An update on the pharmacotherapeutic strategies for the treatment of dysthymic disorder: a systematic review.

INTRODUCTION: Longer treatment times, more comorbidity, more severe impairments in social, psychological, and emotional functioning, increased healthcare use, and more hospitalizations are all factors that are related to dysthymia. Given the significant prevalence of dysthymia (including persistent depressive disorder) worldwide, its comorbidity with several mental disorders, and the detrimental effects of these comorbidities, it is important to conduct a systematic review to compare the effects of pharmacological acute and maintenance treatments for dysthymia with placebo and standard care in the last 10 years, based on the publication of DSM5. AREAS COVERED: This systematic review was performed according to PRISMA guidelines. Databases, including PubMed and Cochrane Central Register of Controlled Trials, were searched to assess the effects of pharmacological acute and maintenance treatments for dysthymia in comparison with placebo and treatment as usual. EXPERT OPINION: Our review shows that SSRIs and SNRIs present efficacy for dysthymia treatment, and L-Acetylcarnitine should be investigated further for this condition in elderly patients. The comparison of antidepressant medication versus placebo showed coherent results based on three studies favoring pharmacotherapy as an effective treatment for participants with dysthymia. However, the scarcity of research on continuation and maintenance therapy in people with dysthymia highlights the need for more primary research.

L-carnitine and Acetyl-L Carnitine: A Possibility for Treating Alterations Induced by Obesity in the Central Nervous System.

Excessive consumption of nutrients, as well as obesity, leads to an inflammatory process, especially in adipose tissue. This inflammation reaches the systemic level and, subsequently, the central nervous system (CNS), which can lead to oxidative stress and mitochondrial dysfunction, resulting in brain damage. Thus, adequate treatment for obesity is necessary, including lifestyle changes (diet adequation and physical activity) and pharmacotherapy. However, these drugs can adversely affect the individual's health. In this sense, searching for new therapeutic alternatives for reestablishing metabolic homeostasis is necessary. L-carnitine (LC) and acetyl-L-carnitine (LAC) have neuroprotective effects against oxidative stress and mitochondrial dysfunction in several conditions, including obesity. Therefore, this study aimed to conduct a narrative review of the literature on the effect of LC and LAC on brain damage caused by obesity, in particular, on mitochondrial dysfunction and oxidative stress. Overall, these findings highlight that LC and LAC may be a promising treatment for recovering REDOX status and mitochondrial dysfunction in the CNS in obesity. Future work should focus on better elucidating the molecular mechanisms behind this treatment.

Potential Therapeutic Role of Carnitine and Acetylcarnitine in Neurological Disorders.

BACKGROUND: Current therapy of neurological disorders has several limitations. Although a high number of drugs are clinically available, several subjects do not achieve full symptomatic remission. In recent years, there has been an increasing interest in the therapeutic potential of L-carnitine (LCAR) and acetyl-L-carnitine (ALCAR) because of the multiplicity of actions they exert in energy metabolism, as antioxidants, neuromodulators and neuroprotectors. They also show excellent safety and tolerability profile. OBJECTIVE: To assess the role of LCAR and ALCAR in neurological disorders. METHODS: A meticulous review of the literature was conducted in order to establish the linkage between LCAR and ALCAR and neurological diseases. RESULTS: LCAR and ALCAR mechanisms and effects were studied for Alzheimer's disease, depression, neuropathic pain, bipolar disorder, Parkinson's disease and epilepsy in the elderly. Both substances exert their actions mainly on primary metabolism, enhancing energy production, through ß-oxidation, and the ammonia elimination via urea cycle promotion. These systemic actions impact positively on the Central Nervous System state, as Ammonia and energy depletion seem to underlie most of the neurotoxic events, such as inflammation, oxidative stress, membrane degeneration, and neurotransmitters disbalances, present in neurological disorders, mainly in the elderly. The impact on bipolar disorder is controversial. LCAR absorption seems to be impaired in the elderly due to the decrease of active transportation; therefore, ALCAR seems to be the more effective option to administer. CONCLUSION: ALCAR emerges as a simple, economical and safe adjuvant option in order to impair the progression of most neurological disorders.

Análise do potencial mutagênico dos esteroides anabólicos androgênicos (EAA) e da l-carnitina mediante o teste do micronúcleo em eritrócitos policromáticos / Analysis of mutagenic potential of the anabolic androgenic steroids (AAS) and l-carnitine by the micronucleus test in polychromatic erythrocytes / Análisis del potencial mutagénico de los esteroides anabólicos androgénicos (EAA) y de la l-carnitina mediante la prueba del micronúcleo en eritrocitos policromáticos

INTRODUÇÃO: Os esteroides anabólicos androgênicos são usados por pessoas que desejam aumentar sua massa muscular para obter um melhor desempenho nos esportes ou melhorar a aparência física. Os EAA são derivados sintéticos da testosterona, capazes de promover a hipertrofia das fibras musculares, aumentando a síntese proteica intracelular. A L-carnitina é um suplemento alimentar empregado para aumentar a produção energética por meio da oxidação de ácidos graxos. Embora haja trabalhos mostrando as propriedades fisiológicas dessas drogas, há poucos estudos sobre o potencial mutagênico das mesmas. OBJETIVOS: Este trabalho avaliou a clastogenicidade e genotoxicidade do decanoato de nandrolona, decanoato de testosterona e da L-carnitina, em diferentes tratamentos, através do teste do micronúcleo em eritrócitos policromáticos de ratos Wistar. MÉTODOS: Os animais foram submetidos a diferentes concentrações e associações de EAA. O controle positivo recebeu ciclofosfamida 50 mg/kg através de injeção intraperitoneal e o controle negativo, 1 ml de soro fisiológico por gavagem. Os ratos foram sacrificados após 36 horas da última aplicação, tendo seus fêmures removidos e a medula óssea extraída. O material foi homogeneizado e centrifugado. O botão de células foi pipetado e transferido para as lâminas, que foram coradas com Giemsa. Foram contados 1.000 eritrócitos policromáticos por animal, observando a frequência de micronúcleos. RESULTADOS: Foi realizado o teste de Kruskal-Wallis, com nível de significância de 5%, que demostrou que o decanoato de nandrolona - três doses de 0,2 mg/kg e 0,6 mg/kg, oito doses de 7,5 mg/kg, L-carnitina - sete doses de 0,4 ml/250g e 1,5 ml/250g, decanoato de testosterona - 28 doses de 0,075 mg/kg, decanoato de nandrolona - oito doses de 7,5 mg/kg associado a L-carnitina 1 ml e decanoato de nandrolona - oito doses de 7,5 mg/kg associado à decanoato de testosterona - oito doses de 7,5 mg/kg apresentaram potencial mutagênico. CONCLUSÃO: Os tratamentos revelaram-se clastogênicos, não sendo indicado como recurso ergogênico.

INTRODUCTION: Anabolic androgenic steroids (AAS) are frequently used by people whose aim to increase muscle mass to obtain a better performance in sports or improve physical appearance. AAS are synthetic derivatives of testosterone, able to promote muscle fibers hypertrophy, increasing intracellular protein synthesis. L-carnitine is a food supplement used to increase energetic production by means of fat acids oxidation. Although there are several works about physiological properties of these drugs, there are few studies about their mutagenic potential. OBJECTIVES: This work evaluated the clastogenicity and genotoxicity of nandrolone decanoate, testosterone decanoate and L-carnitine, in different treatments through the micronucleus test in polychromatic erythrocytes of Wistar rats. METHODS: The animals were submitted to different concentrations and associations of AAS. The positive control received cyclophosphamide 50 mg/kg by intraperitoneal injection and negative control, one ml of saline solution by gavage. The rats were sacrificed after 36 hours of latest application, having the femurs removed and the bone marrow extracted. Material was homogenized and centrifuged. Button cell was pipetted and transferred to slides, which were stained by Giemsa. 1,000 polychromatic erythrocytes were counted per animal, noting the frequency of micronuclei. RESULTS: The Kruskal-Wallis test was performed, with a significance level of 5%, which demonstrated that nandrolone decanoate - three doses of 0,2 mg/kg and 0,6 mg/kg, eight doses of 7,5 mg/kg, L-carnitine - seven doses of 0,4 ml/250 g and 1,5 ml/250 g, testosterone decanoate - 28 doses of 0,075 mg/kg, nandrolone decanoate - eight doses of 7,5 mg/kg associated to L-carnitine and 1 mL and nandrolone decanoate - eight doses of 7,5 mg/kg associated to testosterone decanoate - eight doses of 7,5 mg/kg, showed mutagenic potential. CONCLUSION: The treatments proved to be clastogenic, not being indicated like ergogenic aid.

INTRODUCCIÓN: Los esteroides anabólicos androgénicos son usados por personas que quieren aumentar su masa muscular a fin de obtener un mejor desempeño en los deportes o para mejorar la apariencia física. Los EAA son derivados sintéticos de la testosterona, que pueden causar la hipertrofia de las fibras musculares, aumentando la síntesis proteica intracelular. La L-carnitina es un suplemento alimenticio utilizado para hacer crecer la producción energética por medio de la oxidación de ácidos grasos. Aunque hay trabajos que muestran las propiedades fisiológicas de esos medicamentos, hay pocos estudios sobre el potencial mutagénico de estos. OBJETIVOS: Este trabajo evaluó la clastogenicidad y la genotoxicidad del decanoato de nandrolona, decanoato de testosterona y de la L-carnitina, en diversos tratamientos, mediante la prueba del micronúcleo en eritrocitos policromáticos de ratones Wistar. MÉTODOS: Los animales fueron sometidos a diferentes concentraciones y asociaciones de EAA. El control positivo recibió ciclofosfamida 50 mg/kg a través de inyección intraperitoneal, y el control negativo 1 ml de suero fisiológico por gavaje. Los ratones fueron sacrificados después de 36 horas de la última aplicación, teniendo sus fémures removidos y la médula ósea extraída. El material fue homogeneizado y centrifugado. El botón de células fue tomado con pipetas y transferido para las láminas, a las cuales se les dio color con Giemsa. Fueron contados 1.000 eritrocitos policromáticos por animal, observándose la frecuencia de micronúcleos. RESULTADOS: Se realizó la prueba de Kruskal-Wallis, con nivel de significancia de 5%, la cual demostró que el decanoato de nandrolona - tres dosis de 0,2 mg/kg y 0,6 mg/kg, ocho dosis de 7,5 mg/kg, L-carnitina - siete dosis de 0,4 ml/250g y 1,5 ml/250g, decanoato de testosterona - 28 dosis de 0,075 mg/kg, decanoato de nandrolona - ocho dosis de 7,5 mg/kg asociado a L-carnitina 1 ml y decanoato de nandrolona - ocho dosis de 7,5 mg/kg vinculado al decanoato de testosterona - ocho dosis de 7,5 mg/kg, presentaron potencial mutagénico. CONCLUSIÓN: Los tratamientos se revelaron como siendo clastogénicos, no indicándose como recurso ergogénico.