morphological features of the mitochondria consisted of a double‐membrane‐bounded body containing matrices and a system of cristae. In each mitochondria, the lamellar cristae were sparse. The intercristal space was occupied by a mitochondrial matrix which contained electron‐dense matrix granules, mitochondrial DNA, and ribonucleoprotein granules. Some mitochondria spread out over or fused to the surface of a lipid droplet in the cytoplasm. In addition, both the mitochondrial outer and inner membranes and the membranes of the lipid droplets had disappeared. Some close association between mitochondria and rough endoplasmic reticulum was present.

Conclusions

The features of the mitochondria of the cells in the maculae flavae of the human vocal fold suggested that their metabolic activity and oxidative phosphorylation were low and that they may have shifted to the utilization of lipids to some extent for their metabolic needs.

Level of Evidence

NA

Differentiation potential of the cells in the macula flava of the human vocal fold mucosa

The latest research suggests cells in the maculae flavae located at both ends of the lamina propria of the human vocal fold mucosa have stemness. This study investigated the differentiation potential of the cells in the maculae flavae of the human vocal fold mucosa. Four normal human adult vocal folds from surgical specimens were used. After extraction of the anterior maculae flavae located at the anterior end of the lamina propria of the human vocal fold mucosa under microscope, the maculae flavae were minced, cultured and proliferated in mesenchymal stem cell growth medium and morphological features were assessed. Cell surface markers were detected using flow cytometry. Cell differentiation into adipogenic, chondrogenic and osteogenic lineages was performed. Cell's differentiation potential was assessed using a human pluripotent stem cell functional identification kit and immunohistochemistry. Subcultured cells formed a colony-forming unit. Subcultured cells expressed CD90, CD105 and CD73 and lacked expression of CD45, CD34, CD11b, CD19 and HLA-DR. They differentiated into adipogenic, chondrogenic and osteogenic lineages. Consequently, the cell features in the maculae flavae meet the minimal criteria defining mesenchymal stromal cells. In addition, subcultured cells differentiated into ectoderm, mesoderm and endoderm and expressed stage-specific embryonic antigen 3 (SSEA-3). The results of this study are consistent with the hypothesis that the cells in the maculae flavae in the lamina propria of the human vocal fold mucosa are putative stem cells.

Distribution of label-retaining cells and their properties in the vocal fold mucosa

Objective

The latest research suggests cells in the maculae flavae (MFe) are putative stem cells of the vocal fold mucosa and the MFe are a candidate for a stem cell niche. Distribution and properties of label-retaining cells (LRCs) in the vocal fold mucosa were investigated.

Study Design

Histologic analysis of the rat vocal folds.

Methods

Oral administration of bromodeoxyuridine (BrdU) was given to rats and the LRCs in the vocal fold mucosa were observed by immunohistochemistry. Immunoreactivity to antibodies directed to BrdU, Ki67, cytokeratin, vimentin, glial fibrillary acidic protein, desmin, Sox17, CD34, CD45, Type I collagen, and CD44 was studied. Extracellular matrices around LRCs were observed by Alcian blue staining and hyaluronidase digestion study.

Results

LRCs were present in the MFe and were resting cells (G0-phase). They expressed epithelium, muscle, neural, and mesenchymal cell-associated intermediate filament proteins, and an endodermal marker, indicating cells in the MFe are undifferentiated and express proteins of all three germ layers. They expressed hematopoietic markers (CD34, CD45) and Type I collagen, which are the major markers of bone marrow derived circulating fibrocytes. The hyaluronan concentration in the MFe was high and the cells in the MFe expressed the surface hyaluronan receptor CD44, indicating that the MFe were a hyaluronan-rich matrix.

Conclusion

LRCs reside in the MFe and MFe had a hyaluronan-rich matrix. The results of this study are consistent with the hypothesis that the cells in the MFe are putative stem cells and the MFe are a candidate for a stem cell niche.

Level of Evidence

N/A.

Characteristics and Responses of Human Vocal Fold Cells in a Vibrational Culture Model

OBJECTIVES/HYPOTHESIS

This study was conducted to provide a vibrational culture model to investigate the effects of mechanical environments on cellular functions, and elucidate physiological characteristics of two different types of cells in vocal folds under static and vibrational conditions.

STUDY DESIGN

In vitro study of human vocal fold fibroblasts (hVFFs) and human macula flava stellate cells (hMF-SCs).

METHODS

hVFFs and hMF-SCs were exposed to a 2-second-on/2-second-off, 205 Hz vibration regime for 4 hours by using a vibrational culture model. We compared cell morphology, cell viability, and gene expression in extracellular matrix-related components, growth factors, and differentiation markers under static and vibratory conditions.

RESULTS

hVFFs and hMF-SCs differed in their morphologies and gene expression levels under static condition. The applied vibration did not induce changes in morphology and viability of either cell type. However, gene expression levels changed in both cell types in response to vibration; in particular, hMF-SCs exhibited a more sensitive response to vibration than that shown by hVFFs.

CONCLUSIONS

The vibrational culture model developed in this study enabled us to investigate the effects of the applied vibration on two types of vocal fold resident cells. As a result, we could demonstrate that hVFFs and hMF-SCs exhibited distinctively different characteristics under vibrational conditions.

LEVEL OF EVIDENCE

NA. Laryngoscope, 128:E258-E264, 2018.

The Macula Flava of the Human Vocal Fold as a Stem Cell Microenvironment

1. There is growing evidence to suggest that the cells in the maculae flavae are tissue stem cells of the human vocal fold and maculae flavae are a candidate for a stem cell niche. 2. The latest research shows that the cells in the human maculae flavae are involved in the metabolism of extracellular matrices that are essential for the viscoelasticity in the human vocal fold mucosa as a vibrating tissue, and considered to be important cells in the growth, development, and aging of the human vocal fold mucosa. 3. The cells in the human maculae flavae possess proteins of all three germ layers, indicating they are undifferentiated and have the ability of multipotency. 4. The cell division in the human adult maculae flavae is reflective of asymmetric self-renewal and cultured cells form a colony-forming unit. Therefore, the phenomenon gives rise to the strong possibility that the cells in the human maculae flavae are tissue stem cells. 5. Recent research suggests that the cells in the human maculae flavae arise from the differentiation of bone marrow cells via peripheral circulation. 6. The hyaluronan concentration in the maculae flavae is high and contains cells which possess hyaluronan receptors, indicating that the maculae flavae are hyaluronan-rich matrix, which is required for a stem cell niche. 7. A proper microenvironment in the maculae flavae of the human vocal fold mucosa is necessary to be effective as a stem cell niche maintaining the stemness of the contained tissue stem cells.

Stem Cell Microenvironments and Beyond

Endogenous stem cells are indispensable to keep tissue homeostasis due to their unique ability to generate more specialized cell types in an organized way depending on the body needs. Precise control over stem cell differentiation is essential for organogenesis and tissue homeostasis. Stem cells reside in specialized microenvironments, also called niches, which maintain them in an undifferentiated and self-renewing state. The cellular and molecular mechanisms of stem cell maintenance are key to the regulation of homeostasis and likely contribute to several disorders when altered during adulthood. Extensive studies in a various tissues have shown the importance of the niche in modulating stem cell behavior, including bone marrow, skin, intestine, skeletal muscle, vocal cord, brain, spinal cord, stomach, esophagus, and others. In recent past, extraordinary advancement has been made in the identification and characterization of stem cell niches using modern state-of-art techniques. This progress lead to the definition of the main cellular components in the microenvironment where stem cells reside and the identification of molecular mechanisms by which stem cell behavior is controlled, revealing key niche signals involved in stem cell regulation. Similar to the ecological niche of an organism, a stem cell niche is exclusive to the specific type of stem cell and guides its dynamics. This book describes the major cellular and molecular components of various stem cells microenvironments in different organs and at distinct pathophysiological conditions, such as cell-cell interactions, extra-cellular matrix proteins, soluble factors, and physical forces. Although several advances have been made in our understanding of the signals that promote stem cell activation or quiescence, several components of the stem cells microenvironment remain unknown due to the complexity of niche composition and its dynamics. Further insights into these cellular and molecular mechanisms will have important implications for our understanding of organ homeostasis and disease. In this book, we present a selected collection of detailed chapters on what we know so far about the stem cell niches in various tissues and under distinct pathophysiological conditions. Twelve chapters written by experts in the field summarize the present knowledge about the physiological function and pathophysiological role of the stem cell regulation by the microenvironment.

Tissue engineering in the larynx and airway

PURPOSE OF REVIEW

Tissue engineering is a rapidly expanding field in medicine and involves regeneration and restoration of many organs, including larynx and the airways. Currently, this is not included in routine practice; however, a number of clinical trials in humans are ongoing or starting. This review will cover publications during the past 2 years and the focus is on larynx and trachea.

RECENT FINDINGS

Recent reports concern the development and investigations of cell therapies, including biological factors such as growth factors which promote healing of damage and increased vascular support of the tissue. A separate section concerns studies of stromal cells and stem cells in tissue engineering. Cell therapies and treatment with biological active factors are often combined with the development of scaffolds to support or reconstruct the soft tissue in the larynx or the cartilages in trachea or larynx. New techniques for scaffold construction, such as 3D printing, are developed. The trend in the recent publications is to combine these methods.

SUMMARY

Recent advances in tissue engineering of the larynx and trachea include the development of cell therapies or treatment with biological active factors often in combination with scaffolds.

Microenvironment of macula flava in the human vocal fold as a stem cell niche

BACKGROUND

There is growing evidence that the cells in the maculae flavae are tissue stem cells of the human vocal fold mucosa, and that the maculae flavae are a candidate for a stem cell niche. The role of microenvironment in the maculae flavae of the human vocal fold mucosa was investigated.

METHOD

Anterior maculae flavae from six surgical specimens were cultured in a mesenchymal stem cell growth medium or a Dulbecco's modified Eagle's medium.

RESULTS

Using mesenchymal stem cell growth medium, the subcultured cells formed a colony-forming unit, and cell division reflected asymmetric self-renewal. This indicates that these cells are mesenchymal stem cells or stromal stem cells in the bone marrow. Using Dulbecco's modified Eagle's medium, the subcultured cells showed symmetric cell division without a colony-forming unit.

CONCLUSION

A proper microenvironment in the maculae flavae of the human vocal fold mucosa is necessary to be effective as a stem cell niche that maintains the stemness of the contained tissue stem cells.

Cell origin in the macula flava of the human newborn vocal fold

BACKGROUND

There is growing evidence to suggest that cells in the maculae flavae are tissue stem cells of the human vocal fold and maculae flavae are a stem cell niche.

METHODS

Three newborn vocal folds were investigated. Immunoreactivity to antibodies directed to cytokeratin, desmin, glial fibrillary acidic protein, vimentin, cluster of differentiation 34, cluster of differentiation 45, collagen type I, telomerase reverse transcriptase, SOX17 and stage-specific embryonic antigen 3 was investigated.

RESULTS

The cells in the newborn maculae flavae expressed haematopoietic markers (cluster of differentiation 34, cluster of differentiation 45) and collagen type I, which are the major makers of bone marrow derived circulating fibrocytes. The cells expressed epithelium, muscle, neural and mesenchymal cell associated proteins, and endodermal marker, indicating that they are undifferentiated and express proteins of all three germ layers. The cells also expressed stage-specific embryonic antigen 3 and telomerase reverse transcriptase.

CONCLUSION

The cells in the newborn maculae flavae are undifferentiated cells arising from the differentiation of bone marrow cells. The results of this study are consistent with the hypothesis that the cells in maculae flavae are tissue stem cells.

Stem cell approaches for vocal fold regeneration

OBJECTIVES/HYPOTHESIS

Current interventions in the management of vocal fold (VF) dysfunction focus on conservative and surgical approaches. However, the complex structure and precise biomechanical properties of the human VF mean that these strategies have their limitations in clinical practice and in some cases offer inadequate levels of success. Regenerative medicine is an exciting development in this field and has the potential to further enhance VF recovery beyond conventional treatments. Our aim in this review is to discuss advances in the field of regenerative medicine; that is, advances in the process of replacing, engineering, or regenerating the VF through utilization of stem cells, with the intention of restoring normal VF structure and function.

DATA SOURCES

English literature (1946-2015) review.

METHODS

We conducted a systematic review of MEDLINE for cases and studies of VF tissue engineering utilizing stem cells.

RESULTS

The three main approaches by which regenerative medicine is currently applied to VF regeneration include cell therapy, scaffold development, and utilization of growth factors.

CONCLUSION

Exciting advances have been made in stem cell biology in recent years, including use of induced pluripotent stem cells. We expect such advances to be translated into the field in the forthcoming years. Laryngoscope, 126:1865-1870, 2016.