Organoids show great potential in clinical translational research owing to their intriguing properties to represent a near physiological model for native tissues. However, the dependency of organoid generation on the use of poorly defined matrices has hampered their clinical application. Current organoid culture systems mostly reply on biochemical signals provided by medium compositions and cell-cell interactions to control growth. Recent studies have highlighted the importance of the extracellular matrix (ECM) composition, cell-ECM interactions, and mechanical signals for organoid expansion and differentiation. Thus, several hydrogel systems prepared using natural or synthetic-based materials have been designed to recreate the stem cell niche in vitro, providing biochemical, biophysical, and mechanical signals. In this review, we discuss how recapitulating multiple aspects of the tissue-specific environment through designing and applying matrices could contribute to accelerating the translation of organoid technology from the laboratory to therapeutic and pharmaceutical applications.

Gastrointestinal stromal tumors (GISTs) are the most common mesenchymal tumor of the gastrointestinal tract and occur most frequently in the stomach. The liver is the most common metastatic site of a GIST, and spontaneous rupture of the hepatic metastasis of a malignant gastric GIST is rare. We report the case of a 70-year-old man who presented with sudden right lower quadrant abdominal pain and was diagnosed with a spontaneously ruptured hepatic metastasis of a malignant gastric GIST. The patient was successfully managed with transcatheter arterial embolization of the hepatic artery.
Abdominal Pain ; Aged ; Embolization, Therapeutic ; Gastrointestinal Stromal Tumors* ; Gastrointestinal Tract ; Hemorrhage ; Hepatic Artery ; Humans ; Liver ; Neoplasm Metastasis ; Rupture ; Rupture, Spontaneous ; Stomach

Persistent sciatic artery (PSA), a rare congenital vascular anomaly, increases susceptibility to aneurysms and accounts for 40–61% of the cases. Here, we describe a case of PSA in a 70-yearold man with a history of alcoholic liver cirrhosis. Bilateral complete PSAs were detected incidentally on computed tomography angiography during evaluation for spontaneous intramuscular bleeding in the thigh due to cirrhosis-related coagulopathy. Selective angiography of the left PSA revealed aneurysmal dilatation and thrombotic occlusion of the PSA, which was partially removed with aspiration thrombectomy. Intramuscular bleeding was succesfully managed with empirical embolization of the deep femoral artery.

OBJECTIVES: This study was conducted to investigate the job stress factors, psychosocial stress and their associations in workers engaged in the research and development of vehicles, and according to job role. METHODS: We recruited 4,066 subjects from workers at a research and development center of an automobile company. A total of 2,764 workers answered the questionnaire about socio-demographic factors, health behaviors, work-related factors, subjective labor intensity, KOSS, and SF-PWI. The final analysis included 2,282 male manufacturing and research workers. Univariate analyses and multiple logistic analyses were conducted on the complete questionnaire data to compare the job stress factors, psychosocial stress and their associations between research and manufacturing workers. RESULTS: The adjusted Odds ratios comparing the high risk group to the low risk group regarding PWI group were 2.23(95%CI=1.63-3.04) in "Lack of rewards", 1.64(95%CI=1.20-2.24) in "Interpersonal conflict", 1.59(95%CI=1.15- 2.20) in "Organizational injustice", 1.58(95%CI=1.17-2.14) in "Occupational climate" and 1.43(95%CI=1.05-1.94) in "Job insecurity" among research workers, and 2.46(95%CI=1.59 -3.80) in "Lack of rewards" and 1.94(95%CI=1.17-3.22) in "Organizational injustice" among manufacturing workers. CONCLUSIONS: There are differences in job stress factors between research and manufacturing workers. Further studies and discussions based on quantitative methodology for seeking more fundamental causes of these differences are required to establish job stress intervention plans and policies.
Automobiles ; Health Behavior ; Humans ; Male ; Odds Ratio ; Questionnaires

Eccrine angiomatous hamartoma (EAH) is a benign, uncommon, combined vascular and eccrine malformation. Most cases of this disorder have been single or multiple nodules or plaques that appear red, yellow, blue, violaceous, or skin colored. EAH may be congenital or appear later in childhood; it rarely arises during puberty or adulthood. A 52-year-old female patient visited our department for tender subcutaneous cystic tumor on the right sole with a one month history. Histopathologic examination confirmed EAH. During excisional biopsy procedure, mucinous discharges were observed which were histopathologically diagnosed as ganglion.
Biopsy ; Female ; Foot ; Ganglion Cysts ; Hamartoma ; Humans ; Middle Aged ; Mucins ; Puberty ; Skin

In this study, we aimed to synthesize PAMAMG3 derivatives (PAMAMG3-KRRR and PAMAMG3-HKRRR), using KRRR peptides as a nuclear localization signal and introduced histidine residues into the KRRR-grafted PAMAMG3 for delivering a therapeutic, carcinoma cell-selective apoptosis gene, apoptin into human primary glioma (GBL-14) cells and human dermal fibroblasts. We examined their cytotoxicity and gene expression using luciferase activity and enhanced green fluorescent protein PAMAMG3 derivatives in both cell lines. We treated cells with PAMAMG3 derivative/apoptin complexes and investigated their intracellular distribution using confocal microscopy. The PAMAMG3-KRRR and PAMAMG3-HKRRR dendrimers were found to escape from endolysosomes into the cytosol. The JC-1 assay, glutathione levels, and Annexin V staining results showed that apoptin triggered cell death in GBL-14 cells. Overall, these findings indicated that the PAMAMG3-HKRRR/apoptin complex is a potential candidate for an effective nonviral gene delivery system for brain tumor therapy in vitro.

In this study, we aimed to synthesize PAMAMG3 derivatives (PAMAMG3-KRRR and PAMAMG3-HKRRR), using KRRR peptides as a nuclear localization signal and introduced histidine residues into the KRRR-grafted PAMAMG3 for delivering a therapeutic, carcinoma cell-selective apoptosis gene, apoptin into human primary glioma (GBL-14) cells and human dermal fibroblasts. We examined their cytotoxicity and gene expression using luciferase activity and enhanced green fluorescent protein PAMAMG3 derivatives in both cell lines. We treated cells with PAMAMG3 derivative/apoptin complexes and investigated their intracellular distribution using confocal microscopy. The PAMAMG3-KRRR and PAMAMG3-HKRRR dendrimers were found to escape from endolysosomes into the cytosol. The JC-1 assay, glutathione levels, and Annexin V staining results showed that apoptin triggered cell death in GBL-14 cells. Overall, these findings indicated that the PAMAMG3-HKRRR/apoptin complex is a potential candidate for an effective nonviral gene delivery system for brain tumor therapy in vitro.

BACKGROUND: Direct reprogramming of fibroblasts into chemically induced cardiomyocyte-like cells (CiCMs) through small molecules presents a promising cell source for cardiac regeneration and therapeutic development. However, the contaminating non-cardiomyocytes, primarily unconverted fibroblasts, reduce the effectiveness of CiCMs in various applications. This study investigated a metabolic selection approach using lactate to enrich CiCMs by exploiting the unique metabolic capability of cardiomyocytes to utilize lactate as an alternative energy source. METHODS: Primary mouse embryonic fibroblasts (pMEFs) were reprogrammed into CiCMs and subjected to a glucosedepleted, lactate-supplemented medium for 4 days. Afterward, cell viability was analyzed, and cardiomyocyte efficiency was assessed through the expression of cardiac-specific markers. Additionally, electrophysiological function was evaluated by examining drug-induced responses. RESULTS: The lactate treatment led to a significant decrease in the viability of non-cardiomyocytes (pMEF-LAC), while CiCMs (CiCM-LAC) showed minimal cell death. Specifically, the expression of all cardiac-related markers was increased in CiCM-LAC. Metabolically purified CiCMs exhibited enhanced contractile force and increased contraction frequency compared to non-purified CiCMs, as well as an elevated responsiveness to drugs. CONCLUSION This study demonstrates that lactate-based metabolic selection is an effective and practical approach for enriching CiCMs, offering a cost-effective alternative to other purification methods. The application of this strategy could potentially broaden the accessibility and utility of reprogrammed cardiomyocytes in cardiac regeneration and therapeutic development.

BACKGROUND: Direct reprogramming of fibroblasts into chemically induced cardiomyocyte-like cells (CiCMs) through small molecules presents a promising cell source for cardiac regeneration and therapeutic development. However, the contaminating non-cardiomyocytes, primarily unconverted fibroblasts, reduce the effectiveness of CiCMs in various applications. This study investigated a metabolic selection approach using lactate to enrich CiCMs by exploiting the unique metabolic capability of cardiomyocytes to utilize lactate as an alternative energy source. METHODS: Primary mouse embryonic fibroblasts (pMEFs) were reprogrammed into CiCMs and subjected to a glucosedepleted, lactate-supplemented medium for 4 days. Afterward, cell viability was analyzed, and cardiomyocyte efficiency was assessed through the expression of cardiac-specific markers. Additionally, electrophysiological function was evaluated by examining drug-induced responses. RESULTS: The lactate treatment led to a significant decrease in the viability of non-cardiomyocytes (pMEF-LAC), while CiCMs (CiCM-LAC) showed minimal cell death. Specifically, the expression of all cardiac-related markers was increased in CiCM-LAC. Metabolically purified CiCMs exhibited enhanced contractile force and increased contraction frequency compared to non-purified CiCMs, as well as an elevated responsiveness to drugs. CONCLUSION This study demonstrates that lactate-based metabolic selection is an effective and practical approach for enriching CiCMs, offering a cost-effective alternative to other purification methods. The application of this strategy could potentially broaden the accessibility and utility of reprogrammed cardiomyocytes in cardiac regeneration and therapeutic development.

BACKGROUND: Direct reprogramming of fibroblasts into chemically induced cardiomyocyte-like cells (CiCMs) through small molecules presents a promising cell source for cardiac regeneration and therapeutic development. However, the contaminating non-cardiomyocytes, primarily unconverted fibroblasts, reduce the effectiveness of CiCMs in various applications. This study investigated a metabolic selection approach using lactate to enrich CiCMs by exploiting the unique metabolic capability of cardiomyocytes to utilize lactate as an alternative energy source. METHODS: Primary mouse embryonic fibroblasts (pMEFs) were reprogrammed into CiCMs and subjected to a glucosedepleted, lactate-supplemented medium for 4 days. Afterward, cell viability was analyzed, and cardiomyocyte efficiency was assessed through the expression of cardiac-specific markers. Additionally, electrophysiological function was evaluated by examining drug-induced responses. RESULTS: The lactate treatment led to a significant decrease in the viability of non-cardiomyocytes (pMEF-LAC), while CiCMs (CiCM-LAC) showed minimal cell death. Specifically, the expression of all cardiac-related markers was increased in CiCM-LAC. Metabolically purified CiCMs exhibited enhanced contractile force and increased contraction frequency compared to non-purified CiCMs, as well as an elevated responsiveness to drugs. CONCLUSION This study demonstrates that lactate-based metabolic selection is an effective and practical approach for enriching CiCMs, offering a cost-effective alternative to other purification methods. The application of this strategy could potentially broaden the accessibility and utility of reprogrammed cardiomyocytes in cardiac regeneration and therapeutic development.