Cellular senescence: from growth arrest to immunogenic conversion

Burton, Dominick G. A.; Faragher, R. G. A.

doi:10.1007/s11357-015-9764-2

Cited by 80 publications

(74 citation statements)

References 163 publications

(141 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Interestingly, cellular senescence can also be induced by stress (Toussaint et al, 2000) and oncogenes (Bartkova et al, 2006), demonstrating that cellular senescence is not only caused by exhaustion of replicative capacity as first thought. Such heterogeneity of cellular senescence, which we will briefly discuss in the next paragraph, has led a field to sometimes unnecessary ambiguity, leaving researchers to disagree what cellular senescence entails (Burton and Faragher, 2015).…”

Section: Aging and Cellular Senescencementioning

confidence: 99%

Biomarkers to identify and isolate senescent cells

Matjusaitis

Chin

Sarnoski

et al. 2016

Ageing Research Reviews

119

108

View full text Add to dashboard Cite

Highlights There is no single biomarker which can robustly identify senescent cells. Widely used senescent cell biomarkers should be used in combination for accuracy. Technologies like tangential flow filtration can be used to isolate senescent cells. Other methods, like senolytic viruses, could be used to remove senescent cells. AbstractAging is the main risk factor for many degenerative diseases and declining health. Senescent To better understand cell aging and to reap the benefits of senescent cell removal, it is necessary to have a reliable biomarker to identify these cells. Following an introduction to cellular senescence, we discuss several classes of biomarkers in the context of their utility in identifying and/or removing senescent cells from tissues. Although senescence can be induced by a variety of stimuli, senescent cells share some characteristics that enable their identification both in vitro and in vivo. Nevertheless, it may prove difficult to identify a single biomarker capable of distinguishing senescence in all cell types. Therefore, this will not be a comprehensive review of all senescence biomarkers but rather an outlook on technologies and markers that are most suitable to identify and isolate senescent cells.

show abstract

Section: Aging and Cellular Senescencementioning

confidence: 99%

Biomarkers to identify and isolate senescent cells

Matjusaitis

Chin

Sarnoski

et al. 2016

Ageing Research Reviews

119

108

View full text Add to dashboard Cite

show abstract

“…HF-related frailty and cardiac cachexia are similar if not the same phenotype [110,111]. In AdHF, tissue wasting and cardiac cachexia have been associated with upregulation of the inflammatory biomarkers IL-1 and IL-6, C-reactive protein and TNF-α [112], T-cell and innate immune cell dysfunction [58,85,113], increased numbers of terminally differentiated T cells [114], immunosenescence and immune exhaustion [115,116].…”

Section: Frailty and Outcomesmentioning

confidence: 99%

A Peripheral Blood Transcriptome Biomarker Test to Diagnose Functional Recovery Potential in Advanced Heart Failure

Deng

2018

Biomark. Med.

View full text Add to dashboard Cite

Heart failure (HF) is a complex clinical syndrome that causes systemic hypoperfusion and failure to meet the body's metabolic demands. In an attempt to compensate, chronic upregulation of the sympathetic nervous system and renin-angiotensin-aldosterone leads to further myocardial injury, HF progression and reduced O 2 delivery. This triggers progressive organ dysfunction, immune system activation and profound metabolic derangements, creating a milieu similar to other chronic systemic diseases and presenting as advanced HF with severely limited prognosis. We hypothesize that 1-year survival in advanced HF is linked to functional recovery potential (FRP), a novel clinical composite parameter that includes HF severity, secondary organ dysfunction, co-morbidities, frailty, disabilities as well as chronological age and that can be diagnosed by a molecular biomarker.

show abstract

“…They are therefore at increased risk for OD and death after MCS or HTx surgery. HF-related preoperative immunologic impairment is a component of poor outcomes after MCS and HTx, owing to the known associations between increased age, T cell and innate immune cell dysfunction (17)(18)(19), increased numbers of terminally differentiated T cells (20), immune-senescence (deficient replicative ability), and immune-exhaustion (impaired antigen response) (21,22).…”

Section: Pathophysiology and Neuro-endocrino-immunology Of Adhfmentioning

confidence: 99%

Current indications for transplantation: stratification of severe heart failure and shared decision-making

Vucicevic¹,

Honoris²,

Raia³

et al. 2018

Ann. Cardiothorac. Surg.

View full text Add to dashboard Cite

Heart failure (HF) is a complex clinical syndrome that results from structural or functional cardiovascular disorders causing a mismatch between demand and supply of oxygenated blood and consecutive failure of the body's organs. For those patients with stage D HF, advanced therapies, such as mechanical circulatory support (MCS) or heart transplantation (HTx), are potentially life-saving options. The role of risk stratification of patients with stage D HF in a value-based healthcare framework is to predict which subset might benefit from advanced HF (AdHF) therapies, to improve outcomes related to the individual patient including mortality, morbidity and patient experience as well as to optimize health care delivery system outcomes such as costeffectiveness. Risk stratification and subsequent outcome prediction as well as therapeutic recommendationmaking need to be based on the comparative survival benefit rationale. A robust model needs to (I) have the power to discriminate (i.e., to correctly risk stratify patients); (II) calibrate (i.e., to show agreement between the predicted and observed risk); (III) to be applicable to the general population; and (IV) provide good external validation. The Seattle Heart Failure Model (SHFM) and the Heart Failure Survival Score (HFSS) are two of the most widely utilized scores. However, outcomes for patients with HF are highly variable which make clinical predictions challenging. Despite our clinical expertise and current prediction tools, the best short-and long-term survival for the individual patient, particularly the sickest patient, is not easy to identify because among the most severely ill, elderly and frail patients, most preoperative prediction tools have the tendency to be imprecise in estimating risk. They should be used as a guide in a clinical encounter grounded in a culture of shared decision-making, with the expert healthcare professional team as consultants and the patient as an empowered decision-maker in a trustful safe therapeutic relationship.

show abstract

Cellular senescence: from growth arrest to immunogenic conversion

Cited by 80 publications

References 163 publications

Biomarkers to identify and isolate senescent cells

Biomarkers to identify and isolate senescent cells

A Peripheral Blood Transcriptome Biomarker Test to Diagnose Functional Recovery Potential in Advanced Heart Failure

Current indications for transplantation: stratification of severe heart failure and shared decision-making

Contact Info

Product

Resources

About