Current heart failure disease management and treatment in accredited units from cardiology and internal medicine in Spain.

BACKGROUND AND OBJECTIVES: Heart failure (HF) is a complex disease with high prevalence, incidence and mortality rates leading to high healthcare burden. In Spain, there are multidisciplinary HF units coordinated by cardiology and internal medicine. Our objective is to describe its current organizational model and their adherence to the latest scientific recommendations. MATERIALS AND METHODS: In late 2021, a scientific committee (with cardiology and internal medicine specialists) developed a questionnaire that was sent as an online survey to 110 HF units. 73 from cardiology (accredited by SEC-Excelente) and 37 from internal medicine, (integrated in UMIPIC program). RESULTS: We received 83 answers (75.5% total: 49 from cardiology and 34 from internal medicine). The results showed that HF units are mostly integrated by specialists from cardiology, internal medicine and specialized nurse practitioners (34.9%). Patient characteristics from HF units are widely different when comparing those in cardiology to UMIPIC, being the latter older, more frequently with preserved ejection fraction and higher comorbidity burden. Most HF units (73.5%) currently use a hybrid face-to-face/virtual model to perform patient follow-up. Natriuretic peptides are the biomarkers most commonly used (90%). All four disease-modifying drug classes are mainly implemented at the same time (85%). Only 24% of HF units hold fluent communication with primary care. CONCLUSIONS: Both models from cardiology and internal medicine HF units are complementary, they include specialized nursing, they use hybrid approach for patient follow-up and they display a high adherence to the latest guideline recommendations. Coordination with primary care remains as the major improvement area.

Circulating Insulin-Like Growth Factor I Regulates Its Receptor in the Brain of Male Mice.

The role of IGF-1 and its receptor (IGF-1R) in brain pathology is still unclear. Thus, either reduction of IGF-IR or treatment with IGF-1, two apparently opposite actions, has proven beneficial in brain diseases such as Alzheimer's dementia. A possible explanation of this discrepancy is that IGF-1 down-regulates brain IGF-1R levels, as previously seen in a mouse Alzheimer's dementia model. We now explored whether under normal conditions IGF-1 modulates its receptor. We first observed that in vitro, IGF-1 reduced IGF-1R mRNA levels in all types of brain cells including neurons, astrocytes, microglia, endothelial cells, and oligodendrocytes. IGF-1 also inhibited its own expression in neurons and brain endothelium. Next, we analyzed the in vivo actions of IGF-1. Because serum IGF-1 can enter the brain, we injected mice with IGF-1 ip. As soon as 1 hour after the injection, decreased hippocampal IGF-1 levels were observed, followed by increased IGF-1 and IGF-1R mRNAs 6 hours later. Because environmental enrichment (EE) stimulates the entrance of serum IGF-1 into the brain, we analyzed whether a physiological entrance of IGF-1 also produced changes in brain IGF-1R. Stimulation of IGF-1R by EE triggered a gradual decrease in hippocampal IGF-1 levels. After 6 hours of EE exposure, IGF-1 levels reached a significant decrease in parallel with increased IGF-1R expression. After longer times, IGF-1R mRNA levels returned to baseline. Thus, under nonpathological conditions, IGF-1 regulates brain IGF-1R. Because baseline IGF-1R levels are rapidly restored, a tight control of brain IGF-1R expression seems to operate under physiological conditions.

Loss of serum IGF-I input to the brain as an early biomarker of disease onset in Alzheimer mice.

Circulating insulin-like growth factor I (IGF-I) enters the brain and promotes clearance of amyloid peptides known to accumulate in Alzheimer's disease (AD) brains. Both patients and mouse models of AD show decreased level of circulating IGF-I enter the brain as evidenced by a lower ratio of cerebrospinal fluid/plasma IGF-I. Importantly, in presymptomatic AD mice this reduction is already manifested as a decreased brain input of serum IGF-I in response to environmental enrichment. To explore a potential diagnostic use of this early loss of IGF-I input, we monitored electrocorticogram (ECG) responses to systemic IGF-I in mice. Whereas control mice showed enhanced ECG activity after IGF-I, presymptomatic AD mice showed blunted ECG responses. Because nonhuman primates showed identically enhanced electroencephalogram (EEG) activity in response to systemic IGF-I, loss of the EEG signature of serum IGF-I may be exploited as a disease biomarker in AD patients.