Creatine and low-dose lithium supplementation separately alter energy expenditure, body mass, and adipose metabolism for the promotion of thermogenesis.

Nutraceutical approaches to promote adipose tissue thermogenesis may help to prevent obesity onset. Creatine is a critical regulator of adipose metabolic function and low-dose lithium supplementation has been shown to promote adipose thermogenesis. In the present study, we sought to directly compare the two supplements for their effects on adipose metabolism and thermogenesis. We show that both supplements increase daily energy expenditure (EE) and reduce body mass in male Sprague-Dawley rats. Lithium increased brown adipose tissue (BAT) mitochondrial and lipolytic proteins that are associated with thermogenesis, while creatine increased BAT UCP1 and mitochondrial respiration. The BAT thermogenic findings were not observed in females. White adipose tissue and skeletal muscle markers of thermogenesis were unaltered with the supplements. Together, the data show that low-dose lithium and creatine have diverging effects on markers of BAT thermogenesis and that each increase daily EE and lower body mass in a sex-dependent manner.

Development and evaluation of digitally processed Z-contrast imaging: a technological advance in medical imaging.

For the first time in the field of medical imaging, harmonious use of Z-contrast imaging and digital image processing was developed as an analytical imaging tool and demonstrated in studying human and rabbit spermatozoa. The biological information generated is unique to the science of medical imaging. The versatility of its applications is wide as this advance in imaging technology can be applied to any area of medicine involving tissue analysis. Tissue analysis plays a vital role in both medical research and diagnostic patient care. Imaging in the Z-contrast mode of the scanning-transmission electron microscope affords biologists the capability to image tissue in its natural state such that heavy metal fixatives and stains are not used. The digitally processed Z-contrast image is not only devoid of artifacts caused by fluctuating mass-density, topography variations, and the addition of heavy metal contrast agents but also offers a biological blueprint of the atomic weight distribution in the tissue. The varying gray level intensities assigned to each pixel in the resulting image are specific to the average atomic weight differences inherent in the tissue. The advent of complementary Z-contrast imaging and digital image processing and their concomitant research possibilities offers areas of medical care and medical research an invaluable imaging tool.