Consequences of recurrent hypoglycaemia on brain
function in diabetes
Rory J. McCrimmon
Diabetologia volume 64, pages971–977(2021)
Abstract
The discovery of insulin and its subsequentmassmanufacture transformed the lives of people with type 1 and 2 diabetes. Insulin, however, was a drug with a ‘dark side’. It brought with it the risk of iatrogenic hypoglycaemia. In this short review, the cellular consequences of recurrent hypoglycaemia, with a particular focus on the brain, are discussed. Using the ventromedial hypothalamus as an exemplar, this review highlights how recurrent hypoglycaemia has an impact on the specialised cells in the brain that are critical to the regulation of glucose homeostasis and the counterregulatory response to hypoglycaemia. In these cells, recurrent hypoglycaemia initiates a series of adaptations that ensure that they aremore resilient to subsequent hypoglycaemia, but this leads to impaired hypoglycaemia awareness and a paradoxical increased risk of severe hypoglycaemia. This review also highlights how hypoglycaemia, as an oxidative stressor, may also exacerbate chronic hyperglycaemia-induced increases in oxidative stress and inflammation, leading to damage to vulnerable brain regions (and other end organs) and accelerating cognitive decline. Preclinical research indicates that glucose recovery following hypoglycaemia is considered a period where reactive oxygen species generation and oxidative stress are pronounced and can exacerbate the longer-term consequence of chronic hypoglycaemia. It is proposed that prior glycaemic control, hypoglycaemia and the degree of rebound hyperglycaemia interact synergistically to accelerate oxidative stress and inflammation, which may explain why increased glycaemic variability is now increasingly considered a risk factor for the complications of diabetes.
Some text from the article
Introduction
This year is the centenary of the discovery of insulin by
Frederick Banting and Charles Best in Professor John
Macleod’s department in Toronto (ON, Canada) in the
summer of 1921. There can be little doubt about the impact
of their discovery, which has transformed the lives of millions
of people with both type 1 and 2 diabetes in the 100 years
since. At the same time, it was soon discovered that insulin
therapy was not without risk. Physicians reported that exogenous
insulin, when delivered in excess, led to a low blood
glucose; the ‘hypoglycaemic reaction’. It was also soon apparent
that repeated exposure to low glucose led to, ‘reactions
[that] differ so much from the original ones that patients
became dangerously unaware of their onset’ [1].
Glucose homeostasis is fundamental to survival in most
vertebrate species. As such, we have evolved a number of
counterregulatory mechanisms designed to restore glucose
homeostasis when glucose levels fall below the normal range.
Over the last few decades, we have learnt that, in humans,
there exists an integrated network of specialised glucosesensing
cells, found in certain key parts of the brain and in
the periphery, that are able to monitor and respond to
prevailing glucose levels, as well as integrate glucose homeostasis
with other aspects of whole-body energy status [2, 3].
We also recognise that, in response to recurrent
hypoglycaemia, these specialised glucose-sensing cells adapt,
leading (through mechanisms still not entirely worked out) to
a clinical syndrome called impaired awareness of
hypoglycaemia. Moreover, there is increasing evidence that,
in addition to making individuals susceptible to severe
hypoglycaemia, these adaptations may also have consequences
in terms of end-organ disease. In this short review, I
will briefly discuss the cellular consequences of
hypoglycaemia, focusing on the impact of recurrent
hypoglycaemia in the brain. This will be illustrated by
outlining the ways in which recurrent hypoglycaemia affects
cells in glucose-sensing regions of the brain (leading to
impaired awareness of hypoglycaemia and severe
hypoglycaemia), as well as how recurrent hypoglycaemia
may affect other brain regions, potentially amplifying the
tissue damage that results from chronic hyperglycaemia.
Summary
The value of insulin in the management of diabetes and the
evidence in support of intensive insulin therapy targeting nearnormalisation
of glycaemic control to minimise the micro- and
macrovascular complications of diabetes is overwhelming.
However, hypoglycaemia remains a relatively common adverse
effect of insulin therapy that has consequences for the individual
and their carers. Asides from the immediate cognitive and
emotional impacts of acute hypoglycaemia, impaired
hypoglycaemia awareness is a consequence of repeated exposure
to hypoglycaemia that carries a high risk for severe
hypoglycaemia. Epidemiological and pre-clinical research also
indicates that recurrent hypoglycaemia may exacerbate chronic
hyperglycaemia-induced increases in oxidative stress and
inflammation, leading, in particular, to damage in vulnerable
brain regions and accelerated cognitive decline.
There remain many unanswered questions that hopefully
future research will be able to shed light on. For instance, do
the effects of recurrent hypoglycaemia on specialised glucosesensing
neurons occur through a single signalling defect or
multiple pathways given the complexity of the hypoglycaemic
response? Moreover, is there actually a ‘defect’ in sensing or
are glucose-sensing neurons just less responsive to low
glucose? If the latter, do the major changes specifically occur
in the specialised neuron or in the periphery (e.g., adrenal
gland)? It is also uncertain whether these effects are reversible
in all people through strict hypoglycaemic avoidance or
whether, in some, these may prove irreversible as a consequence
of long-term damage to critical components of this
homeostatic defence mechanism.
When we consider other consequences of recurrent
hypoglycaemia on the brain, we also need clarity on the actual
level of hypoglycaemia that is clinically significant, which
may or may not be 3.0 mmol/l as recently proposed by the
International Hypoglycaemia Study Group [42]. It is also
possible that recurrent hypoglycaemia has consequences in
other metabolically active tissues, such as the heart and
kidney, whereby the interaction between prior glycaemic
control, hypoglycaemia and the degree of rebound
hyperglycaemia may explain why increased glycaemic variability
is considered a risk factor for complications in multiple
organ systems [43].
Supplementary Information The online version contains a slideset of the
figures for download, which is available to authorised
Läs ELA artikeln som pdf 7 sidor free utan lösenord, inkl slideset
https://link.springer.com/article/10.1007/s00125-020-05369-0
Nyhetsinfo
www red DiabetologNytt