La neuroestimulación eléctrica percutánea del dermatoma T7 mejora el perfil glucémico en pacientes obesos y diabéticos tipo 2. Estudio clínico aleatorizado

Effect of Lactobacillus kefiri, in Conjunction with PENS T6 and a Hypocaloric Diet, on Weight Loss, Hypertension and Laboratory Glycemic and Lipid Profile

The pathogenesis of obesity has been linked to alterations in gut microorganisms. The aim of this study was to investigate the effect of Lactobacillus kefiri, together with PENS T6 and a hypocaloric diet, on weight loss, hypertension and laboratory glycemic and lipid profile. A prospective non-randomized study was conducted involving adult patients with a body mass index (BMI) > 30 kg/m2. Patients were divided into two groups: those undergoing PENS-T6 and hypocaloric diet (PENS-Diet Group) and those undergoing the same PENS-T6 scheme and hypocaloric diet, but additionally receiving probiotics including Lactobacillus kefiri (PENS-Diet + L. kefiri Group). Weight loss was assessed at the end of the treatment, and analytical glycemic and lipid profile, and microbiological analysis of feces were performed before and after treatment. The addition of Lactobacillus kefiri to PENS T6 and a low-calorie diet, increases weight loss and further improves the glycemic and lipid profile. L. kefiri also causes a further improvement in obesity-associated dysbiosis, mainly by increasing the muconutritive (Akkermansia muciniphila) and regulatory (Bifidobacterium spp.) microbiome, and the Phylum Bacteroidetes (Prevotella spp.) and decreasing the Firmicutes/Bacteroidetes ratio.

A systematic review on neuromodulation therapies for reducing body weight in patients with obesity

The global prevalence of obesity increases yearly along with a rising demand for efficacious, safe, and accessible treatments. Neuromodulation interventions (i.e., deep brain stimulation [DBS], transcranial magnetic stimulation [TMS], transcranial direct current stimulation [tDCS], percutaneous neurostimulation [PENS], vagus nerve stimulation [VNS], and gastric electrical stimulation [GES]) have been proposed as novel therapies. This systematic review sought to examine the safety and efficacy of neuromodulation therapies in reducing body weight in patients with obesity. Using PRISMA guidelines, we performed a systematic review for studies on neuromodulation for the treatment of obesity, resulting in 60 trials included (7 DBS, 5 TMS, 7 tDCS, 17 PENS and VNS, and 24 GES; a total of 3,042 participants). While promising results have been reported in open label studies, double-blinded randomized clinical trials often did not reach their primary endpoints, with no technique inducing a striking reduction in body weight. Bearing in mind the complexity and multifactorial nature of obesity, it is possible that a single treatment may not be enough for patients to lose or maintain the weight lost at long term.

Metabolic Effect of the Hepatic Branch of the Vagal Nerve in One-Anastomosis Gastric Bypass (OAGB)

BACKGROUND

Bariatric surgery is often performed not only to lose weight, but also to improve obesity-related comorbidities. A certain metabolic effect of the bariatric techniques has been demonstrated, as the improvement or even remission of comorbidities is patent, before having lost a relevant amount of weight. The autonomic innervation of diverse viscera by the vagus nerve has been hypothesized to participate in it. We aimed to evaluate the ponderal and metabolic impact of the preservation of the hepatic branch of the vagus in type 2 diabetic (T2D) patients undergoing one-anastomosis gastric bypass (OAGB).

PATIENTS AND METHODS

We conducted a prospective study on patients with a preoperative diagnosis of morbid obesity and T2D, who underwent an OAGB. Preservation of the hepatic branch of the vagus was carried out in the first 14 patients (Group 1), whereas in another 14 patients it was sectioned. Ponderal and metabolic outcomes were assessed 1 and 2 years after surgery.

RESULTS

The length of the biliary limb was 210 cm in both groups. Postoperative BMI or excess BMI loss was not significantly different between groups. The patients included in Group 1 showed a statistically greater improvement in glycemic and lipid variables.

CONCLUSION

The preservation of the hepatic branch of the vagus in an OAGB leads to more favorable postoperative glycemic and lipid profiles.

Neuromodulation of metabolic functions: from pharmaceuticals to bioelectronics to biocircuits

Neuromodulation of central and peripheral neural circuitry brings together neurobiologists and neural engineers to develop advanced neural interfaces to decode and recapitulate the information encoded in the nervous system. Dysfunctional neuronal networks contribute not only to the pathophysiology of neurological diseases, but also to numerous metabolic disorders. Many regions of the central nervous system (CNS), especially within the hypothalamus, regulate metabolism. Recent evidence has linked obesity and diabetes to hyperactive or dysregulated autonomic nervous system (ANS) activity. Neural regulation of metabolic functions provides access to control pathology through neuromodulation. Metabolism is defined as cellular events that involve catabolic and/or anabolic processes, including control of systemic metabolic functions, as well as cellular signaling pathways, such as cytokine release by immune cells. Therefore, neuromodulation to control metabolic functions can be used to target metabolic diseases, such as diabetes and chronic inflammatory diseases. Better understanding of neurometabolic circuitry will allow for targeted stimulation to modulate metabolic functions. Within the broad category of metabolic functions, cellular signaling, including the production and release of cytokines and other immunological processes, is regulated by both the CNS and ANS. Neural innervations of metabolic (e.g. pancreas) and immunologic (e.g. spleen) organs have been understood for over a century, however, it is only now becoming possible to decode the neuronal information to enable exogenous controls of these systems. Future interventions taking advantage of this progress will enable scientists, engineering and medical doctors to more effectively treat metabolic diseases.