Cultivo tridimensional de tejido adiposo termogénico vascularizado a partir de fragmentos microvasculares
Summary
Aquí, presentamos un protocolo detallado que describe el uso de fragmentos microvasculares aislados de tejido graso humano o de roedores como un enfoque directo para diseñar tejido adiposo beige vascularizado funcional.
Abstract
La ingeniería de tejido adiposo termogénico (por ejemplo, tejidos adiposos beige o marrones) se ha investigado como una terapia potencial para enfermedades metabólicas o para el diseño de microtejidos personalizados para la detección de la salud y las pruebas de drogas. Las estrategias actuales son a menudo bastante complejas y no logran representar con precisión las propiedades multicelulares y funcionales del tejido adiposo termogénico. Los fragmentos microvasculares, pequeños microvasos intactos compuestos por arteriolas, vénulas y capilares aislados del tejido adiposo, sirven como una única fuente autóloga de células que permiten la vascularización y la formación de tejido adiposo. Este artículo describe métodos para optimizar las condiciones de cultivo para permitir la generación de tejidos adiposos termogénicos tridimensionales, vascularizados y funcionales a partir de fragmentos microvasculares, incluidos los protocolos para aislar fragmentos microvasculares del tejido adiposo y las condiciones de cultivo. Además, se discuten las mejores prácticas, al igual que las técnicas para caracterizar los tejidos diseñados, y se proporcionan resultados de muestras de fragmentos microvasculares humanos y de roedores. Este enfoque tiene el potencial de ser utilizado para la comprensión y el desarrollo de tratamientos para la obesidad y las enfermedades metabólicas.
Introduction
El objetivo de este protocolo es describir un enfoque para desarrollar tejido adiposo beige vascularizado a partir de una sola fuente potencialmente autóloga, fragmento microvascular (MVF). Se ha demostrado que los tejidos adiposos marrones y beige muestran propiedades beneficiosas relacionadas con la regulación metabólica; Sin embargo, el pequeño volumen de estos depósitos de tejido adiposo en adultos limita el impacto potencial sobre el metabolismo sistémico, particularmente en condiciones enfermas como la obesidad o la diabetes tipo 2 1,2,3,4,5,6,7. Existe un interés significativo en la grasa marrón/beige como diana terapéutica para prevenir los efectos metabólicos nocivos relacionados con la obesidad y sus comorbilidades 8,9,10,11,12.
Los MVF son estructuras de vasos que pueden aislarse directamente del tejido adiposo, cultivarse y mantenerse en una configuración tridimensional durante largos períodos de tiempo13,14,15. Trabajos previos de nuestro grupo, y otros, han comenzado a explotar la capacidad multicelular y multipotente de los MVF, específicamente en lo que se refiere a la formación de tejido adiposo16,17,18. Como preparación de este trabajo, recientemente demostramos que los MVF derivados de modelos de roedores de diabetes sana y tipo 219 y de sujetos humanos (adultos mayores de 50 años)20 contenían células capaces de ser inducidas a formar tejido adiposo termogénico o beige.
Aquí se trata de un enfoque innovador a partir del cual se utiliza una MVF de una sola fuente, no sólo capaz de crear tejido adiposo beige sino también su componente vascular asociado y crítico21. El uso de esta técnica podría ser de gran valor para los estudios que buscan un enfoque directo de ingeniería tisular para la formación de tejido adiposo termogénico. A diferencia de otros métodos que aspiran a diseñar tejido adiposo beige 22,23,24,25,26,27,28, el proceso descrito en este estudio no requiere el uso de múltiples tipos de células o regímenes de inducción complejos. Se pueden crear modelos vascularizados de color beige y grasa blanca con MVF procedentes de roedores y fuentes humanas, lo que demuestra un gran potencial de traducción. El producto final de este protocolo es un tejido graso termogénico beige diseñado con una estructura y función metabólica comparable al tejido adiposo marrón. En general, este protocolo presenta la idea de que una MVF de fuente fácilmente accesible y posiblemente autóloga puede ser una intervención terapéutica y una herramienta que vale la pena para estudiar los trastornos metabólicos.
Protocol
Representative Results
Discussion
El campo de la ingeniería de tejidos adiposos marrones/beige es en gran medida inmaduro 22,23,24,25,26,27,28, con la mayor parte de los modelos adiposos desarrollados para el tejido adiposo blanco 8,22,31<sup…
Declarações
The authors have nothing to disclose.
Acknowledgements
El Dr. Acosta cuenta con el apoyo de las subvenciones CA148724 y TL1TR002647 de los Institutos Nacionales de Salud. El Dr. González Porras cuenta con el apoyo del Instituto Nacional de Diabetes y Enfermedades Digestivas y Renales de los Institutos Nacionales de Salud, bajo el número de adjudicación F32-0DK122754. Este trabajo fue apoyado, en parte, por los Institutos Nacionales de Salud (5SC1DK122578) y el Departamento de Ingeniería Biomédica de la Universidad de Texas en San Antonio. El contenido es responsabilidad exclusiva de los autores y no representa necesariamente los puntos de vista oficiales de los Institutos Nacionales de Salud. Las figuras fueron creadas parcialmente con Biorender.com.
Materials
| Aminocaproic Acid | Sigma Aldrich | A2504-100G | Added in DMEM at the concentration of 1 mg/mL |
| Blunt-Tipped Scissors | Fisher scientific | 12-000-172 | Sterilize in autoclave |
| Bovin Serum Albumin (BSA) | Millipore | 126575-10GM | Diluted in PBS to 4 mg/mL and 1 mg/mL |
| Collagenase Type 1 | Fisher scientific | NC9633623 | Diluted to 6 mg/mL in BSA 4 mg/mL, Digestion of minced fat |
| Dexamethasone | Thermo Scientific | AC230302500 | Diluted in ethanol at a 2 mg/ml stock concentration |
| Disposable underpads | Fisher scientific | 23-666-062 | For fluid absorption during surgery |
| Dissecting Scissors | Fisher scientific | 08-951-5 | Sterilize in autoclave |
| Dulbecco′s Modified Eagle′s Medium (DMEM) | Fisher scientific | 11885092 | |
| Dulbecco′s Modified Eagle′s Medium/Nutrient Mixture F-12 Ham (DMEM/F12) | Sigma Aldrich | D8062 | |
| Fetal Bovine Serum | Fisher scientific | 16140089 | Added in DMEM to 20% v/v. |
| Fibrinogen | Sigma Aldrich | F8630-25G | Solubilized in DMEM at the concentration of 20 mg/mL, Protein found in blood plasma and main component of hydrogel |
| Flask, 250 mL | Fisher scientific | FB500250 | Allows for digestion of fat using a large surface area |
| Forceps | Fisher scientific | 50-264-21 | Sterilize in autoclave, For handling of tissue and filters |
| Forskolin | Sigma Aldrich | F6886 | Diluted in ethanol at a 10 mM stock concentration |
| Human MVF | Advanced Solutions Life Scienes, LLC | https://www.advancedsolutions.com/microvessels | Human MVFs (hMVFs) isolated from three different patients (52-, 54-, and 56-year old females) were used in the current study. |
| Indomethacine | Sigma Aldrich | I7378 | Diluted in ethanol at a 12.5 mM stock concentration |
| Insulin from porcine pancreas | Sigma Aldrich | I5523 | Diluted in 0.01 N HCl at a 5 mg/ml stock concentration |
| MycoZap | Fisher scientific | NC9023832 | Added in DMEM to 0.2% w/v, Mycoplasma Prophylactic |
| Pennycilin/Streptomycin (10,000 U/mL) | Fisher scientific | 15140122 | Added in DMEM to 1% v/v. |
| Petri dishes, polystyrene (100 mm x 15 mm). | Fisher scientific | 351029 | 3 for removal of blood vessels and mincing, 8 (lid) for presoaking of screens & 8 (dish) for use when filtering with 500 or 37 µM screens |
| Petri dishes, polystyrene (35 mm x 10 mm). | Fisher scientific | 50-202-036 | For counting fragments |
| Phosphate Buffer Saline (PBS) | Fisher scientific | 14-190-250 | Diluted to 1x with sterile deionized water. |
| Rat Clippers (Andwin Mini Arco Pet Trimmer) | Fisher scientific | NC0854141 | |
| Rosiglitazone | Fisher scientific | R0106200MG | Diluted in DMSO at a 10 mM stock concentration |
| Scissors | Fine Science Tools | 14059-11 | 1 for initial incision, 1 for epididymal incision, 1 for tip clipping |
| Screen 37 µM | Carolina Biological Supply Company | 652222R | Cut into 3" rounded squares and sterilized in ethylene oxide, Fragment entrapment and removal of very small fragments/single cells and debris |
| Screen 500 µM | Carolina Biological Supply Company | 652222F | Cut into 3" rounded squares and sterilized in ethylene oxide, Removes larger fragments/debris |
| Serrated Hemostat | Fisher scientific | 12-000-171 | Sterilize in autoclave, For clamping of skin before incision |
| Steriflip Filter 0.22 μm | Millipore | SE1M179M6 | |
| Thrombin | Fisher scientific | 6051601KU | Diluted in deionzed water to 10 U/mL, Used as a clotting agent turning fibrinogen to fibrin |
| Thyroid hormone (T3) | Sigma Aldrich | T2877 | Diluted in 1N NaOH at a 0.02 mM stock concentration |
| Zucker diabetic fatty (ZDF) rats – obese (FA/FA) or lean (FA/+) male | Charles River | https://www.criver.com/products-services/find-model/zdf-rat-lean-fa?region=3611 https://www.criver.com/products-services/find-model/zdf-rat-obese?region=3611 |
Obtained from Charles River (Wilmington, MA). Rats were acquired at 4 weeks of age and fed Purina 5008 until euthanasia (15-19 weeks of age). Glucose levels (blood from the lateral saphenous vein) were greater than 300 mg/dL in all FA/FA rats used in the study. All animals were housed in a temperature-controlled environment with a 12-h light-dark cycle and fed ad libitum. |
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