Whole-organ tissue engineering: Decellularization and recellularization of three-dimensional matrix liver scaffolds

Sabetkish, Shabnam; Kajbafzadeh, Abdol‐Mohammad; Sabetkish, Nastaran; Khorramirouz, Reza; Akbarzadeh, Aram; Ladi‐Seyedian, Seyedeh‐Sanam; Pasalar, Parvin; Orangian, Saghar; Beigi, Reza Seyyed Hossein; Aryan, Zahra; Akbari, Hesam; Tavangar, Seyed Mohammad

doi:10.1002/jbm.a.35291

Cited by 136 publications

(88 citation statements)

References 29 publications

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“…6B, day 7) in agreement with other reports using different sources of hepatocytes. 5,12 An increasing trend in overall HepG2 metabolic activity was observed, and resazurin reduction (and calculated cell number) was significantly higher after 5 ( p = 0.002) and 7 days ( p < 0.001) of perfusion culture compared to 3 days (Fig. 6C).…”

Section: Figmentioning

confidence: 90%

“…Decellularization of livers and kidneys through perfusion of detergent solutions through the vasculature has been well documented 3,4 -with technical feasibility demonstrated using both large animal and humanscale organs [5][6][7][8] as well as small animal organs for repopulation with stem or immature progenitor cells. 7,[9][10][11][12][13] The current challenges and limitations to organ and tissue engineering have shifted to the cellular repopulation phase of tissue development where donor cells are reintroduced into wholeorgan ECM scaffolds; however, very little detail is typically provided describing bioreactor construction despite the identification of specific design features that are critical to optimize scaffold recellularization and overall function.…”

Section: Introductionmentioning

confidence: 99%

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Dual-Purpose Bioreactors to Monitor Noninvasive Physical and Biochemical Markers of Kidney and Liver Scaffold Recellularization

Uzarski

Bijonowski

Wang

et al. 2015

Tissue Engineering Part C: Methods

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Analysis of perfusion-based bioreactors for organ engineering and a detailed evaluation of physical and biochemical parameters that measure dynamic changes within maturing cell-laden scaffolds are critical components of ex vivo tissue development that remain understudied topics in the tissue and organ engineering literature. Intricately designed bioreactors that house developing tissue are critical to properly recapitulate the in vivo environment, deliver nutrients within perfused media, and monitor physiological parameters of tissue development. Herein, we provide an in-depth description and analysis of two dual-purpose perfusion bioreactors that improve upon current bioreactor designs and enable comparative analyses of ex vivo scaffold recellularization strategies and cell growth performance during long-term maintenance culture of engineered kidney or liver tissues. Both bioreactors are effective at maximizing cell seeding of small-animal organ scaffolds and maintaining cell survival in extended culture. We further demonstrate noninvasive monitoring capabilities for tracking dynamic changes within scaffolds as the native cellular component is removed during decellularization and model parenchymal cells are introduced into the scaffold during recellularization and proliferate in maintenance culture. We found that hydrodynamic pressure drop (DP) across the retained scaffold vasculature is a noninvasive measurement of scaffold integrity. We further show that DP, and thus resistance to fluid flow through the scaffold, decreases with cell loss during decellularization and correspondingly increases to near normal values for whole organs following recellularization of the kidney or liver scaffolds. Perfused media may be further sampled in real time to measure soluble biomarkers (e.g., resazurin, albumin, or kidney injury molecule-1) that indicate degree of cellular metabolic activity, synthetic function, or engraftment into the scaffold. Cell growth within bioreactors is validated for primary and immortalized cells, and the design of each bioreactor is scalable to accommodate any three-dimensional scaffold (e.g., synthetic or naturally derived matrix) that contains conduits for nutrient perfusion to deliver media to growing cells and monitor noninvasive parameters during scaffold repopulation, broadening the applicability of these bioreactor systems.

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Section: Figmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Dual-Purpose Bioreactors to Monitor Noninvasive Physical and Biochemical Markers of Kidney and Liver Scaffold Recellularization

Uzarski

Bijonowski

Wang

et al. 2015

Tissue Engineering Part C: Methods

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“…Studies have demonstrated that decellularized matrix based tissue regeneration is feasible for many hollow and parenchyma organs, such as bladder, 8 skin, 9 blood vessels, 10 heart, 11 lung, 12 kidney, 13 as well as liver. 14 Nonetheless, potential clinical application of DLM-based HLT may be plagued by the selection of scaffold source, considering that human derived DLM is also insufficient, and the application of xenogeneic DLM is hindered by potential risks of zoonosis and immunological rejection. Herein, in order to expand the scaffold donor pool, we have established the decellularized spleen matrix (DSM), which had homogeneous ECM with DLM, and presented comparable condition for hepatocyte cultivation.…”

Section: Introductionmentioning

confidence: 99%

Decellularized spleen matrix for reengineering functional hepatic-like tissue based on bone marrow mesenchymal stem cells

et al. 2016

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“…В литературе описаны успешные эксперимен-ты по децеллюляризации целой печени животных: крыс [4], кроликов [5], свиньи [6]. Также описан эксперимент по децеллюляризации левой латераль-ной доли, взятой у пациента с гемангиомой пече-ни [7].…”

Section: Abstract: Liver Decellularization Extracellular Matrix Tunclassified

Technology features of decellularization of human liver fragments as tissue-specific fine-grained matrix for cell-engineering liver construction

Немец

Кирсанова

Басок

et al. 2018

RJTAO

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1 ФГБУ «Национальный медицинский исследовательский центр трансплантологии и искусственных органов имени академика В.И. Шумакова» Минздрава России, Москва, Российская Федерация 2 ФГАОУ ВО «Первый Московский государственный медицинский университет имени И.М. Сеченова» Минздрава России (Сеченовский университет), Москва, Российская Федерация К одной из актуальных задач при создании биоинженерной печени как альтернативы трансплантации донорской печени при лечении терминальных стадий печеночной недостаточности относится поиск матрикса, способного временно выполнять функции внеклеточного матрикса (ВКМ) печени и обеспечи-вать необходимые условия для поддержания жизнеспособности и функциональной эффективности кле-ток. Основным недостатком матриксов из резорбируемых биополимерных материалов является отсутс-твие тканеспецифичности и невозможность воспроизведения уникальной структуры ВКМ печени. Цель настоящей работы состояла в разработке технологии получения децеллюляризированных фрагментов печени с сохранением структурных свойств ее ВКМ. Материалы и методы. Децеллюляризацию меха-нически измельченных фрагментов печени человека проводили в трех сменах буферного раствора (рН = 7,4), содержащего 0,1% додецилсульфата натрия и повышающуюся концентрацию Тритона Х100 (1, 2 и 3% соответственно). Исследовали влияние длительности, условий отмывки (статика, динамика, рота-ционная система, магнитная мешалка) и способов измельчения печени на сохранность структуры ВКМ печени и полноту удаления клеточных элементов и детрита. Срезы децеллюляризованных образцов фрагментов печени окрашивали гематоксилином и эозином, а также методом Массона для выявления соединительно-тканных элементов. Результаты и обсуждение. Методами гистологического анализа по-казано, что оптимальным является режим отмывки фрагментов печени в течение 3 суток при комнатной температуре в статике, сопровождающийся перемешиванием на магнитной мешалке 2-3 раза в сутки в течение 1 ч. Более длительное время или большая кратность режима перемешивания сопровождается увеличением риска нарушения структуры печеночной ткани. Предложен алгоритм предварительного исследования донорской печени человека с целью оптимизации процесса получения децеллюляризи-рованных фрагментов печени. Выводы. Предложен алгоритм оценки пригодности донорской печени человека для децеллюляризации и найдены оптимальные условия получения децеллюляризированных фрагментов печени с сохранением структуры ВКМ печени и полным удалением клеточных элементов и детрита.

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Whole-organ tissue engineering: Decellularization and recellularization of three-dimensional matrix liver scaffolds

Cited by 136 publications

References 29 publications

Dual-Purpose Bioreactors to Monitor Noninvasive Physical and Biochemical Markers of Kidney and Liver Scaffold Recellularization

Dual-Purpose Bioreactors to Monitor Noninvasive Physical and Biochemical Markers of Kidney and Liver Scaffold Recellularization

Decellularized spleen matrix for reengineering functional hepatic-like tissue based on bone marrow mesenchymal stem cells

Technology features of decellularization of human liver fragments as tissue-specific fine-grained matrix for cell-engineering liver construction

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