In the most widely recognized natural history model for type 1 diabetes, there is a presumption that all individuals begin life with the same number of beta cells. In combination with this, a consensus exists that the so-called “normal” adult pancreas possesses approximately one million islet cells. These concepts have drawn little attention or question over time as much of the research interest in terms of the disorder’s natural history has focused on genetic susceptibility and the trigger period, where the beta cells begin a process of linear loss. However, a limited body of largely unnoticed data draws question to the notions of a normal pancreas as well as the number of islets and/or beta-cells that may be resident, both in early life through adulthood, in humans.

We (in association with Dr. Martha Campbell Thompson and Dr. John Kaddis) recently published data (JAMA, 2012) involving nPOD tissues suggesting that the pancreas of individuals with type 1 diabetes is smaller, consistent with other studies over the previous two decades. But, until recently, the observation drew little investigator attention. Moving away from pancreatic size, the situation becomes even more intellectually diffuse when one considers quantification of islet and/or beta-cell numbers. In studies of pancreatic development in both humans and rodents, it appears that a wave of beta-cell death occurs as a normal physiological process following birth. The implications for this process may influence T1D’s pathogenesis in at least two ways. First is how it might influence T1D relates to the initiation of autoimmunity. A second notion as being of equivalent if not an even greater potential relates to the aforementioned concept of “100%”. We believe it conceivable that a major and yet highly unappreciated risk factor for T1D resides in the number of beta-cells present in early life. Taken collectively, these findings support a hypothesis that immune and perhaps non-autoimmune mechanisms (e.g., developmental, environmental, genetic, etc.) influence a loss of beta-cell mass as well as loss of pancreatic mass in T1D, possibly even before full-blown disease; thus, forming clear objectives for our studies.

Type 1 diabetes patients often exhibit exocrine insufficiency (REF), however, it remains unclear whether these alterations result from disrupted islet-acinar interactions secondary to the loss of functional β-cell mass or contribute directly to type 1 diabetes development. Thus, as a basis for a better understanding of pancreatic exocrine function, we propose to investigate the expression pattern of major digestive enzymes in the pancreas of nondiabetic, autoantibody positive without diabetes and T1 diabetes nPOD donors. This will be achieved by multiplex immunohistochemical staining for amylase, lipase and trypsinogen (amongst others) and by employing fresh tissue slicing technique to obtain functional readouts of pancreatic endocrine and exocrine cell function .