SGLT-2 Inhibitors in Type 1 Diabetes Mellitus: A Comprehensive Review of the Literature.

BACKGROUND: Sodium-Glucose Cotransporter 2 (SGTL-2) inhibitors are a new class of antidiabetics, which have been approved for the treatment of patients with Type 2 Diabetes Mellitus (T2DM). Besides their beneficial metabolic effects, they exert favourable results in cardiovascular events and risk factors along with renoprotection. However, SGLT-2 inhibitors have not been yet approved as an adjunct therapy to insulin in patients with Type 1 Diabetes Mellitus (T1DM). This review aims at presenting both clinical and experimental data that reinforce the role of SGLT-2 inhibitors as adjunctive treatment in patients with T1DM along with the main restrictions of their use, namely Diabetic Ketoacidosis (DKA). METHODS: We conducted a comprehensive research of the relevant literature regarding the off-label use of SGLT-2 inhibitors in clinical practice, presenting the major benefits and the potential risks. RESULTS: SGLT-2 inhibitors are associated with improved glycemic control, reduction in body weight, and decrease in insulin dosage, along with their beneficial cardiovascular and renal effects. However, we cannot overlook the association with increased incidence of DKA events, in the presence of well known predisposing factors. Further investigation is required, in order to establish them as adjunctive treatment in those patients. CONCLUSION: This novel class of antidiabetics seems to be a very attractive treatment option in patients with T1DM, due to their multiple beneficial effects, but the increased risk of DKA should be taken into account.

Imunoproteção de ilhotas pancreáticas microencapsuladas em biomateriais inovadores e seu potencial terapêutico no diabetes mellitus tipo 1 / Immunoprotection of pancreatic islets microencapsulated in inovative biomaterials and its therapeutic potential in type 1 Diabetes Mellitus

O transplante de ilhotas microencapsuladas constitui uma alternativa terapêutica interessante para o Diabetes Mellitus tipo 1, permitindo um melhor controle glicêmico e eliminando a necessidade de imunossupressão. Entretanto, a manutenção a longo prazo da viabilidade das células-β ainda é um desafio. No isolamento, a perda da matriz extracelular e as condições hipóxicas subsequentes afetam decisivamente a sobrevivência e funcionalidade das ilhotas. Objetivo Para diminuir o estresse sobre o enxerto, levando a um sucesso prolongado do transplante, propôs-se a adição de perfluorocarbono (PFC) ou laminina (LN), moléculas associadas respectivamente à oxigenação e interações célula-célula, ao biomaterial baseado em alginato, Biodritina, adequado ao encapsulamento celular. Metodologia Para testar a estabilidade das formulações PFC-Biodritina e LN-Biodritina, microcápsulas foram submetidas a diferentes estresses (rotacional, osmótico, temperatura e cultura) por 7 e 30 dias. A pureza do biomaterial foi avaliada pela coincubação com macrófagos murinos RAW264.7, por 3, 9 e 24h, quando a ativação dos macrófagos foi observada pela expressão gênica de IL- 1β e TNFα. Microcápsulas implantadas i.p. em camundongos foram recuperadas após 7 ou 30 dias, para análises de biocompatibilidade. A expressão de níveis de mRNA (bax, bad, bcl-2, bcl-XL, xiap, caspase 3, mcp1/ccl2, hsp70, ldh, insulina 1 e 2), proteínas (Bax, Bcl-XL e Xiap) e a atividade de Caspase3 foram avaliadas em ilhotas microencapsuladas com PFC- e LN-Biodritina, após cultura de 48h em condições de normóxia e hipóxia (<2% O2). Camundongos diabéticos foram transplantados com ilhotas encapsuladas nas diferentes formulações e os animais foram monitorados pelas variações de massa corporal, glicêmicas e pela funcionalidade do enxerto (TOTGs). As ilhotas foram recuperadas de animais normo ou hiperglicêmicos e uma análise de biocompatibilidade das cápsulas foi realizada, assim como a avaliação funcional das células-β...

Transplantation of microencapsulated islets represents an attractive therapeutical approach to treat type 1 Diabetes Mellitus, accounting for an improved glycemic control and the abolishment of immunosuppressive therapies. However, maintenance of long-term β-cell viability remains a major problem. During islet isolation, the loss of extracellular matrix interactions and the hypoxic conditions thereafter dramatically affect β-cell survival and function. Objective To lessen the burden of islet stress and achieve a better outcome in islet transplantation we tested the addition of perfluorocarbon (PFC) or laminin (LN), molecules associated respectively with oxygenation and cell-cell interaction, to Biodritin, an alginate-based material suitable for cell microencapsulation. Methodology To test the stability of PFC-Biodritin and LN-Biodritin composites, microcapsules were subjected to different stresses (rotational, osmotic, temperature and culture) for 7 and 30 days. To assess biomaterial purity microcapsules were co-incubated with RAW264.7 murine macrophage cell line for 3, 9 and 24h and macrophage activation was detected through mRNA levels of IL-1β and TNFα. Microcapsules were implanted i.p. in mice and retrieved after 7 or 30 days, for biocompatibility analyses. Gene expression at mRNA (bax, bad, bcl-2, bcl-XL, xiap, caspase 3, mcp1/ccl2, hsp70, ldh, insulin 1 and 2) and protein (Bax, Bcl-XL and Xiap) levels, together with Caspase3 activity, were evaluated in islets microencapsulated in PFC- or LN-Biodritin, upon culturing for 48h in normoxic or hypoxic (<2% O2) conditions. Diabetic mice were transplanted with PFC- or LN-Biodritin microencapsulated islets, followed by assessments of body weight, glycemia and graft function by oral glucose tolerance tests (OGTTs). Microencapsulated islets were retrieved from normoglycemic or hyperglycemic mice and biocompatibility analyses of the beads together with a functional assessment of the graft followed. After graft...