The Boston Region Metropolitan Planning Organization (Boston Region MPO) is developing a Vision Zero Action Plan supported by a grant from the federal Safe Streets and Roads for All (SS4A) Program. A key component in developing this plan is the creation of a High-Injury Network (HIN)—a series of roadway locations throughout the region on which a high proportion of traffic fatalities and serious injuries occur. This memorandum provides a description of the methodology for developing the HIN, the data and criteria used, and key findings from the HIN. The results of the HIN will provide priority locations for tailored treatments throughout the regional, subregional, and municipal transportation networks.

Data Sources

Development of the HIN requires two key forms of data: crash data and roadway data. For the Boston Region MPO HIN, crash data were obtained through the Massachusetts Department of Transportation (MassDOT) IMPACT Crash Data Portal. The data represent years 2018 to 2022.

MassDOT’s Roadway Inventory data were utilized as the spatial base for the HIN, segmenting the roadway every 0.1 miles. Limited-access roads were removed from the dataset, as the focus of this plan is primarily local roads and what the MPO and municipalities can do to address local roadway safety. Also, MassDOT has systems in place for addressing limited-access state-owned roads, and the higher traffic volumes and congested-related crashes would skew the HIN thresholds.

Crashes were assigned to the segments within 100 feet of the crash location. Limited-access roadways and ramps were then removed from the HIN, leaving only partial- and full-access roadways.

Methodology

The HIN development is one of the main elements of the Vision Zero Action Plan. The purpose of the HIN is to locate roads where the crashes are highest both in terms of frequency and severity. To do so, an HIN sliding window analysis was conducted by using a 1-mile window to assess clusters of crashes along the roadway network at the level of Greater Boston Metro Region, the 97 municipalities in the region, and eight subregions: North Shore Task Force (NSTF), North Suburban Planning Council (NSPC), Minuteman Advisory Group on Interlocal Coordination (MAGIC), Inner Core Committee (ICC), MetroWest Regional Collaborative (MWRC), South Shore Coalition (SSC), Three Rivers Interlocal Council (TRIC) and South West Advisory Planning Committee (SWAP). Ranking the roadway segments was completed using a five-step process outlined in Figure 1.1. Each step is described in further detail below.

Figure 1.1 | HIN Analysis Steps

A step of a staircase with text and symbols
AI-generated content may be incorrect.

Step 1—Preprocess the Data

The first step in the HIN development is preprocessing the road layer and the crash layer. This includes reviewing the data for errors and anomalies, as well as formatting the data in a way that allows for connecting and joining in geographic information systems (GIS).

Road Layer Preprocessing

The MassDOT road layer was reviewed for any connectivity issues or inconsistencies. The following roadways were excluded from the analysis layer:

Interstates
Ramps
Pedestrian facilities
Bike Facilities
Tunnels
Access controlled segments
The resulting layer includes roadway segments with partial and full access.

Crash Layer Preprocessing

The crash data was obtained from the MassDOT IMPACT Crash Data Portal. Crashes that occurred on Interstates and ramps were removed to avoid attributing them to neighboring roadway facilities. The crash layers contain all the crash metadata including crash severity and whether the crash involves a vulnerable road user (VRU).

It should be noted that crash data within the City of Waltham show an overrepresentation of the fatal and serious injury crash categories that is not consistent with the previous years. This resulted in the municipality being overrepresented in both the regional and subregional HIN. To remain impartial towards the data, no adjustments have been made to balance the overrepresented fatal and serious injury crashes. Any efforts targeting or prioritizing projects in Waltham based on the regional or subregional HIN should consider this data quality concern when comparing the municipality’s roadways to neighboring municipalities.

Step 2—Create a 1-Mile Sliding Window

In the second step, a 1-mile sliding window was created that slides at 0.1-mile increments along each road. This sliding window allows for a localized analysis of crash data, enabling a detailed examination of specific segments of the road network. The movement of the window ensures that all road segments are covered in the analysis and that the largest groupings of crashes are identified. For roads less than a mile in length, the entire road was treated as a single segment.

Step 3—Create a 100-Foot Buffer

The third step involved creating a 100-foot buffer around each 1-mile window. This buffer is essential for capturing the crashes that can be attributed to the roadway segment, including those that were geolocated just outside the travel way. The team experimented with multiple buffer widths, and found a 100-foot buffer was best at addressing limited geolocation precision without attributing crashes to unrelated nearby segments.

Step 4—Aggregate the Crash Scores

In the fourth step, crash scores were aggregated within the created buffers. This aggregation process involved compiling data on crashes that occurred within the buffer. The aggregated scores were calculated based on equivalent property damage only (EPDO) crash cost scores. EPDO assigns a value for each crash based on the severity and the general cost of crashes classified under that severity, relative to property damage only crashes. Values for each crash within a given window/‌buffer are then added or aggregated together. The aggregation of EPDO scores provide valuable insights into the safety performance of each road segment by including both frequency and severity of crashes in a single metric. Table 1.1 provides the EPDO crash values used for the HIN.

Table 1.1 | HIN Crash Scoring

KABCO Severity Category	Non-VRU Crash Score	VRU Crash Score
Fatal Injury (K)	15	22.5
Suspected Serious Injury (A)	15	22.5
Suspected Minor Injury (B)	2	3
Possible Injury (C)	1	1.5
No Apparent Injury (O)	0	0

Step 5—Calculate Percentile Rankings

The final step of the HIN process was to calculate the ranking of the sliding window segments based on the buffer scores. This ranking helps to identify which segments of the road network have seen a higher rate of costly crashes compared to others based on reactive analysis of crash data. The team decided to set the threshold at the top five percent of the roads/crash scores to constitute the HIN. The top five percentile scores were selected to minimize the percentage of roads, while maximizing the coverage of the crashes. About 65 percent of the region’s fatal and serious injury crashes occurred on the HIN.

The Boston Region MPO chose to distinguish between the corridors in the HIN, the severe crash hotspots, and the other corridors with high crash frequencies but lower crash severity. As such, the corridors with two (2) or fewer fatal and serious injury crashes were defined as “corridors of concern’ and eliminated from the main HIN.

The HIN was created using a five-step systematic approach to assess and prioritize road safety. The approach utilizes network screening best practices for HIN development. It is also unbiased and replicable.

Analysis Findings

Coverage Statistics

Table 1.2 shows the coverage percentage of the HIN for each of the subregion’s fatal and serious injury crashes compared to the portion of roadway mileage in the subregion. The regional HIN provides substantial coverage of the region’s crashes.

Table 1.2 | HIN Coverage by Subregion

Subregion	HIN Coverage %	Road Length %
Inner Core Committee (ICC)	67.5%	8.7%
Minuteman Advisory Group on Interlocal Coordination (MAGIC)	64.4%	6.9%
MetroWest Regional Collaborative (MWRC)	48.3%	5.5%
North Suburban Planning Council (NSPC)	65.2%	7.1%
North Shore Task Force (NSTF)	61.6%	6.7%
South Shore Coalition (SSC)	67.7%	7.3%
South West Advisory Planning Committee (SWAP)	64.5%	6.7%
Three Rivers Interlocal Council (TRIC)	58.2%	6.9%
Boston Region MPO Regional Network	65.1%	6.9%

The HIN coverage statistics provide a measure of how concentrated or dispersed the crashes are within a certain network. The highest coverage is 67.7 percent for the SSC subregion and 67.5 percent for the ICC subregion, which indicates the crashes are slightly more concentrated, consistent with more urban settings and congested roadways. The lowest coverage is 48.3 percent for the MWRC subregion, which shows that crashes are slightly more dispersed, consistent with the suburban/rural land use types where the network has less traffic and opportunities for conflicts and driver errors are more spread out.

Regional HIN and Corridors of Concern

The regional HIN (as shown in Figure 1.2) is heavily concentrated around the ICC subregion due to the heavy traffic, congestion and opportunities for crash conflicts in the subregion. This is also impacted by the multimodal nature of this network and higher pedestrian and bike activity. Most of the identified corridors within the regional HIN have two or more fatal and serious injury crashes, since fatal and serious injury crashes are weighted heavily in the EPDO calculation. Few corridors were labelled as corridors of concern or locations with high EPDO scores despite lower severe crash totals.

Figure 1.2 | Regional HIN

Figure 1.2: A map showing the boundaries of the Boston Region MPO network with corridors of concern and the high injury network depicted in line segments.

Subregional HINs and Corridors of Concern

The subregional HINs (as shown in Figure 1.3) provide a clearer, more nuanced view of the roads that can be crash hotspots within each subregion. These are particularly useful to prioritize targeted safety investments when the projects are tied to geographies within the subregional boundaries. The subregional HINs have a higher percentage of corridors of concern identified than the Regional HIN. This is because the subregional HIN compares crash scores within each subregion, including some suburban/rural subregions that have much lower crash concentrations (and fatal and serious injury crash concentrations) than the ICC subregion.

Figure 1.3 | Subregional HIN

Figure 1.3: A map of the entire Boston MPO Region which displays road segments as lines depicting the crash hotspots within each of the eight subregions.

Municipal HINs and Corridors of Concern

The 97 individual municipal HINs (shown in Figure 1.4) provide a prioritization tool for each municipality to explore its own roadways and crash hotspots. Smaller municipalities with fewer roads and lower traffic volumes do not appear as frequently on the regional or the subregional HINs, thus the municipal HIN provides a context-sensitive comparison of their network and local roads. Municipalities can also partner with neighboring municipalities to create stronger improvements along roadway segments that transcend town barriers. The municipal HINs have the most corridors of concern identified, to support locations with high EPDO values, even where more than two fatal or serious injury crashes were not observed.

Figure 1.4 | Municipal HINs

Figure 1.4: A map of the Boston MPO Region with line segments depicting the high injury network in each of the 97 municipalities. The map is an example from the project on-line tool which allows users to focus in on specific municipalities to identify specific corridors of concern and high injury locations.

The following figures (Figure 1.5 through Figure 1.9) contain examples from five different municipalities that represent different land uses, ranging from heavily urban to rural contexts. The HIN for each of these municipalities provides prioritization of higher crash roadways within the municipalities and allows decision makers to prioritize these roadways for future safety improvements and funding.

Figure 1.5 | Quincy HIN and Corridors of Concern

Figure 1.5: A A map of Quincy, MA, a highly urban area of the region. Most major roads through Quincy are labeled as high-injury network locations.

Figure 1.6 | Revere HIN and Corridors of Concern

Figure 1.6: A A map of Revere, MA, a highly urban area of the region. Route 1A, Route 60, and parts of Route 107 are highlighted as high-injury network locations.

Figure 1.7 | Needham HIN and Corridors of Concern

Figure 1.7: A A map of Needham, MA, a suburban area of the region. Route 135 and roads that intersect with Route 135 are shown as high-injury network locations. Highland Avenue and West Street are highlighted as corridors of concern.

Figure 1.8 | Bolton HIN and Corridors of Concern

Figure 1.8: A A map of Bolton, MA, a rural town in the region. Parts of Route 117/Main Street are shown as both corridors of concern and a high-injury network location.

Figure 1.9 | Somerville HIN and Corridors of Concern

Figure 1.9: A A map of Somerville, MA, a highly urban area of the region. Broadway and Beacon Street are highlighted as corridors of concern. Multiple roads, including Route 2A, Route 28, Highland Avenue, Somerville Avenue, and Medford Street are shown as high-injury network locations.

2 The High-Injury Network and PTI Populations

An objective of Task 2.4 was to identify what Priority Transportation Investment (PTI) communities and populations are disproportionally exposed to high crash roads, as defined by the High-Injury Network (HIN) (developed in Task 2.3). The analysis conducted under Task 2.4 informs the prioritization of high-injury network corridors for targeted safety investments (Task 5 of the development of the Boston Region Vision Zero Action Plan).

Findings from the Task 2.4 analyses suggest that areas with a higher share of low-income, minority, and/or limited-English proficiency (L.E.P.) individuals also have a greater share of roadway segments included in the HIN.

Key Findings

Findings indicate that roadways in areas with a higher share of low-income, minority, and/or L.E.P. populations (and to a lesser extent areas with a relatively higher share of individuals with a disability) consist of a greater share of the HIN relative to the area’s roadway miles.

The top quintile (20 percent) of tracts with the highest share of low-income population accounts for 39.3 percent of the region’s low-income population (versus 17.6 percent of the region’s population) and has a share of the region's HIN that is over 2.3 times its share of the road network.
The top quintile (20 percent) of tracts with the highest share of minority population includes 39.2 percent of the region's minority population (versus 19.0 percent of the region’s population) and has a share of the region's HIN that is about 2.3 times its share of the road network.
The top quintile (20 percent) of tracts with the highest share of L.E.P. population accounts for 51.3 percent of the region's L.E.P. population (versus 19.6 percent of the region’s population) and has a share of the region’s HIN that is about 2.3 times its share of the road network.
The top quintile (20 percent) of tracts with the highest share of disability population accounts for 33.2 percent of the region’s disability population (versus 19.6 percent of the region’s population) and has a share of the region’s HIN that is about 1.5 times its share of the road network.

What Does this Mean?

Prioritization of safety investments in areas with a high share of minority, low-income, and L.E.P. populations would address the disproportionate number of crashes and support underserved communities.

Task Approach

Comparing the HIN to PTI Populations

The task objective was to identify communities that are disproportionally exposed to roadways with a high number of severe crashes. This task consisted of using GIS to compare the location of the HIN against the census tract demographics. Census tracts are a useful geography for this investigation as these areas tend to have the same boundary over the census years, generally an average population of about 4,000 people, and can be tied to various socio-demographic characteristics.

Defining Communities

There are various ways to consider PTI populations in the process of understanding whether the HIN falls disproportionally in different communities. For an initial investigation, two existing sources that define PTI populations were used: one based on the MPO’s definition of PTI populations and one based on U.S. DOT’s definition. Both databases define areas associated with protected populations under civil rights laws and environmental justice directives.1 Other sources were considered (e.g., CDC/ATSDR Social Vulnerability Index), yet these were not applied in the examination of the HIN because these sources use the same underlying data sets (U.S. Census surveys) and would result in similar outcomes.

PTI Populations, as defined by the Boston Region MPO

The Boston Region MPO provided a database of the region’s census tracts with the number and share of PTI populations associated with their definitions of (a) Low-income; (b) Minority; (c) limited English proficiency (L.E.P.); (d) Older Adults (age 75 or older); (e) Young People (age 17 and under); and (f) Disabled. In this database, a PTI area is defined as having a share of the PTI population that is higher than MPO region’s average for that PTI population.2

As described later in this memorandum, the project team explored variations of how to define a PTI area using the share of a PTI population and its percentile rank within the Boston Region.

Disadvantaged Neighborhood/Community, as defined by the U.S. DOT (ETC)

As an alternative to the Boston Region MPO’s PTI database, two datasets from U.S. DOT (the Equitable Transportation Community [ETC] Social Vulnerability index and the ETC Transportation Insecurity index) were analyzed to understand these indices relative to the HIN. The ETC Explorer tool is “an interactive web application that uses 2020 Census Tracts and data, to explore the cumulative burden communities experience, as a result of underinvestment in transportation.” The use of the tool is intended to “help ensure the benefits of DOT’s investments are addressing the transportation related causes of disadvantage” and to “understand how [an area] is experiencing [a] burden that transportation investments can mitigate or reverse.”3 Furthermore, U.S. DOT states that the ETC Explorer “provides MPOs, State DOT’s, and local decision makers tools to help select projects that meet the transportation needs of areas, which in turn will help strengthen communities and create more opportunities to improve daily life.”

This database is also organized by census tract. The ETC’s Social Vulnerability index is a measure of 13 socioeconomic indicators “that have a direct impact on quality of life. This set of indicators measure lack of employment, educational attainment, poverty, housing tenure, access to broadband, and housing cost burden as well as identifying household characteristics such as age, disability status and English proficiency.” The Transportation Insecurity index is intended to represent “when people are unable to get to where they need to go to meet the needs of their daily life regularly, reliably, and safely.”4

HIN Relative to Area Demographics

As noted by the Boston Region MPO’s own geographical analyses of PTI populations in the Boston region, in general, minority populations, people with low incomes, and people with limited English proficiency tend to live closer to or in the city of Boston, whereas people age 75 years or older, people age 17 years or younger, and people with disabilities are dispersed throughout the region.5 By exploring the association of the geographic distribution and concentrations of PTI populations against the location of the HIN, it can be determined whether a greater share of the HIN falls within areas with high concentrations of PTI populations.

The project team performed two sets of screening analyses:

An initial screening using defined areas for PTI populations (Boston Region MPO definition) or disadvantaged communities (U.S. DOT’s ETC indices).
A refined analysis to confirm the initial findings and point to which (and how) PTI populations could factor in the prioritization of the HIN for safety investments.

Initial Screening

Initial Screening: Boston Region MPO PTI Areas

Figure 2.1 and Figure 2.2 show the comparison between the share of the HIN and the share of the entire roadway network that overlap with specific PTI populations. Situations where the HIN overlaps more with PTI populations compared to the entire roadway network indicate a stronger correlation between those PTI populations and high-injury crash areas.

Comparing the PTI populations with the HIN produce the following findings:

In low-income and minority populations the HIN is over-represented compared to the overall roadway network. Both have more than double the share of roadway mileage (44 percent versus 22 percent and 46 percent versus 22 percent, respectively) in the HIN compared to the entire network.
While not as strong as low-income and minority populations, L.E.P. and disability populations are over-represented in the HIN network compared to the entire road network (7 percent versus 5 percent and 50 percent versus 38 percent, respectively).
While older and younger populations are not over-represented on the HIN, they remain important PTI populations.

Figure 2.1 | High-Injury Network in Relation to Low-Income, Minority, and L.E.P. Populations

Figure 2.1: Three pie chart comparing the share of the HIN and the share of the entire roadway network that overlap with specific Priority Transportation Investment populations as low income (44% of the HIN and 22% of total road network), minority (46% of the HIN and 22% of the road network), and limited English proficiency (7% of the HIN and 5% of road network).

Figure 2.2 | High-Injury Network in Relation to Disabled, Older, and Younger Populations

Figure 2.2: Three pie chart comparing the share of the HIN and the share of the entire roadway network that overlap with the disabled population (50% of HIN and 38% of road network), older population (47% of HIN and 55% of road network), and younger population (46% of HIN and 66% of road network).

Initial Screening: ETC Disadvantaged Community Areas

In addition to specific populations based on one PTI characteristic, the HIN can also be compared to more holistic PTI communities, such as:

U.S. DOT’s ETC Social Vulnerability Index includes various socio-economic indicators such as low-income, old population, younger population, disability, L.E.P., and others.
U.S. DOT’s Transportation Insecurity Index is related to barriers people face in performing their daily activities such as getting to jobs, getting to school, and getting to doctor’s appointments.

Results of this comparison are seen in Figure 2.3. The Social Vulnerability Index is significantly over-represented (40 percent versus 20 percent) in the HIN and the Transportation Insecurity Index is not over-represented (33 percent versus 52 percent).

Figure 2.3 | High-Injury Network in Relation to U.S. DOT ETC’s Disadvantaged Population Indices

Figure 2.3: Two pie charts depicting the comparison of USDOT ETC’s Disadvantaged Population Indices of social vulnerability (40% of HIN and 20% of road network) and transportation insecurity (33% of HIN and 52% of road network).

Refined Screening

Refined Screening: Boston Region MPO PTI Areas

In reviewing the Boston Region MPO’s census tracts based on their percentile rank associated with the share of each PTI population, areas with a higher share of minority, low-income, L.E.P., and (to a lesser extent) disabled populations tend to have a higher share of the HIN relative to the area’s roadways:

The top quintile (20 percent) of tracts with the highest share of low-income population accounts for 39.3 percent of the region’s low-income population (versus 17.6 percent of the region’s population) and has a share of the region’s HIN that is over 2.3 times its share of the road network.
The top quintile (20 percent) of tracts with the highest share of minority population accounts for 39.2 percent of the region’s minority population (versus 19.0 percent of the region’s population) and has a share of the region’s HIN that is about 2.3 times its share of the road network.
The top quintile (20 percent) of tracts with the highest share of L.E.P. population accounts for 51.3 percent of the region’s L.E.P. population (versus 19.6 percent of the region’s population) and has a share of the region’s HIN that is about 2.3 times its share of the road network.
The top quintile (20 percent) of tracts with the highest share of disability population accounts for 33.2 percent of the region’s disability population (versus 19.6 percent of the region’s population) and has a share of the region’s HIN that is about 1.5 times its share of the road network.
The top quintile (20 percent) of tracts with the highest share of youth population, accounts for 29.4 percent of the region’s youth population (versus 21.2 percent of the region’s population) and has a share of the region’s HIN that is about 0.6 times its share of the road network. The bottom quintile (lowest share of youth) has a share of the region’s HIN that is nearly twice its share of roadways.
The top quintile (20 percent) of tracts with the highest share of elderly population accounts for 34.8 percent of the region’s elderly population (versus 20.7 percent of the region’s population) and has a share of the region’s HIN that is about 0.85 times its share of the road network. The bottom quintile (lowest share of elderly population) has a share of the region’s HIN that is about twice its share of roadways.

Summary tables associated with this screening are provided below in Table 2.1 through Table 2.6.

Table 2.1 | Minority Populations and the HIN

Quintile	Population Totals			Share of MPO Population		Roadway Network
Quintile	Minority Population	Total Population	% Minority	Minority Population	Total Population	Share of MPO Road Miles	Share of HIN Miles	Ratio
1	479,667	636,800	75.3%	39.2%	19.0%	9.1%	20.8%	2.29
2	303,836	653,583	46.5%	24.8%	19.5%	12.5%	24.1%	1.92
3	203,697	648,715	31.4%	16.6%	19.3%	18.1%	22.3%	1.23
4	151,681	701,590	21.6%	12.4%	20.9%	26.9%	17.8%	0.66
5	84,934	716,506	11.9%	6.9%	21.3%	33.3%	14.9%	0.45
Total	1,223,835	3,357,194	36.5%	100.0%	100.0%	100.0%	100.0%	1.00