Paula Heinke scite author profile

It is not known how long it takes from the initial neoplastic transformation of a cell to the detection of a tumor, which would be valuable for understanding tumor growth dynamics. Meningiomas show a broad histological, genetic and clinical spectrum, are usually benign and considered slowly growing. There is an intense debate regarding their age and growth pattern and when meningiomas should be resected. We have assessed the age and growth dynamics of 14 patients with meningiomas (WHO grade I: n = 6 with meningothelial and n = 6 with fibrous subtype, as well as n = 2 atypical WHO grade II meningiomas) by combining retrospective birth-dating of cells by analyzing incorporation of nuclear-bomb-test-derived 14C, analysis of cell proliferation, cell density, MRI imaging and mathematical modeling. We provide an integrated model of the growth dynamics of benign meningiomas. The mean age of WHO grade I meningiomas was 22.1 ± 6.5 years, whereas atypical WHO grade II meningiomas originated 1.5 ± 0.1 years prior to surgery (p < 0.01). We conclude that WHO grade I meningiomas are very slowly growing brain tumors, which are resected in average two decades after time of origination.

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Diploid hepatocytes drive physiological liver renewal in adult humans

Heinke¹,

Rost²,

Rode³

et al. 2020

Journal of Hepatology

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Diploid Hepatocytes Drive Physiological Liver Renewal in Adult Humans

et al. 2020

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Diploid hepatocytes drive physiological liver renewal in adult humans

Heinke

Rost

Rode

et al. 2020

Preprint

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SummaryPhysiological liver cell replacement is central to maintaining the organ’s high metabolic activity, although its characteristics are difficult to study in humans. Using retrospective 14C birth dating of cells, we report that human hepatocytes show continuous and lifelong turnover, maintaining the liver a young organ (average age < 3 years). Hepatocyte renewal is highly dependent on the ploidy level. Diploid hepatocytes show an seven-fold higher annual exchange rate than polyploid hepatocytes. These observations support the view that physiological liver cell renewal in humans is mainly dependent on diploid hepatocytes, whereas polyploid cells are compromised in their ability to divide. Moreover, cellular transitions between these two subpopulations are limited, with minimal contribution to the respective other ploidy class under homeostatic conditions. With these findings, we present a new integrated model of homeostatic liver cell generation in humans that provides fundamental insights into liver cell turnover dynamics.

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Paula Heinke

Diploid hepatocytes drive physiological liver renewal in adult humans

Meningioma growth dynamics assessed by radiocarbon retrospective birth dating

Diploid hepatocytes drive physiological liver renewal in adult humans

Diploid Hepatocytes Drive Physiological Liver Renewal in Adult Humans

Diploid hepatocytes drive physiological liver renewal in adult humans

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