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MANAGING CYBER RISK

MANAGING CYBER RISK WITH SMART CYBER

NICK GALLETTO

COMPREHENSIVE STEPS TO KICKSTART YOUR JOURNEY

In the digital age, artificial intelligence (AI) technologies are starting to have the same kind of game-changing impact that factories and assembly lines had on manufacturing at the dawn of the industrial age, dramatically improving efficiency and enabling new products, services, and business models that simply were not possible before.

Driven by internal and external pressures to continuously evolve and mature their capabilities for mitigating and minimising cyber risk, organisations are actively exploring new technologies and improvement opportunities wherever possible.

AI is a hot topic, pushing innovation to new heights in many business areas. Advancements in AI technologies, processing capabilities, and data availability are enabling computer systems to perform tasks that once required human intelligence to execute. Examples of these include machine learning, natural language processing, speech recognition, computer vision, image comprehension, and robotics.

In cyber, AI technologies can improve threat intelligence, prediction and protection. It can also enable faster attack detection and response, while reducing the need for human cybersecurity experts – specialists who are in critically short supply these days. AI can learn from security analysts and improve its performance over time, leading to time savings and better decisions. These “smart cyber” capabilities are urgently needed as cyberattacks continue to grow in volume and sophistication.

Analytics and big data are a key enabler for AI, making it possible to process and analyse vast quantities of data – with parsing, filtering, and visualisation done in near-real time. The adoption of advanced analytics is also a critical step toward becoming an insight-driven organisation.

Smart cyber technologies span a broad spectrum, from rules-based automation that mimics human action to predictive AI that mimics or even surpasses human intelligence and judgement (Figure 1).

Figure 1 The spectrum of smart cyber technologies

BENEFITS OF SMART CYBER

By applying AI and advanced analytics on vast amounts of internal and external data, smart cyber technologies can generate predictive, usable insights that help you make better cyber decisions and protect your organisation from threats. They can also help you detect and respond to threats faster by monitoring the cyber environment with a level of speed and accuracy only machines can provide. Perhaps, most importantly, smart cyber helps you keep pace with today’s endless barrage of increasingly sophisticated attacks.

The traditional layered approach to cybersecurity is only capable of deterring and detecting the least sophisticated threats. Meanwhile, modern cyberattacks are being carefully designed to circumvent traditional security controls by learning detection rules. Also, traditional controls may not adequately address insider threats, which are an insidious form of attack from people with legitimate access.

By tapping into a wide range of data sources, smart detection platforms can learn and recognise normal behaviour, develop baselines and detect outliers, identify malicious actions that resemble previously seen events, and make predictions about previously unseen threats. These objectives cannot be achieved with traditional rules- and signature-based controls.

In addition, smart cyber technologies perform tasks in a highly consistent and repeatable way, reducing manual intervention and human errors. This has the extra benefit of making it easier to secure, manage, and audit the cyber environment to achieve compliance with government regulations and other external requirements.

Last but not least, smart cyber technologies can help you make the most of scarce cybersecurity talent. They enable your cyber teams to get the job done with fewer resources by first doing the heavy lifting on routine, labour-intensive tasks so human experts can focus on activities that are more valuable and strategic, and second, giving cyber specialists the tools to perform at a high level without requiring years of experience and training.

By tapping into a wide range of data sources, smart detection platforms can learn and recognise normal behaviour, develop baselines and detect outliers, identify malicious actions that resemble previously seen events, and make predictions about previously unseen threats.

GETTING IN FRONT OF RISKS WITH PREDICTIVE RISK INTELLIGENCE

Cyber risk management has typically been a reactive activity, focusing on risks and loss events that have already occurred. But with the rising adoption of advanced analytics and AI technologies, the practice is becoming more forward looking and predictive.

Predictive risk intelligence uses analytics and AI to provide advance notice of emerging risks, increase awareness of external threats, and improve an organisation’s understanding of its risk exposure and potential losses.

Monitoring activities now occur throughout the risk management lifecycle, and can be divided into three categories:

  • Reactive activities

Capture losses and identify near-miss past events. Develop baseline information to quantify the impact of losses from events. Report on the status of current risks and corrective actions.

  • Predictive activities

Accumulate and integrate internal and external information to provide reporting alerts in near-real time. Describe trends and emerging risks. Use reactive and integrated inputs to generate predictive risk insights with advanced analytics.

  • Integrated activities

Objectively measure risk performance by facilitating the development of key risk indicators, key performance indicators, and associated threshold measures. Enable an accurate description of risk exposure by providing a holistic view across the entire organisation.

WHERE TO START

Many companies are sitting on a wealth of valuable data that is buried beneath a jumble of inefficient and disconnected business processes, making it hard to know where and how to get started. To this end, Deloitte has developed a capability-based framework to identify specific areas where AI technologies and cyber analytics can be applied. The framework is depicted as a table that spans across four pillars of cybersecurity – Governance, Secure, Vigilant and Resilient (Figure 2).

Figure 2 The periodic table of cybersecurity elements

The following are some potential uses for automation in specific cybersecurity areas under the different pillars, which may include multiple elements in the table.

Element 4: Cyber risk management, metrics, and reporting

Governance and risk management

Informs overall strategy and improves reporting capabilities by using large volumes of contextual data and decision points to help with strategic decision making that aligns with the organisation’s risk appetite.

Regulation synthesis and mapping

Develops and maintains an organisation’s integrated security controls framework, extracting information from multiple regulatory sources and guidelines.

Assessment triggering

Conducts automated assessments periodically, or is triggered automatically by changes to applications and/or business processes.

KRI automation

Automates the collection and visualisation of key risk indicator metrics to enable the organisation to assess and address risk exposure.

Responsibility allocation

Uses self-service processes to allocate cybersecurity responsibilities across teams, improving efficiency and enabling closer alignment with risk owners.

Control testing

Automates control testing so that it continually assesses control effectiveness and provides near-real time updates about the organisation’s security posture.

Elements 17 and 18: Identify lifecycle management; Privileged access management

Role maintenance

Uses an AI engine to provide recommendations on role maintenance, helping organisations streamline the difficult, costly, and time-consuming task of keeping role definitions up to date.

Role mining engine

Extends the role maintenance engine to mine roles from multiple data sources, recommending new roles and entitlements.

Access request recommendation engine

Makes the access request process simpler by analysing various data sources – such as peer group access and historical access requests – and then recommending the level of access required for a user.

Access certification analytics

Analyses different data sets and applies analytics to improve the certification process by pre-approving certification items based on access request data, detecting anomalies in the attestation cycle, and using peer group data to calculate a confidence score that helps reviewers make informed decisions.

Access usage data for analytics engine

Incorporates access usage data into the analytics engine to help it generate more informed and efficient insights.

At the more sophisticated end of the technology spectrum, the following are some of the many potential uses for AI and analytics technologies in cybersecurity.

Element 15: System security

Control effectiveness

Augments and assesses the effectiveness of tried and tested tools such as firewalls, proxies, and data loss prevention solutions by monitoring the available log data and then identifying and remediating misconfigurations.

Element 27: Threat detection

Anomalous behaviour detection

Helps identify anomalous data access activity and malicious application activity by focusing on user logins, changes in user behaviour, and unapproved changes.

Threat discovery

Monitors activities and entities to establish normal behaviour, and detects sources of anomalies that could create potential risks such as fraud, money laundering, and insider threats.

Alert cleansing and prioritisation

Uses machine learning to significantly automate the first level of triage based on factors such as type of attack, frequency, and previous experience.

Targeted investigation and support

Uses a big data platform to drive new insights through historical analysis, thereby allowing investigations into incidents based on current and historical data to be done quickly and efficiently.

Element 25: Cyber threat intelligence

Cyber risk sensing

Identifies or predicts risks that are often difficult for humans and rules-based systems to detect, including new categories of risks, diffused risk signals, and potential sources of future risks such as increased use of social media.

Elements 28 and 30: Threat hunting and vulnerability management

Threat hunting

Quickly searches for new threats by importing known tactics, techniques, procedures, and attack patterns – along with vulnerability details and remediation information – to help neutralise threats early in the attack cycle.

Vulnerability scanning

Uses bots to initiate and scan applications, systems, and other assets for vulnerabilities, assessing risk and prioritising the patch schedule.

Configuration review

Uses bots to review system configurations to ensure baseline hardening and ensure no misconfigurations.

Attack path modelling

Performs predictive analytics on security data to determine vulnerable entry points and the likely path an attacker might use to gain access.

FROM FRAMEWORK TO PRACTICE

There are seven steps you can start taking today to boost your organisation’s cyber capabilities through the use of AI technologies and analytics.

Step 1 Embrace the future

Collaborate with your ecosystem to help shape the future of these powerful new cyber technologies.

Step 2 Educate yourself and your teams

Understand the business opportunities associated with AI technologies and analytics in cyber, immersing yourself in internal forums and decision-making processes to ensure you are a valuable contributor.

Step 3 Reassess the risk and threat landscape

Understand the impact of new technologies and develop appropriate risk management responses.

Step 4 Redefine your accountability model

Consider how changes in the operating environment will affect the risk landscape and required controls, and then adjust your cyber team’s roles and responsibilities accordingly.

Step 5 Rationalise your control framework

Encourage risk-intelligent design for new systems, technologies, and control frameworks to reduce unnecessary control layers and build more preventative and automated capabilities upfront.

Step 6 Start small and scale fast

Develop a practical strategy for applying AI technologies and analytics to cybersecurity by identifying opportunities with high impact, low complexity, readily available data, and insufficient current capabilities.

Step 7 Rethink your cyber talent strategy

Update your talent strategy, taking steps to ensure highly skilled cyber professionals are leading the way in your cybersecurity efforts.

AI technologies and analytics can lift your company’s cyber capabilities to the next level. By taking the lead on applying these disruptive innovations to cybersecurity, you can tip the balance in your favour and stay a step ahead of the threats.


Nick Galletto is Global and Canadian Cyber Risk Services Leader, Deloitte.