Understanding HIT Security Risks – The Ugly Truth!

On the Privacy and Security of Healthcare Records

By Richard J. Mata, MD, CIS

There is no privacy …  get over it.

Scott McNealy, Former Sun Microsystems CEO

Storing and transmitting health information in electronic form exposes it to risks that do not exist, or exist to a lesser extent, when the information is maintained in paper.  For example, although both paper-based and electronic systems need protection from fire, water, and wear and tear because of aging, electronic data is also vulnerable to hardware or software malfunctions that can make data inaccessible or become corrupt, and to non-secure policies that can make data vulnerable to illegal access.  In addition, cyber-crimes, and unauthorized intrusions originating both internally and externally, are increasing dramatically every year, costing companies millions of dollars.  Nonetheless, electronic medical records (EMRs) are usually considered more secure than paper patient charts because paper records lack an audit trail, papers are easily lost, and their contents can be illegible.

Take Care the Risks

Healthcare organizations must take the new risks seriously, however, because health information is a vital business asset, and protecting it preserves the value of this asset.  In addition, securing patients’ information protects their privacy and enhances the organization’s reputation for professionalism, patient well-being, and trustworthiness.  Hospitals, emerging healthcare organizations (EHOs), physicians, and healthcare entities long ago recognized the value of health information, and implemented security policies and procedures, but as they move more into the electronic arena, it is vital to revise and update policies and procedures to acknowledge the different risks inherent in the digital age.

Three Components of Security

The three classic components of information security are confidentiality, integrity, and availability.  Donn B. Parker, a pioneer in the field of computer information protection,[1] added possession, authenticity, and utility to the original three.  These six attributes of information that need to be protected by information security measures can be defined as follows:  

• Confidentiality: The protection and ethics of guarding personal information — for example, being cognizant of verbal communication leaks beyond conversation with associated healthcare colleagues.
• Possession: The ownership or control of information, as distinct from confidentiality — a database of protected health information (PHI) belongs to the patients.
• Data integrity: The process of retaining the original intention of the definition of the data by an authorized user — this is achieved by preventing accidental or deliberate but unauthorized insertion, modification or destruction of data in a database.  Make frequent backups of data to compare with other versions for changes made.
• Authenticity: The correct attribution of origin — such as the authorship of an e-mail message or the correct description of information such as a data field that is properly named.  Authenticity may require encryption.
• Availability: The accessibility of a system resource in a timely manner — for example, the measurement of a system’s uptime.  Is the intranet available?
• Utility: Usefulness; fitness for a particular use — for example, if data are encrypted and the decryption key is unavailable, the breach of security is in the lack of utility of the data (they are still confidential, possessed, integral, authentic and available).

Ethics

When these attributes are considered in the healthcare context, another factor comes into play: ethics.  According to Dr. J. A. Magnuson, professor of public health informatics at Oregon Health Science University’s Medical Informatics Program, privacy,[2] security, and ethics are inextricably intertwined, and all are critical to public health’s role as a trustee of the public’s data.  As public health becomes increasingly involved in Electronic Data Interchange (EDI;[3]), the information aspects of privacy, security, and ethics become ever more critical.  All doctors take an ethical oath to protect the patient, and the obligation to uphold this oath extends to health data management, even for employees who do not take an oath.

The fields of medicine and information technology (IT) each have separate and related ethical considerations.  Ethics may prohibit technology, for example, when using a specific application that would make a security breach likely.  However, ethics may also demand technology.  Suppose that a new surveillance application would improve public health — is it not ethically imperative to utilize it to save countless lives?  But suppose it also almost guarantees a security breach — what does the ethical position on use of the application become then?  That is an extreme example, though not completely unrealistic.

Varied Uses

Complicating the picture is the fact that IT in the healthcare arena has so many and varied uses.  For instance, office-, clinic-, and hospital-based medical enterprise resource planning (ERP) is based on the same back-end functions that a company requires, including manufacturing, logistics, distribution, inventory, shipping, invoicing, and accounting.  ERP software can also aid in the control of many business activities, like sales, delivery, billing, production, inventory management, quality management, and human resources management.  However, other applications particular to the medical setting include the following:

• The EMR, which has the potential to replace medical charts in the future, is feasible.[4]
• Healthcare application service providers (ASPs)[5] are available via Internet portals.
• Custom software production may produce more solution-specific applications.
• Medical speech recognition systems and implementation are replacing dictation systems.
• Healthcare local area networks (LANs), wide area networks (WANs), voice-over Internet protocol (IP) networks, Web and ATM file servers are ubiquitous.
• The use of barcodes to monitor pharmaceuticals is decreasing the chance of medication errors and warns providers of potential adverse reactions.
• Telemedicine and real-time video conferencing are already a reality.
• Biometrics will be used more often for data access.
• Personal digital assistant (PDA) wireless connectivity, which relies on digital or broadband technology including satellites, and radio-wave communications are increasingly common.
• The use of wireless technology in medical devices will be increasing.

No Healthcare Standardization

All of these applications offer advantages, but the security of these IT methods and devices is not yet fully standardized or familiar to health professionals; despite the CCHIT, Office of the National Coordinator for Health Information Technology, etc.  They all involve inherent security and privacy risks, and the prudent healthcare organization will want to ensure that these risks are identified and contained.  For instance, a single firewall or intrusion detection system (IDS) may not be enough.

The process must begin by conducting a security risk assessment — that is, doing a thorough assessment of current systems and data, and performing checks such as real-time intrusion testing, validation of data audit trails, firewall testing, and remediation when gaps or failed systems are exposed.  These activities are part of developing a healthcare security plan, including disaster recovery.

Privacy Officers

To ensure that the risk assessment is thorough, hospital network administrators and Privacy Officers should have a working knowledge of federal regulations and of the following security mechanisms:

• vulnerability assessment;
• security policy development;
• risk management;
• firewall assessment;
• security application assessment;
• network security assessment;
• incident response and recovery assessment;
• authentication and authorization systems;
• security products;
• firewall implementation;
• public key infrastructure (PKI) design;
• virtual private network (VPN) design and implementation
• intrusion detection systems;
• penetration testing;
• security program implementation;
• security policy assessment; and
• security awareness training.

The federal government has recognized the importance of health information security by establishing regulatory guidance with its Health Insurance Portability and Accountability Act of 1996 (HIPAA).

Assessment

IT system managers in healthcare settings are also familiar with the comprehensive security model offered by the International Standards Organization (ISO).  For instance, using ISO’s 17799 Code of Practice for Information Security Management, versions 2000, 2005, or 2010 information security is achieved by implementing a suitable set of controls to govern policies, processes, procedures, organizational structures and software and hardware functions.  The Code requires the IT manager to establish, implement, monitor, review, and where necessary, improve these controls to ensure that the specific security and business objectives of a healthcare organization are met.

Conclusion

The work of the National Institute of Science and Technology (NIST) in developing innovative technology for the healthcare sector is also of interest to IT system managers.  For instance, research on a computer note-writing system that captures clinical data automatically and a data repository system that captures patient data and integrates it with clinical decision support and knowledge bases are two of the initiatives that have originated with NIST.  In addition, the organization publishes numerous Special Publications that provide guidance on how to establish and maintain IT security.

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References:

[1]   Donn B. Parker developed the so-called Parkerian Hexad Principles, which discuss the attributes of information security.

[2]   Privacy generally refers to a ‘people’ context, a state of being free from unauthorized intrusion or invasion.  This concept is as applicable to medical records as it is to your own house.  Confidentiality is viewed more in the context of information, usually dealing with accessing and sharing information or data.

[3]   EDI involves electronic transmission methods, often utilizing networks or the Internet.[3]  The benefits of EDI include speed, data entry savings, and reduction of manual errors; the risks are legion.

[4]   Terms used in the field include electronic medical record (EMR), electronic patient record (EPR), electronic health record (EHR), computer-based patient record (CPR), etc.  These terms can be used interchangeably or generically, but some specific differences have been identified.  For example, an EPR has been defined as encapsulating a record of care provided by a single site, in contrast to an EHR, which provides a longitudinal record of a patient’s care carried out across different institutions and sectors.  However, such differentiations are not consistently observed.

[5]   An application service provider (ASP) is a business that provides computer-based services to customers over a network.