Abstract
This paper presents a bioelectrical conception of connective tissue regulation in bone, cartilage, and tendon, as well as other mechanically stressed connective tissues, based on the biological hypothesis of a biosensor and nerve-like signal conducting function of the native collagen fibril in the extracellular matrix. The various levels of existing conceptions of bioelectrical connective tissue regulation as well as some questions of classical connective tissue research (e.g., neutral and acid protease activity) are discussed from this electrophysiological point of view. Part I presented the topic in the form of classical biophysics and physicochemistry. This paper, Part II, makes use of the concept for a discussion of the “living state” of the extracellular matrix, biochemical aspects of acid and neutral protease activity, and nanoelectronic, relativistic, and coherent aspects of connective tissue regulation.