CME Topic

Surveillance of the Colorectal Cancer
Disparities Among Demographic Subgroups:
A Spatial Analysis
Chiehwen Ed Hsu, PhD, MPH, Francisco Soto Mas, MD, PhD, MPH, Jessica M. Hickey, MPH,
Jerry A. Miller, PhD, and Dejian Lai, PhD

Objective: The literature suggests that colorectal cancer mortality in
Texas is distributed inhomogeneously among specific demographic

subgroups and in certain geographic regions over an extended pe-

riod. To understand the extent of the demographic and geographic

disparities, the present study examined colorectal cancer mortality in

15 demographic groups in Texas counties between 1990 and 2001.

Methods: The Spatial Scan Statistic was used to assess the stan-
dardized mortality ratio, duration and age-adjusted rates of excess

mortality, and their respective p-values for testing the null hypoth-

esis of homogeneity of geographic and temporal distribution.

Results: The study confirmed the excess mortality in some Texas
counties found in the literature, identified 13 additional excess mor-

tality regions, and found 4 health regions with persistent excess

mortality involving several population subgroups.

Conclusion: Health disparities of colorectal cancer mortality con-
tinue to exist in Texas demographic subpopulations. Health educa-

tion and intervention programs should be directed to the at-risk
subpopulations in the identified regions.

Key Words: colorectal cancer, health disparities, public health in-
formatics, Geographic Information Systems, spatial analysis.

In 2005, an estimated 56,290 deaths from colorectal cancerwere expected in the United States, sustaining colorectal
cancer as the third leading cause of cancer-related deaths
among Americans.1 Recent studies suggest that screening is
effective in decreasing colorectal cancer in both incidence
and mortality by early detection and removal of precancerous
lesions or polyps, and enhancing survival rates among colo-
rectal cancer patients.2 Colorectal cancer is one of the most
preventable types of cancer when detected at an early stage.3

However, while the 5-year survival rate for colorectal cancer
is around 90% for those cases detected at an early stage, only
about 37% of colorectal cancers were diagnosed at an early
stage in 2004.4 At the state level, between 1989 and 1998, the
age-adjusted mortality rate for colorectal cancer in Texas ac-
tually increased by more than 20%.3 To target prevention and
intervention efforts, it is important to understand the contrib-
uting risk factors for colorectal cancer affecting demographic
groups living in different geographic regions.

From the Department of Public and Community Health, University of Mary-
land College Park, College Park, MD, and School of Health Information
Sciences, University of Texas Houston Health Science Center, Houston,
TX; Department of Teacher Education, College of Education, University
of Texas at El Paso, El Paso, TX; Centers for Medicare and Medicaid
Services, Dallas Regional Office, Dallas, TX; ORISE/CDC Public Health
Fellow, Centers for Disease Control and Prevention, National Center on
Birth Defects and Developmental Disabilities, Atlanta, GA; and the Di-
vision of Biostatistics, School of Public Health, University of Texas
Houston Health Science Center, Houston, TX.

Reprint requests to Chiehwen Ed Hsu, PhD, University of Maryland, College
Park, Department of Public and Community Health 2371 HHP Building,
Valley Drive, College Park, MD 20742. Email: edhsu@umd.edu

The findings and conclusions in this article are those of the author(s) and do
not necessarily represent the views of the Centers for Disease Control and
Prevention.

The authors have no disclosures to declare.

Accepted April 3, 2006.

Copyright © 2006 by The Southern Medical Association

0038-4348/0�2000/9900-0949

Key Points
• Colorectal cancer mortality in Texas was found to be

distributed inhomogeneously among specific demo-
graphic subgroups and in certain geographic regions
over an extended period.

• The study confirmed the excess mortality in some
Texas counties reported in the literature, identified 13
additional excess mortality regions, and found 4 health
regions with persistent excess mortality involving sev-
eral population subgroups.

• Health disparities in colorectal cancer mortality con-
tinue to exist in Texas demographic subpopulations.
Health education and intervention programs should be
enhanced to address the at-risk subpopulations in the
identified regions.

Southern Medical Journal • Volume 99, Number 9, September 2006 949



State-level studies in Texas have found that colorectal
cancer mortality disproportionately burdened population sub-
groups defined by certain demographic characteristics, such
as age, gender, race/ethnicity, and by residential distribution.
In terms of age, more than 90% of colorectal cancer cases are
diagnosed in people aged 50 and older.3 Regarding gender,
epidemiologic data indicate that there is a pronounced vari-
ation in the risk of colorectal cancer by gender, with men at
a greater risk of colorectal cancer mortality than women.
Between 1984 and 1996, the averaged Texas age-adjusted
mortality rate from colon cancer for males was 17.64, and for
females 12.18 per 100,000 people.5 The disparities on colo-
rectal cancer mortality by gender have widened in recent
years. In 2003, the American Cancer Society reported that the
age-adjusted colorectal cancer mortality rate in Texans rose
to 26.1 per 100,000 for men and 17.4 per 100,000 for wom-
en.4 These rates paralleled national statistics of age-adjusted
colorectal cancer mortality rates for men (25.8/100,000) and
for women (18.0/100,000).4 Risk of colorectal cancer also
varies by race and ethnicity. National data suggested that
African Americans (both female and male) have the highest
age-adjusted mortality rate when compared with other sub-
groups. Current Surveillance, Epidemiology and End Results
(SEER) data from the National Cancer Institute indicate that
the age-adjusted colorectal cancer mortality rate for African
Americans is 28.5 per 100,000, compared with 20.7 per
100,000 for whites in the same year.6 The disparity trend
appeared to hold true by gender and race. Between 1970 and
1994, age-adjusted colon cancer mortality in Texas was 16.57
for white males versus 12.20 for white females, and 21.46 for
black males versus 17.22 for black females per 100,000.7 A
study reported in the Southern Medical Journal indicated that
between 1980 and 1990, colorectal cancer mortality in Texas
increased at a statistically significant level, notably in Afri-
can-American and Hispanic males.8 In terms of geographic
distribution of mortality, the (Dallas-Fort Worth) Metroplex,
Gulf Coast, Central and Southwest Texas areas, namely the
Public Health Regions, or PHR 3, 5, 6, and 7, had the highest
age-adjusted mortality rates for colorectal cancer9 (refer to
figures for Public Health Regions). In addition, several Tex-
as-specific cancer studies confirmed that cancer mortality has
unevenly burdened residents in specific geographic regions
over an extended period of time.10,11,12 Cooper and col-
leagues8 reported that excess colorectal cancer mortality dis-
proportionally affected certain racial and ethnic groups be-
tween 1980 and 1991. The affected regions included the
Houston/Harris County area for non-Hispanic white men and
women, and the Victoria Area for Hispanic men, all in PHR
Region 6. Zhan and Lin11 confirmed the excess of colon
cancer mortality among the general population in the South-
west, Gulf Coast and Metroplex Regions of Texas from 1990
to 1997.

To develop effective colorectal cancer prevention inter-
ventions for at-risk populations, it is important to understand

how the excess mortality is distributed among population
subgroups in different regions, and estimate the persistence of
the excess mortality in terms of whether the trend of excess
continues. The purpose of this study was to further determine
and quantify the geographic variation of colorectal mortality
in subgroups of Texas residents. The present study examined
the areas of excess colorectal cancer mortality among 15
Texas population subgroups by gender, race/ethnicity and
their combinations between 1990 and 2001, to compare and
contrast the results with the published literature. This infor-
mation could prove beneficial for the allocation of resources
and development of preventive interventions directed toward
at-risk population groups.

Methods
Data for analysis included 16 age groups (group 1, aged

0 – 4; group 2, 5–9... to group 16, 75�), two gender groups,
and the 4 major population subgroups in Texas (non-Hispanic
white, blacks, Hispanics and “other”). First, a “Case File”
was created to store colorectal cancer death cases, and the
corresponding race, gender and age group by ethnicity. The
data of counts were based on ICD-9 codes 153 to 154 for
colorectal cancer in the study years 1990 to 1998, and ICD-10
codes C18-C21 for the years 1999 to 2001. The ICD-10 clas-
sification includes cancer deaths of colon, rectum and anus,
cancer of the rectosigmoid junction and rectum, and cancer of
the anus and anal canal. The data were collected from a
publicly available cancer mortality source (Expert Health Data
Programming Incorporated’s Texas Vitalweb. Available at:
http://www.ehdp.com). Second, a “Population File” was cre-
ated to store the population by county, and the corresponding
race, gender and age group by ethnicity for each of the study
years. For intercensal years, population estimate data was
obtained from the Texas Population Center of Texas A&M
University. Finally, a third file, the “Geographic File,” was
created. This file contained data from the U.S. Census Bureau
(http://www.cdc.gov/epiinfo/usa/tx.exe), including the longi-
tudinal and latitudinal information on all 254 county cen-
troids of Texas. The information was used as a proxy for the
geographic location of each county. The excess colorectal
cancer mortality, as measured by the geographic concentra-
tion of mortality in relation to other regions over an extended
period, were detected using the SaTScan software18 version
4.0 (Available at: http://www.satscan.org). The software per-
forms spatial-temporal analysis adjusting for covariates such
as age, gender and race/ethnicity. Our study was modeled
after a study by Kulldorff and colleagues,13 who had applied
the spatial scan statistic in examining cancer burdens in the
Los Alamos region of New Mexico. The same methodology
has been widely applied in public health studies that inves-
tigated behavior-related diseases,14 –16 and for analysis of spa-
tial distributions of health outcomes data in Texas, including
colon cancer mortality,11 breast cancer10 and accidental poi-

Hsu et al • Surveillance of the Colorectal Cancer Disparities Among Demographic Subgroups

950 © 2006 Southern Medical Association



soning disparities.17 The stepwise procedures were reported
by the authors elsewhere.10,17 SaTScan employs the Monte-
Carlo simulation to conduct hypothesis testing, which can
differentiate areas with unequal cancer mortality burden. In
the present study, statistical significance was established at
the 0.05 level without adjusting the significance level due to
multiple comparisons. In addition, a space-time relationship
was examined between the colorectal cancer mortality rate
and the defined geographic area being studied (ie, a county).
The null hypothesis of the homogenous Poisson process for
this study provides that when no covariates are being consid-
ered, the expected deaths for each county are proportional to
the population of that county area and that there is an absence
of time trend. The alternative hypothesis is that the deaths are
not homogenously distributed (or not exactly proportional to
the population in the same geographic area), and/or there is a
presence of temporal trend in the inhomogeneous distribution
of health outcomes. The study used a parameter “50% of
population at risk” in which a cluster, if detected, would
comprise at most, 50% of the study population. The param-
eter was proposed by Kulldorff13 as an optimal setting. The
temporal setting of clusters was set at 90%, meaning that a
detected cluster would include a maximum of 90% of the
study period (ie, up to a maximum of 10 years), while time is
treated nonparametrically, ie, as an indicator variable to make
sure the clusters are not an artifact of temporal trend. This
spatial-temporal analysis also includes a “spatial only” anal-
ysis that allowed the examination of cross-sectional preva-
lence of colorectal cancer deaths over the entire study period
(12 years). A brief review of scan statistics and their appli-
cations to ecological studies and environmental sciences is
available by Patil and Taillie.18 The Poisson model is appli-

cable in this study of colorectal cancer because the analysis
involved small numbers of cases against larger population
denominators, as is often the case with cancer. This is par-
ticularly true for the state of Texas, where in 2003 the age-
adjusted mortality rate for colorectal cancer was estimated at
26.1 per 100,000 for males and 17.4 per 100,000 for females.1

Both rates are relatively small in terms of the number of
deaths in the numerator and the population at risk in the
denominator. All rates are age-standardized and stratified for
each of 16 groups using indirect standardization.

The SaTScan analysis produced the metrics useful for
quantifying spatial clustering and estimating excess mortality
in each group. These measurements included the P value,
standardized mortality ratio (SMR), the age-adjusted rate, and
the duration of excess. They were then imported into ArcGIS
8.0 software to produce Geographic Information Systems
(GIS) maps, so as to present a visual illustration of the actual
disparity for colorectal cancer mortality by Texas county ex-
cess mortality. For the purpose of analysis, we color-shaded
the detected regions of excess mortality with dissolved county
boundaries overlaid with the geographic boundary file of 11
Texas Public Health Regions (PHR).

Results
This study included 390,144 records in both the case file

and population file in the 254 Texas counties between 1990
and 2001. The overall mortality trends and specific geographic
variations by subgroups are presented below. For the 12-year
study period, there were 37,596 deaths attributable to colo-
rectal cancer, resulting in an age-adjusted rate of 16.5 per
100,000. Males had higher age-and-race adjusted mortality

Table 1. Characteristics of study population and deaths, Texas 1990 –2001

Population
Average

total population (%)
Cumulative

deaths (%)

Annual
age-adjusted rate

(per 100,000)

All 18,974,226 100 37,596 100 16.5

Male 9,388,316 49.48 19,133 50.89 17.0

Female 9,585,911 50.52 18,463 49.11 16.1

Black 2,205,661 11.62 5,283 14.05 20.0

Male 1,068,714 5.63 2,589 6.89 20.2

Female 1,136,947 5.99 2,694 7.17 19.7

Hispanic 5,342,242 28.16 4,313 11.47 6.7

Male 2,696,015 14.21 2,500 6.65 7.7

Female 2,646,227 13.95 1,813 4.82 5.7

Non-Hispanic White 10,946,960 57.69 27,745 73.80 21.1

Male 5,384,897 28.38 13,925 37.04 21.5

Female 5,562,063 29.31 13,820 36.76 20.7

Other 479,363 2.53 255 0.68 4.4

Male 240,673 1.27 136 0.36 4.7

Female 238,690 1.26 119 0.32 4.2

CME Topic

Southern Medical Journal • Volume 99, Number 9, September 2006 951



rates of 17.0 per 100,000 than females of 16.1 per 100,000.
Table 1 summarizes the demographic characteristics of the
study population in Texas.

When compared across major racial groups, non-His-
panic whites, blacks, Hispanics, and others had age-adjusted
rates of 21.1, 20.0, 6.7, and 4.4 per 100,000 respectively.
Mortality disparities by gender among the selected racial/
ethnic groups were apparent: age-adjusted mortality rates for
female non-Hispanic whites, blacks, Hispanics and others
were 20.7, 19.7, 5.7 and 4.7 per 100,000; and for male non-
Hispanic whites, blacks, Hispanics and others were 21.5, 20.2,
7.7 and 4.2 respectively.

Table 2 summarizes the measurements of excess mortal-
ity by SMR, P value, age-adjusted rate, and the duration of
excess for each of 15 population groups. To determine po-
tential excess mortality, we present color-shaded excess mor-
tality regions in Figure 1. A “most likely” or “secondary”
excess region is identified based on the values of 1) statistical
significance, 2) a high SMR, 3) age-adjusted rate, and 4)
excess mortality regions that persisted through most recent
years (ie, year 2001). Among the 15 combined groups of
gender, race and race-by-gender examined in the study, 13

public health regions* were identified with an excess colo-
rectal cancer mortality of statistical significance. The major-
ity of the areas of excess mortality were located throughout
the Southeastern region of Texas and in the (Dallas-Fort
Worth) Metroplex (involving 8 groups) and North East Texas
(involving 4 groups). In terms of age-adjusted rates, black
males in the counties near Metroplex and Central Texas pre-
sented the highest mortality rate (37.3/100,000) with the high-
est SMR (RR � 1.84); however, the excess mortality oc-
curred only one year in 1996, and it was not statistically
significant (P � 0.926). Non-Hispanic white males also pre-
sented a significant excess mortality, with rates of 28.6 and
24.8 per 100,000 in 1990 to 1994 and 1997 to 1999 respec-
tively, followed by the “all male” group with a rate of 24.7
per 100,000 (RR � 1.45) between 2000 and 2001. Other
female and male groups did not present statistically signifi-
cant excess mortality. In terms of most recent excess mortal-

*In this study, the reference of Texas public health regions follows the
conventional naming system used by the Texas Health and Human Ser-
vices Regions (THHS, 2005). Available at: http://www.hhs.state.tx.us/
aboutHHS/HHS_Regions.shtml. Accessed: July 10, 2005.

Table 2. Potential excess mortality a by subgroup and geographic region (PHR)

Population subgroups
Years

(duration)
No. of
deaths

Annual age
adjusted rate/

100,000 P value
Standardized
mortality rate PHR

Figure 1
label

Spatiotemporal excess mortality

All population, A 1990–1997(8) 7,544 17.5 0.002 1.06 PHR 5–8,11 1.1 A

All population, B 1993–2000(8) 1,096 19.5 0.003 1.18 PHR 3–4 1.1 B

All males, A 1991–1994(4) 1,579 19.4 0.007 1.14 PHR 5–8, 11 1.2 A

All male, B 2000–2001(2) 197 24.7 0.035 1.45 PHR 3–4, 7 1.2 B

All females 1991–1999(9) 927 19.4 0.001 1.21 PHR 3–4 1.3

Non-Hispanic white females 1994–2001(8) 1,878 23.5 0.002 1.14 PHR 3–7 1.7

Non-Hispanic white males, A 1990–1994(5) 1,489 24.8 0.001 1.15 PHR 6–8, 11 1.10A

Non-Hispanic white males, B 1997–1999(3) 367 28.6 0.009 1.33 PHR 2–3, 7, 9 1.10B

Black, male 1996–1996(1) 41 37.3 0.926 1.84 PHR 3, 7 1.11

Other male 1993–1993(1) 2 440.4 0.449 106 PHR 3 –

Other female 2000–2001(2) 5 61.3 0.267 13.00 PHR 2 –

Spatial only

All non-Hispanic whites 1990–2001(12) 11,588 22.2 0.001 1.05 PHR 3–4 1.4

All black 1990–2001(12) 1,542 22.1 0.084 1.11 PHR 2–4 1.5

All Hispanics 1990–2001(12) 1,837 8.00 0.001 1.19 PHR 6–9, 11 1.6

Black, female 1990–2001(12) 848 22.8 0.027 1.16 PHR 2–4 1.8

Hispanic females 1990–2001(12) 729 6.8 0.001 1.19 PHR 6–8, 11 1.9

Hispanic males 1990–2001(12) 1,062 9.3 0.001 1.21 PHR 6–9,11 1.12

a Excess mortality is defined as up to 50% of study population, with temporal persistence for up to 90% of the study years, including purely spatial clusters
adjusting for temporal effect nonparametrically.

PHR, Texas Public Health Region as defined by the Texas Department of Health and Human Services.

http://www.hhs.state.tx.us/aboutHHS/HHS_regions.shtml

Hsu et al • Surveillance of the Colorectal Cancer Disparities Among Demographic Subgroups

952 © 2006 Southern Medical Association



ity, 8 groups presented persistent mortality rates through 2001;
seven of them with a SMR of less than 1.2 and thus negligi-
ble, except for the one which occurred in the “all males”
group (described above) in PHR 3, 4 and 7. In terms of
disparity by gender, between 1990 and 2001, Hispanic fe-
males in PHR 6 to 9 and 11 were at 1.19 SMR compared with
those in other regions, while the age-adjusted rate was only
6.8/100,000; non-Hispanic white males in PHR 2 to 3, 7 and

9 had the highest (RR � 1.33) age adjusted rate (28.6/100,000)
between 1997 and 1999 that demonstrated statistical signifi-
cance. Figure 1 presents the Texas regions of excess mortality
by gender and demographic subgroups.

Discussion
This study presents an overall colorectal cancer trend and

outlines the specific geographic variations among demo-

Fig. 1 (continued).

Fig. 1 Potential excess colorectal cancer mortality in Texas public health regions by population and subgroups, 1990 to 2001.

CME Topic

Southern Medical Journal • Volume 99, Number 9, September 2006 953



graphic subgroups over an extended period. In terms of over-
all trend, between 1990 and 2001 there was a pronounced
variation in mortality by gender. The age-adjusted mortality
rate for females increased significantly (16.1/100,000 —an
increase of 33% when compared with the rates based on
1984-1996 data of 12.18 per 100,000), while that of males
was somewhat reduced (17.00 versus 17.64). This suggests
that the disparities in the mortality trend between females and
males continued. While males still have high mortality, the
gap appears to have narrowed over the recent years. This
could possibly reflect a secular or cohort trend of increased
incidence of colorectal cancer in females from environmen-
tal/dietary causes, reduced screening among females, or both.
In contrast with other races, non-Hispanic white female mor-
tality increased by 68% in comparison to the 1970 to 1994
period, and for blacks by 14.4% in the same period. In addi-
tion, among all race/ethnicity groups, only females in the
“other” category exceeded males in the age-adjusted mortal-
ity rate; however, regions of excess mortality detected in the
“other” group were not statistically significant. Consistent
with the results of a previous study examining cancer data
among Texas counties,10 for the “other” group the age-ad-
justed rate (female � 61.3/100,000 and male � 440.4/
100,000) and SMR (female � 13.00 and male � 106) were
artificially inflated due to the small denominators of both
population subgroups.

In terms of geotemporal distribution, several PHRs pre-
sented persistent excess colorectal cancer mortality through
the present decade affecting multiple groups, notably in Pub-
lic Health Region 3, 4, 6, and 7, which includes the Dallas-
Fort Worth and Houston metropolitan regions.

The results of this study confirmed most of the previ-
ously reported areas of excess colorectal mortality in the
Southwest, Gulf Coast, part of Central Texas PHRs and Kauff-
man County between 1990 and 1997.11 We found that in the
Southwest, Gulf Coast and part of Central Texas regions, the
excess mortality primarily affected both male and female non-
black populations, and confirmed that the trend discontinued
in 1997. On the other hand, in Kauffman and neighboring
counties, excess mortality primarily affected non-Hispanic
females and black males through 2001. This excess also in-
volved the North Metroplex and Upper East Texas PHRs,
affecting both non-Hispanic white and black females, with
the trend persisting between 1990 and 2001. Compared with
the findings based on 1980 to 1990 data,8 the excess mortality
affecting black males might have ceased in 1996 because the
excess mortality in this group was no longer statistically sig-
nificant. On the other hand, the excess mortality detected
among Hispanic males in the South and Lower South Texas
PHRs reported by Cooper and colleagues8 was found to have
persisted between 1990 and 2001 at a moderate and statisti-
cally significant level (RR � 1.21) in this study. Ongoing
monitoring and preventive interventions are warranted to
avoid the temporal trend of excess mortality from continuing.

In addition, this study further confirms the finding by the
Texas Cancer Data Center5 regarding the identification of the
4 PHRs with the highest colorectal cancer mortality rate in
Texas. The regions detected with excess mortality are prime
targets for additional demographic studies to identify other
disparities related to health care and access to quality colo-
rectal cancer preventive and treatment services. The findings
of this study may inform agencies such as the State Cancer
Council, as well as cancer advocacy groups in developing
strategic planning for colorectal cancer. These findings are
significant, current, and consistent with other studies and,
therefore, may provide insight for the development of inter-
ventions that intend to address the disparities of colorectal
cancer mortality among demographic groups. The spatial and
temporal analysis method has been employed to investigate
other disease incidence or mortality14 –16 which may provide
directions for advancing cancer prevention and control poli-
cies.

This study renders several research questions that war-
rant further discussion. First, a potential problem of data re-
liability is the change from ICD-9-CM to ICD-10-CM codes
implemented in 1999. The literature has suggested that
changes in coding practices due to the transition has inevita-
bly introduced under- or over-representation of cases or counts
to an extent that may bias research results.19,20 In the present
study the ICD-9 codes only included colorectal data, while
ICD-10 codes included cancer of the colon, rectum and anus;
cancer of the rectosigmoid junction and rectum; and cancer of
the anus and anal canal. One may expect the more inclusive
cancers to be reported with the ICD 10 codes, which may in
turn result in the detection of relative excess mortality after
1999. However, the results of our study suggest that the
changes in coding did not shift the temporal mortality trend
toward 1999 and after, because in comparison with other
periods, no substantial increase of mortality occurred begin-
ning in 1999, or in between 1999 and 2001.

Second, the present study introduces spatiotemporal anal-
ysis as an attempt to quantify colorectal cancer disparities and
focus intervention efforts on targeted regions and popula-
tions. By doing so it prompts additional research questions
that warrant further clarification. For example, to determine
potential excess mortality that may warrant preventive inter-
ventions, the present study focused on the regions with excess
mortality of statistical significance, with a high SMR and
age-adjusted rate that persisted through the most recent years.
The addition of the temporal dimension has the strengthening
effect of smoothing the rates in a cluster over time, and could
give clues to colorectal cancer etiology or long-term risk
factors. On the other hand, this approach to quantifying colo-
rectal cancer mortality burden, though adequate for this study,
does not provide a precise quantification of disparities. Future
research could seek to model the disparity burden by, for
example, developing a composite index that combines several

Hsu et al • Surveillance of the Colorectal Cancer Disparities Among Demographic Subgroups

954 © 2006 Southern Medical Association



measurements such as SMR, adjusted rate, and duration of
excess health to better quantify the magnitude of the dispar-
ities in a multivariate context.

Third, further analysis should be conducted among at-
risk population subgroups identified in this study and in the
literature. For example, the Texas Cancer Council has re-
ported that more than 90% of colorectal cancer patients were
diagnosed at age 50 and older. Incidence rates are six times
higher among persons aged 65 years and older than for those
aged 50 to 64 years, and more than 70% of all newly diag-
nosed colorectal cancers occurred in persons aged 65 years
and older.3 Therefore, additional analysis may be directed to
these high-risk age groups to determine the magnitude and
spatial distribution of both incidence and mortality for colo-
rectal cancer. In addition, although this study did not find any
hot-spot excess mortality region (ie, those with SMR � 2.0),
further studies should be conducted to explore how policy
changes or new screening or treatment methods for colorectal
cancer may affect the disease distribution among populations,
and in turn affect the geographic distribution of excess mor-
tality. For example, Medicare has covered some screening
tests for colorectal cancer since 1998, but as of 2001, it has
covered all recommended colorectal cancer screening tests
through Part B of the program, which covers the 65 and older
population. Further studies may examine recent data to ex-
plore the effect of screening coverage on colorectal health by
demographic groups.

Fourth, efforts should be directed to study “other” de-
mographic subgroups. The present study, consistent with the
literature, found that males generally have higher mortality
rates than females across most race/ethnicity subgroups, with
the exception of the females in the “other” racial category
which exceeded males in terms of age-adjusted rates. This
may suggest that females in the “other” category experience
additional barriers to health care access. The “federal stan-
dards for maintaining, collecting, and presenting federal data
on race and ethnicity” (OMB Statistical Directive 15) pro-
vides for the collection and reporting of health data by 6
races21 (including American Indian or Alaska Native, Asian,
black or African-American, Native Hawaiian, Pacific Is-
lander, and white) and two ethnicities (Hispanic or Latino
versus non-Hispanic or Latino). Misclassification of race/eth-
nicity may account for some persons being categorized as
“other,” in which case the mortality rates for correctly cate-
gorized race/ethnicities may be over- or underestimated, al-
though how this affects the detection of clusters (ie, relative
rates between racial/ethnic groups) remains unclear. Misclas-
sification can come from two sources: census and cancer
registry. State health reporting authorities should seek to dis-
aggregate the “other” category and include those population
subgroups not otherwise included. The disaggregation of the
“other” group health data may be particularly urgent for the
Asian population, which is among the fastest growing sub-

group in the U.S. according to the Census 2000, and is con-
fronting many clear and present epidemic challenges.

Conclusion
The findings for the total population group were rela-

tively consistent with previous studies in that most of the
excess mortality was identified in the Southeast (around Har-
ris County encompassing the city of Houston) region and
Metroplex (around Dallas County) of Texas. In addition, the
present study identified several regions of potential excess
mortality among racial groups that have not been previously
reported. In particular, several demographic groups warrant
particular notice, including the male population in PHR 3 to
4 and 7 (RR � 1.45, rate � 24.7/100,000, between 2000 and
2001), and the other 7 population subgroups with excess mor-
tality trends persisting to the present decade. In addition, the
multiple population groups in Public Health Regions 3, 4, 6,
9 and 11 have experienced persistent excess mortality over
time, which warrants further investigation. Overall, this study
provides evidence that the spatiotemporal analysis for differ-
entiation of excess mortality among age, gender and race/
ethnic groups constitutes a potentially relevant method for
public health planning and health disparities studies. The find-
ings of demographic disparities of the disease may assist state
health authorities in updating their action plans, as they are
both significant and current. The spatiotemporal analysis
should be considered for developing prevention and interven-
tion programs for addressing the demographic disparities of
colorectal cancer mortality, given the limited resources, in-
creased racial/ethnic diversity and aging of the population of
the state of Texas, with which to confront the disproportional
burden of this disease.

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CME Topic

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Please see James Wooten’s editorial on page 915
of this issue.

We find a delight in the beauty and happiness of chil-
dren that makes the heart too big for the body.

—Ralph Waldo Emerson

Hsu et al • Surveillance of the Colorectal Cancer Disparities Among Demographic Subgroups

956 © 2006 Southern Medical Association