Frailty syndrome

Frailty is a common geriatric syndrome that embodies an elevated risk of catastrophic declines in health and function among older adults. Frailty is a condition associated with ageing, and it has been recognized for centuries. As described by Shakespeare in As You Like It, "the sixth age shifts into the lean and slipper’d pantaloon, with spectacles on nose and pouch on side, his youthful hose well sav’d, a world too wide, for his shrunk shank…". The shrunk shank is a result of loss of muscle with aging. It is also a marker of a more widespread syndrome of frailty, with associated weakness, slowing, decreased energy, lower activity, and, when severe, unintended weight loss.

Frailty syndrome
SpecialtyGeriatrics
A walker in the apartment of a senior woman

As a population ages, a central focus of geriatricians and public health practitioners is to understand, and then beneficially intervene on, the factors and processes that put elders at such risk, especially the increased vulnerability to stressors (e.g. extremes of heat and cold, infection, injury, or even changes in medication) that characterizes many older adults.[1]

Epidemiology

Frailty is a common geriatric syndrome. Estimates of frailty's prevalence in older populations may vary according to a number of factors, including the setting in which the prevalence is being estimated – e.g., nursing home (higher prevalence) vs. community (lower prevalence), and the operational definition used for defining frailty. Using the widely used frailty phenotype framework proposed by Fried et al. (2001),[1] prevalence estimates of 7–16% have been reported in non-institutionalized, community-dwelling older adults.

The occurrence of frailty increases incrementally with advancing age, and is more common in older women than men, and among those of lower socio-economic status. Frail older adults are at high risk for major adverse health outcomes, including disability, falls, institutionalization, hospitalization, and mortality.

Epidemiologic research to date has led to the identification of a number of risk factors for frailty, including: (a) chronic diseases, such as cardiovascular disease, diabetes, chronic kidney disease, depression, and cognitive impairment;[2] (b) physiologic impairments, such as activation of inflammation and coagulation systems,[3] anemia,[4][5] atherosclerosis,[6] autonomic dysfunction,[4][7] hormonal abnormalities,[8] obesity,[9] hypovitaminosis D in men,[10] and environment-related factors such as life space and neighborhood characteristics.[11] Advances about potentially modifiable risk factors for frailty now offer the basis for translational research effort aimed at prevention and treatment of frailty in older adults. A recent systematic review found that exercise interventions can increase muscle strength and improve physical function; however, results are inconsistent in frail older adults living in the community.[12]

Theoretical understanding

Recent work on frailty has sought to characterize both the underlying changes in the body and the manifestations that make frailty recognizable. It is well-agreed upon that declines in physiologic reserves and resilience is the essence of being frail.[13] Similarly, scientists agree that the risk of frailty increases with age and with the incidence of diseases. Beyond that, there is now strong evidence to support the theory that the development of frailty involves declines in energy production, energy utilization and repair systems in the body, resulting in declines in the function of many different physiological systems. This decline in multiple systems affects the normal complex adaptive behavior that is essential to health [14] and eventually results in frailty typically manifesting as a syndrome of a constellation of weakness, slowness, reduced activity, low energy and unintended weight loss.[15] When most severe, i.e. when 3 or more of these manifestations are present, the individual is at a high risk of death.

Assessment of geriatric frailty

The syndrome of geriatric frailty is hypothesized to reflect impairments in the regulation of multiple physiologic systems, embodying a lack of resilience to physiologic challenges and thus elevated risk for a range of deleterious endpoints. Generally speaking, the empirical assessment of geriatric frailty in individuals seeks ultimately to capture this or related features, though distinct approaches to such assessment have been developed in the literature (see de Vries et al., 2011 for a comprehensive review).[16]

Two key approaches are discussed below:

Linda Fried / Johns Hopkins Frailty Criteria

A popular approach to the assessment of geriatric frailty encompasses the assessment of five dimensions that are hypothesized to reflect systems whose impaired regulation underlies the syndrome. These five dimensions are:

  • unintentional weight loss,
  • exhaustion,
  • muscle weakness,
  • slowness while walking, and
  • low levels of activity.[1]

Corresponding to these dimensions are five specific criteria indicating adverse functioning, which are implemented using a combination of self-reported and performance-based measures. Those who meet at least three of the criteria are defined as “frail”, while those not matching any of the five criteria are defined as “robust”. Additional work on the construct is done by Bandeen-Roche et al. (2006),[15] though some of the exact criteria and measures differ (see Table 1 in the paper for this contrast). Other studies in the literature have also adopted the general approach of Linda P. Fried et al. (2001)[1] though, again, the exact criteria and their particular measures may vary. This assessment approach was developed and refined by Fried and colleagues at the Johns Hopkins University’s Center on Aging and Health. This Center is home to Johns Hopkins Claude D. Pepper Older Americans Independence Center, which focuses on frailty research.

Rockwood Frailty Index

Another notable approach to the assessment of geriatric frailty (if not also to some degree its conceptualization) is that of Rockwood and Mitnitski (2007)[17] in which frailty is viewed in terms of the number of health "deficits" that are manifest in the individual, leading to a continuous measure of frailty (see Rockwood, Andrew, and Mitnitski (2007)[18] for a contrast of the two approaches). This approach was developed by Dr. Rockwood and colleagues at Dalhousie University.

Four domains of frailty

A four domains of frailty model was proposed in response to an article in the BMJ.[19] This conceptualisation could be viewed as blending the phenotypic and index models. Researchers tested this model for signal in routinely collected hospital data,[20] and then used this signal in the development of a frailty model, finding even predictive capability across 3 outcomes of care.[21] In the care home setting, one study indicated that not all four domains of frailty were routinely assessed in residents, giving evidence to suggest that frailty may still primarily be viewed only in terms of physical health.[22]

SHARE Frailty Index

The SHARE-Frailty Index (SHARE-FI) was originally developed by Romero-Ortuno (2010) (https://bmcgeriatr.biomedcentral.com/articles/10.1186/1471-2318-10-57) and researchers as part of the Survey of Healthy Ageing and Retirement in Europe. It consists of five domains of the frailty phenotype: •Fatigue •Loss of appetite •Grip strength •Functional difficulties •Physical activity

The SHARE-FI calculator is freely available to use online. The calculator classifies individuals as 1) frail; 2) pre-frail; and 3) non-frail / robust. The SHARE-FI has good clinical utility as it provides relatively quick assessment of frailty in often time-poor healthcare settings.

Biological underpinnings

It has been suggested that the biological underpinnings of frailty are multifactorial, involving dysregulation across many physiological systems.[14] A proinflammatory state,[3] sarcopenia,[23] anemia,[4][5] relative deficiencies in anabolic hormones (androgens and growth hormone)[8] and excess exposure to catabolic hormones (cortisol),[24] insulin resistance,[25] glucose levels,[26] compromised altered immune function,[27][28] micronutrient deficiencies and oxidative stress[29] are each individually associated with a higher likelihood of frailty. Additional findings show that the risk of frailty increases with the number of dysregulated physiological systems in a nonlinear pattern, independent of chronic diseases and chronologic age, suggesting synergistic effects of individual abnormalities that on their own may be relatively mild.[14] The clinical implication of this finding is that interventions that affect multiple systems may yield greater, synergistic benefits in prevention and treatment of frailty than interventions that affect only one system.

Associations between specific disease states are also associated with and frailty have also been observed, including cardiovascular disease, diabetes mellitus, chronic kidney disease and other diseases in which inflammation is prominent. To the extent that dysregulation across several physiologic systems underlie the pathogenesis of the frailty, specific disease states are likely concurrent manifestations of the underlying impaired physiologic function and regulation. It is possible that clinically measurable disease states can manifest themselves or be captured prior to the onset of frailty. No single disease state is necessary and sufficient for the pathogenesis of frailty, since many individuals with chronic diseases are not frail. Therefore, rather than being dependent on the presence of measurable diseases, frailty is an expression of a critical mass of physiologic impairments.

Components

Sarcopenia

Sarcopenia (from the Greek meaning "poverty of flesh") is the degenerative loss of skeletal muscle mass, quality, and strength associated with aging.[30] The rate of muscle loss is dependent on exercise level, co-morbidities, nutrition and other factors. Sarcopenia can lead to reduction in functional status and cause significant disability from increased weakness. The muscle loss is related to changes in muscle synthesis signalling pathways although is incompletely understood. The cellular mechanisms are distinct from other types of muscle atrophy such as cachexia, in which muscle is degraded through cytokine-mediated degradation although both conditions may co-exist.[31]

Osteoporosis

Osteoporosis causes a hunched-over appearance in some people.

Osteoporosis is an age-related disease of bone that leads to an increased risk of fracture. In osteoporosis the bone mineral density (BMD) is reduced, bone microarchitecture is disrupted, and the amount and variety of proteins in bone is altered. Osteoporosis is defined by the World Health Organization (WHO) in women as a bone mineral density 2.5 standard deviations below peak bone mass (20-year-old healthy female average) as measured by DXA; the term "established osteoporosis" includes the presence of a fragility fracture.[32]

Osteoporosis is most common in women after menopause, when it is called postmenopausal osteoporosis, but may also develop in men, and may occur in anyone in the presence of particular hormonal disorders and other chronic diseases or as a result of medications, specifically glucocorticoids, when the disease is called steroid- or glucocorticoid-induced osteoporosis (SIOP or GIOP). Given its influence in the risk of fragility fracture, osteoporosis may significantly affect life expectancy and quality of life.

Muscle weakness

Muscle weakness, also known as muscle fatigue, (or "lack of strength") refers to the inability to exert force with one's skeletal muscles. Weakness often follows muscle atrophy and a decrease in activity, such as after a long bout of bedrest as a result of an illness. There is also a gradual onset of muscle weakness as a result of sarcopenia - the age-related loss of skeletal muscle.

Muscle weakness makes it difficult to perform everyday activities, like getting into a bathtub.

A test of strength is often used during a diagnosis of a muscular disorder before the etiology can be identified. Such etiology depends on the type of muscle weakness, which can be true or perceived as well as variable topically. True weakness is substantial, while perceived rather is a sensation of having to put more effort to do the same task.[33] On the other hand, various topic locations for muscle weakness are central, neural and peripheral. Central muscle weakness is an overall exhaustion of the whole body, while peripheral weakness is an exhaustion of individual muscles. Neural weakness is somewhere between.

Healing power

Physical injuries heal slower and are more likely to leave permanent scars in older people.

Aged people recover slower and are lesser likely to completely recover from physical injuries and accidents.[34]

Surgical outcomes

Frail elderly people are at significant risk of post-surgical complications and the need for extended care. Frailty more than doubles the risk of morbidity and mortality from surgery and cardiovascular conditions.[35] Assessment of older patients before elective surgeries can accurately predict the patients' recovery trajectories.[36] The most widely used frailty scale consists of five items:[1]

  • unintentional weight loss >4.5 kg in the past year
  • <20th population centile for grip strength
  • self-reported exhaustion
  • low physical activity such that persons would only rarely undertake a short walk
  • slowed walking speed, defined as lowest population quartile on 4 minute walking test.

A healthy person scores 0; a very frail person scores 5. Compared to non-frail elderly people, people with intermediate frailty scores (2 or 3) are twice as likely to have post-surgical complications, spend 50% more time in the hospital, and are three times as likely to be discharged to a skilled nursing facility instead of to their own homes.[36] Frail elderly patients (score of 4 or 5) have even worse outcomes, with the risk of being discharged to a nursing home rising to twenty times the rate for non-frail elderly people.

See also

References

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  2. Fried LP; Ferrucci L; Darer J; Williamson JD; Anderson G (March 2004). "Untangling the concepts of disability, frailty, and comorbidity: implications for improved targeting and care". J Gerontol A Biol Sci Med Sci. 59 (3): 255–63. PMID 15031310.
  3. Walston, J; McBurnie, MA; Newman, A; Tracy, RP; Kop, WJ; Hirsch, CH; Gottdiener, J; Fried, LP; Cardiovascular Health Study (Nov 2002). "Frailty and activation of the inflammation and coagulation systems with and without clinical comorbidities: results from the Cardiovascular Health Study". Arch Intern Med. 162 (20): 2333–2341. doi:10.1001/archinte.162.20.2333. PMID 12418947.
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