Anatomical basis of fascial plane blocks

Fascial plane blocks (FPBs) are regional anesthesia techniques in which the space (“plane”) between two discrete fascial layers is the target of needle insertion and injection. Analgesia is primarily achieved by local anesthetic spread to nerves traveling within this plane and adjacent tissues. This narrative review discusses key fundamental anatomical concepts relevant to FPBs, with a focus on blocks of the torso. Fascia, in this context, refers to any sheet of connective tissue that encloses or separates muscles and internal organs. The basic composition of fascia is a latticework of collagen fibers filled with a hydrated glycosaminoglycan matrix and infiltrated by adipocytes and fibroblasts; fluid can cross this by diffusion but not bulk flow. The plane between fascial layers is filled with a similar fat-glycosaminoglycan matric and provides gliding and cushioning between structures, as well as a pathway for nerves and vessels. The planes between the various muscle layers of the thorax, abdomen, and paraspinal area close to the thoracic paravertebral space and vertebral canal, are popular targets for ultrasound-guided local anesthetic injection. The pertinent musculofascial anatomy of these regions, together with the nerves involved in somatic and visceral innervation, are summarized. This knowledge will aid not only sonographic identification of landmarks and block performance, but also understanding of the potential pathways and barriers for spread of local anesthetic. It is also critical as the basis for further exploration and refinement of FPBs, with an emphasis on improving their clinical utility, efficacy, and safety.

Optical Imaging of Pancreatic Innervation

At the time of Ivan Pavlov, pancreatic innervation was studied by looking at pancreas secretions in response to electrical stimulation of nerves. Nowadays we have ways to visualize neuronal activity in real time thanks to advances in fluorescent reporters and imaging techniques. We also have very precise optogenetic and pharmacogenetic approaches that allow neuronal manipulations in a very specific manner. These technological advances have been extensively employed for studying the central nervous system and are just beginning to be incorporated for studying visceral innervation. Pancreatic innervation is complex, and the role it plays in physiology and pathophysiology of the organ is still not fully understood. In this review we highlight anatomical aspects of pancreatic innervation, techniques for pancreatic neuronal labeling, and approaches for imaging pancreatic innervation in vitro and in vivo.

Acupuncture for Visceral Pain: Neural Substrates and Potential Mechanisms

Visceral pain is the most common form of pain caused by varied diseases and a major reason for patients to seek medical consultation. Despite much advances, the pathophysiological mechanism is still poorly understood comparing with its somatic counterpart and, as a result, the therapeutic efficacy is usually unsatisfactory. Acupuncture has long been used for the management of numerous disorders in particular pain and visceral pain, characterized by the high therapeutic benefits and low adverse effects. Previous findings suggest that acupuncture depresses pain via activation of a number of neurotransmitters or modulators including opioid peptides, serotonin, norepinephrine, and adenosine centrally and peripherally. It endows us, by advancing the understanding of the role of ion channels and gut microbiota in pain process, with novel perspectives to probe the mechanisms underlying acupuncture analgesia. In this review, after describing the visceral innervation and the relevant afferent pathways, in particular the ion channels in visceral nociception, we propose three principal mechanisms responsible for acupuncture induced benefits on visceral pain. Finally, potential topics are highlighted regarding the future studies in this field.

The abdominal visceral innervation and the emetic reflex: pathways, pharmacology, and plasticity

In recent years the role of the area postrema in the emetic reflex has been predominant and the involvement of the abdominal visceral innervation has tended to be overlooked. This paper attempts to redress the balance reflex by reviewing aspects of the existing literature and complementing this with original studies from the ferret. In view of the widespread use of the ferret in studies of emesis and particularly in the characterization of the antiemetic actions of 5-HT3 receptor antagonist, the opportunity is taken to assess the suitability of this species for studies of emesis. It is concluded that the ferret is sensitive to a wide range of emetic stimuli including intragastric irritants, opiate and dopamine receptor agonists, many cytotoxic drugs, and radiation. For several stimuli it is more sensitive than other species and for radiation on the basis of its ED100 it appears to be the most sensitive of the laboratory animals studied. Using electrical stimulation of the central end of the dorsal vagal trunk in the abdomen in conscious and anaesthetized animals, the vagal afferents were shown to be capable of eliciting emesis. Using lesioning studies an involvement of the vagus in the emetic response to a number of cytotoxic drugs (e.g., cisplatinum, cyclophosphamide, mustine) and radiation was demonstrated, although the magnitude of the effect varied with the different stimuli. An attempt is made to reconcile these observations with previous studies of area postrema ablation. The problems of interpreting the effects of nerve lesions are critically discussed in light of preliminary evidence presented here that there may be a degree of plasticity in the emetic pathway following such lesions. The range of antiemetic effects of 5-HT3 receptor antagonists is reviewed and an attempt is made to identify the site(s) at which these agents act. Results are presented that suggest a link between the vagus and 5-HT3 receptor antagonism. These studies are discussed together with others and lead us to propose that (in the ferret) 5-HT3 receptor antagonists have their main antiemetic effect by acting on vagal afferent terminals in the wall of the upper gut with an additional minor site either in the nucleus tractus solitarius or presynaptically on the vagal afferent terminals in the medulla where binding sites for 5-HT3 receptor ligands have recently been demonstrated in this species.Key words: emesis, visceral nerves, vagus nerve, ferret, plasticity, serotonin antagonists.