Background: Pancreatic cancer is the fourth leading cause of cancer-related death.

Only about 6% of patients are alive 5 years after diagnosis. One reason for this

low survival rate is that most patients are diagnosed at a late stage, when the tumor

has spread to surrounding tissues or distant organs. Less than 20% of cases are

diagnosed at an early stage that allows them to undergo potentially curative

surgery. However, even for patients with a tumor that has been surgically

removed, local and systemic recurrence is common and the median survival is

only 17-23 months. This underscores the importance to identify factors that can

predict postresection survival. With technical advances and centralization of care,

pancreatic surgery has become a safe procedure. The future optimal treatment for

pancreatic cancer is dependent on increased understanding of tumor biology and

development of individualized and systemic treatment. Previous experimental

studies have reported that mucins, especially the MUC4 mucin, may confer

resistance to the chemotherapeutic agent gemcitabine and may serve as targets for

the development of novel types of intervention.



Aim: The aim of the thesis was to investigate strategies to improve management of

pancreatic cancer, with special reference to early detection, prognostic factors, and

treatment.



Methods: In paper I, 27 prospectively collected serum samples from resectable

pancreatic cancer (n=9), benign pancreatic disease (n=9), and healthy controls

(n=9) were analyzed by high definition mass spectrometry (HDMSE). In paper II,

an artificial neural network (ANN) model was constructed on 84 pancreatic cancer

patients undergoing surgical resection. In paper III, we investigated the effects of

transition from a low- to a high volume-center for pancreaticoduodenectomy in

221 patients. In paper IV, the grade of concordance in terms of MUC4 expression

was examined in 17 tissue sections from primary pancreatic cancer and matched

lymph node metastases. In paper V, pancreatic xenograft tumors were generated in

15 immunodeficient mice by subcutaneous injection of MUC4+ human pancreatic

cancer cell lines; Capan-1, HPAF-II, or CD18/HPAF. In paper VI, a 76-member

combined epigenetics and phosphatase small-molecule inhibitor library was

screened against Capan-1 (MUC4+) and Panc-1 (MUC4-) cells, followed by high

content screening of protein expression.



Results/Conclusion: 134 differentially expressed serum proteins were identified,

of which 40 proteins showed a significant up-regulation in the pancreatic cancer

group. Pancreatic disease link associations could be made for BAZ2A, CDK13,

DAPK1, DST, EXOSC3, INHBE, KAT2B, KIF20B, SMC1B, and SPAG5, by

pathway network linkages to p53, the most frequently altered tumor suppressor in

pancreatic cancer (I). An ANN survival model was developed, identifying 7 risk

factors. The C-index for the model was 0.79, and it performed significantly better

than the Cox regression (II). We experienced improved surgical results for

pancreaticoduodenectomy after the transition to a high-volume center (≥25

procedures/year), including decreased operative duration, blood loss, hemorrhagic

complications, reoperations, and hospital stay. There was also a tendency toward

reduced operative mortality, from 4% to 0% (III). MUC4 positivity was detected

in most primary pancreatic cancer tissues, as well as in matched metastatic lymph

nodes (15/17 vs. 14/17), with a high concordance level (82%) (IV). The tumor

incidence was 100% in the xenograft model. The median MUC4 count was found

to be highest in Capan-1 tumors. α-SMA and collagen extent were also highest in

Capan-1 tumors (V). Apicidin (a histone deacetylase inhibitor) had potent

antiproliferative activity against Capan-1 cells and significantly reduced the

expression of MUC4 and its transcription factor HNF4α. The combined treatment

of apicidin and gemcitabine synergistically inhibited growth of Capan-1 cells (VI).