Adult weight gain and risk of colon cancer in men

Previous research supports the hypothesis that a "rich" diet (i.e., high in fat and low in fiber) increases the risk of colon cancer. Previous research also supports the hypothesis that physical inactivity increases the risk of colon cancer, perhaps because physical inactivity decreases gut motility, thereby increasing tee time that carcinogens are in contact with the intestinal mucosa. Habitual physical inactivity, combined with rich diet, ordinarily results in chronic energy imbalance and gain in weight, except when energy balance is modified by disease or factors such as cigarette smoking. Cigarette smokers typically stay lean because of effects of smoking on the resting metabolic rate as well as on efficiency of caloric intake and storage. Therefore, if physical inactivity and rich diet do increase the risk of colon cancer, then weight gain during young adulthood should be positively associated with incidence of colon cancer during later life, especially in nonsmokers.^ This hypothesis was investigated in a cohort of 2,059 randomly selected middle-aged men who were employed at the Western Electric Company in Chicago and were free of clinically diagnosed cancer at initial examination in 1958. Body mass index (BMI) in middle age was calculated from measured height and weight at the initial examination. BMI at age 20 was estimated from weight at age 20 as recalled at the initial examination and height as measured at the initial examination. Change in BMI between age 20 and middle age was estimated by subtracting the BMI at 20 from the BMI in middle age. Forty-nine incident cases of colon cancer were detected during 25 years (43,326 person-years) at risk. When stratified by level of change in BMI from age 20 to middle age ($\le$1.9, 2.0-3.9, 4.0-5.9, $\ge$6.0 kg/m$\sp2$), age-adjusted relative hazards of colon cancer in never-smokers were 1.00, 1.22, 2.31, and 5.01, respectively (p for trend = 0.008); corresponding values in ever-smokers were 1.00, 0.95, 0.77, and 0.87, These associations did not change appreciably after further adjustment for BMI at age 20, subscapular-triceps skinfold ratio, cigarette smoking, consumption of alcohol, energy, fat, and calcium.^ We also investigated the hypothesis that the risk of colon cancer was higher in men who were lean at age 20 and became fat by middle age (lean-to-fat) than in men who were fat at age 20 and stayed fat in middle-age (fat-to-fat). "Lean" was defined as BMI $<$24 kg/m$\sp2$ at age 20 and as BMI $<$27.0 kg/m$\sp2$ in middle age. Among never-smokers, in comparison to men who were lean at age 20 and in middle age (lean-to-lean), the age-adjusted relative hazard of colon cancer was 1.43 in the fat-to-fat group (95% confidence interval (CI) 0.37-5.52) and 3.36 in the lean-to-fat group (95% CI 1.21-9.37). This investigation provides new results on the magnitude of risk of colon cancer associated with weight gain during adulthood (from age 20 to middle age). This relation was obscured or underestimated in previous studies due to effect-modification by cigarette smoking. Finally, the result supports the idea that a life-style characterized by chronic energy imbalance during young adulthood increases risk of colon cancer. ^

ADAPTATION OF INTESTINAL MUSCLE IN THE RAT AFTER INTESTINAL BYPASS

After intestinal bypass, the mucosa of the in-continuity segment (ICS) of intestine undergoes adaptive hyperplasia which results in increased absorptive function per length of intestine. In the present study, 70% of the small intestine was bypassed in rats to determine if intestinal muscle also adapts after bypass. To determine the effect of bypass on intestinal transit, a poorly absorbed marker substance was introduced into the orad portion of the ICS or bypassed loop (BL). Significantly less marker (P < 0.05) was passed from the ICS into the colon in 50 minutes in fed rats at 14 days compared to at 3 days after bypass. In 150 minutes there was more marker in the colon of fed rats at 3 and 14 days but not at 35 days after bypass than in control. In the BL, transit was slowed significantly in fed rats at 3 and 35 days and in fasted rats at 3 days but not 35 days after bypass compared to control. The circular muscle from the BL and the distal but not proximal portion of the ICS developed significantly more carbachol-stimulated force in vitro at 35 but not 3 days after bypass compared to unoperated but not sham-operated controls. At 35 days after bypass, the muscle layers had a greater muscle wet weight and protein content compared to both unoperated and sham-operated control in both the proximal and distal portions of the ICS. Similarly, there was more muscle in histological sections of the BL and distal portion of the ICS at 35 days after bypass compared to either control. Nonetheless, at 35 days after bypass actomyosin content as a fraction of muscle weight or total protein content was not different from control. The results support the hypothesis that there was a functional adaptation, i.e. slowed transit in fed rats that allowed more time for absorption. Feeding caused slowed transit in the BL as well as the ICS. Other results suggest that an increased amount of functional muscle formed in the distal portion of the ICS after bypass. ^

MODULATION OF HOST INTESTINAL MYOELECTRIC ACTIVITY BY LOCAL ANAPHYLAXIS: A COMPONENT OF PROTECTIVE IMMUNITY TO AN ENTERIC PARASITE (TRICHINELLA SPIRALIS, EIMERIA NIESCHULZI, BOWEL MOTILITY)

The hypothesis tested was that rapid rejection of Trichinella spiralis infective larvae from immunized rats following a challenge infection is associated with a local anaphylactic reaction, and this response should be reflected in altered small intestinal motility. The objective was to determine if altered gut smooth muscle function accompanies worm rejection based on the assumption that anaphylaxis in vivo could be detected by changes in intestinal smooth muscle contractile activity (ie. an equivalent of the Schultz-Dale reaction or in vitro anaphylaxis). The aims were to (1) characterize motility changes by monitoring intestinal myoelectric activity in conscious rats during the enteric phase of T. spiralis infection in immunized hosts, (2) detect the onset and magnitude of myoelectric changes caused by challenge infection in immunized rats, (3) determine the parasite stimulus causing changes, and (4) determine the specificity of host response to stimulation. Electrical slow wave frequency, spiking activity, normal interdigestive migrating myoelectric complexes and abnormal migrating action potential complexes were measured. Changes in myoelectric parameters induced by larvae inoculated into the duodenum of immune hosts differed from those associated with primary infection with respect to time of onset, magnitude and duration. Myoelectric changes elicited by live larvae could not be reproduced by inoculation of hosts with dead larvae, larval excretory-secretory products, or by challenge with a heterologous parasite, Eimeria nieschulzi. These results indicate that (1) local anaphylaxis is a component of the initial response to T. spiralis in immune hosts, since the rapid onset of altered smooth muscle function parallels in time the expression of rapid rejection of infective larvae, and (2) an active mucosal penetration attempt by the worm is necessary to elicit this host response. These findings provide evidence that worm rejection is a consequence of, or sequel to, an immediate hypersensitivity reaction elicited when parasites attempt to invade the gut mucosa of immunized hosts. ^