Category Archives: Gene Therapy Clinics


Chemotherapy Drugs Market Strategies, Major Industry Participants, Marketing Channels and Forecast To2018 2028 – Commerce Gazette

Chemotherapy is the type of treatment medication mostly used to treat cancer. The aim of chemo is to stop or prevent the growth of cancer cells. Chemotherapy mostly affects the rapid growing cancerous cells. In chemotherapy, a chemical drug is used to stop the growth of cancer cells. There are different types of chemotherapy drugs. Some of the chemotherapy drugs widely used for adjuvant and neoadjuvant chemo are Adriamycin, Ellence, Taxol, Taxotere, Cytoxan, Paraplatin, Abraxane, Navelbine, Xeloda, Gemzar, Ixempra, Halaven. All these chemotherapy drugs work on different phases of cell cycle. In chemotherapy, drugs can be given as monotherapy or in combination therapy. Chemotherapy drugs have a lot of side effects. During chemotherapy drugs treatment, many healthy normal cells get affected. According to the American Cancer Society Cancer statistics report 2018, newly diagnosed cancer cases is estimated to be 1,735,350 and around 609,640 cancer deaths occur in the United States. Moreover, according to Cancer Research U.K., 17 million new cancer cases were estimated worldwide and 9.6 million cancer deaths were recorded in 2018 and are projected to increase at an incidence rate of 62% worldwide during the forecast period 2018-2040.

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Chemotherapy has both pros and cons. The global chemotherapy drugs have significant potential that will drive the market. After an early stage cancer surgery, most of the oncologist follow chemotherapy drugs treatment to prevent further multiplication of cancerous cells which as a result will boost the chemotherapy drugs market. Apart from this, chemotherapy drugs have multiple benefits such as it helps to shrink the tumor cells, it reduces the growth of cancerous cells thereby increasing the life span of a person which as a result will increase the growth of chemotherapy drugs market. Development of treatment-related side effects is one of the significant disadvantages which may restrain the growth of chemotherapy drugs. Chemotherapy treatment is a time-consuming and lengthy process. Henceforth the chemotherapy drugs market may face challenges in the coming years as a new alternative has been developed such as immunotherapy, gene therapy and also high treatment cost may adversely affect the chemotherapy drugs market. Immunotherapy has become the area of interest in the treatment of cancer as it enhances the immune system to fight against the cancerous cells and also patients have minimal side effects unlike conventional therapies like chemotherapy or radiation. All these alternatives may suppress the growth of overall chemotherapy drugs market.

The global chemotherapy drugs market is segmented on the basis of types, route of administration and distributional channel. Market Segmentation by types Alkylating Agents Antitumor Antibiotics Plant Alkaloids Antimetabolites Topoisomerase Inhibitors Miscellaneous Antineoplastic Market Segmentation by route of administration Intravenous Oral Intramuscular Subcutaneous Market Segmentation by end users Hospitals Ambulatory Surgical Centers Clinics Others

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North America and Europe collectively hold the largest share in the chemotherapy drugs market due to advanced healthcare facilities which provide effective treatment options and also increase launch of new cancer drugs and its approval from FDA and EMA which as a result will increase the chemotherapy drugs market. The Asia Pacific also have the potential to increase the global chemotherapy drugs market due to the rising prevalence of cancer in this region and increasing government initiatives for public health policies is likely to drive the global chemotherapy drugs market. The Middle East and Africa are shown to have less potential in chemotherapy drugs market due to low budget in healthcare spending, inappropriate treatment facilities which overall may impact the overall chemotherapy drugs treatment.

Some of the key players leading in chemotherapy drugs market are Novartis AG, Amgen Inc., F. Hoffmann-La Roche Ltd, Sanofi, Eli Lilly and Company, Almatica Pharma, Inc., Celgene Corporation, Johnson & Johnson Services, Inc., Pfizer Inc., AbbVie Inc., Merck & Co., Inc., Exelixis, Inc, Servier Pharmaceuticals LLC, AstraZeneca Pharmaceuticals LP, Celltrion Inc., Genentech, Inc., Astellas Pharma US Inc., Loxo Oncology Inc., Bayer HealthCare Pharmaceuticals Inc., Wyeth Pharmaceuticals Inc., Jazz Pharmaceuticals, Inc., Bristol-Myers Squibb Company, Puma Biotechnology, Inc., EMD Serono, Inc. Takeda Pharmaceutical Company Limited, Tesaro, Inc., Clovis Oncology, Inc., and others.

The report covers exhaustive analysis on: Chemotherapy drugs Market Segments Chemotherapy drugs Market Dynamics Historical Actual Market Size, 2013 2017 Chemotherapy drugs Market Size & Forecast 2018 to 2028 Chemotherapy drugs Current Trends/Issues/Challenges Competition & Companies involved Chemotherapy drugs Market Drivers and Restraints

Regional analysis includes North America Latin America Europe Asia Pacific Middle East & Africa

Report Highlights: Shifting Industry dynamics In-depth market segmentation Historical, current and projected industry size Recent industry trends Key Competition landscape Strategies for key players and product offerings Potential and niche segments/regions exhibiting promising growth A neutral perspective towards market performance

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Chemotherapy Drugs Market Strategies, Major Industry Participants, Marketing Channels and Forecast To2018 2028 - Commerce Gazette

Targeted Cancer Therapies Market Regional Landscape, Production, Sales & Consumption Status and Prospects 2025 – Commerce Gazette

Targeted cancer therapies are drugs that are actively involved in blocking the growth of cancer by interfering with specific molecules which are responsible for the growth, progression, and spread of cancerous cells. These therapies are also known as precision medicines. Targeted cancer therapy is different from standard chemotherapy treatment as these therapies target only cancerous cells without affecting the normal cells. Also targeted cancer therapy block tumour cell proliferation, whereas standard chemotherapy kills the tumour cells. Recently targeted cancer therapies have gained increasing focus in anti-cancer drug development industry as these therapies forms the main branch of precision medicine i.e. a form of medicine that uses molecular diagnostic techniques to prevent, diagnose, and treat cancer. Targeted cancer therapies market comprises of the drugs used as precision medicine for treating malignant and benign tumours. Many drugs in targeted cancer therapies have been approved by FDA to treat various types of cancer and have been commercialized, whereas numerous cancer therapies are being studied in clinical trials and many are in preclinical testing.

Targeted cancer therapies market is growing, this is attributed to increasing prevalence of various types of cancers such as lung cancer, breast cancer, colorectal cancer, prostate cancer, lymphoma, leukaemia, melanoma etc. Also increasing awareness regarding molecular diagnostic techniques such as liquid biopsy to detect malignancy is expected to drive the market for targeted cancer therapies over the forecast period. Growing healthcare expenditure, and rising insurance coverage, aids in the revenue growth of targeted cancer therapies market. Increasing number of new targeted anti-cancerous drugs also drives the market for targeted anti-cancer drugs. However higher pricing of these drugs along with higher pricing of the molecular diagnostic tests to detect cancer is expected to hamper the growth of the targeted cancer therapies market over the forecast period.

The targeted cancer therapies market is segment based on the therapy type, end user and application

Targeted cancer therapies market is segmented into following types:

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By Therapy Type Hormone Therapies Signal Transduction Inhibitors Gene Expression Modulators Apoptosis Inducers Angiogenesis Inhibitors Immunotherapies Monoclonal Antibodies

By Disease Indication Gastrointestinal Lung Cancer Breast Cancer Colorectal Cancer Leukemia Lymphoma Melanoma Prostate Cancer Others

By End User Hospitals Cancer and Radiation Therapy Centers Clinics

Targeted cancer therapies market revenue is expected to grow at a significant rate, over the forecast period. The market is anticipated to perform well in the near future due to increasing awareness regarding various cancer types and their treatment protocols. Also the targeted cancer therapies market is expected to expand globally due increasing prevalence of cancer and increasing preference of oncologists to prescribe targeted anti-cancer drugs for the patients. The targeted therapies for lung cancer is anticipated to grow with a fastest CAGR over the forecast period, attributed to increasing number of smokers globally. Increasing competition among anti-cancer drug manufacturers, increasing investment in R&D and increasing number of new drug launches are the major factors estimated to drive the revenue growth of targeted cancer therapies market.

Depending on geographic region, the targeted cancer therapies market is segmented into five key regions: North America, Latin America, Europe, Asia Pacific (APAC) and Middle East & Africa (MEA).

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North America is occupying the largest regional market share in the global targeted cancer therapies market owing to the presence of more number of market players, high patient awareness levels, increasing healthcare expenditure and relatively larger number of R&D exercises pertaining to drug manufacturing and marketing activities in the region. Also Europe is expected to perform well in the near future due to increasing inclination of oncologists and physicians in the region prescribing targeted anti-cancerous drugs to the patients suffering from cancer.

Asia Pacific is expected to grow at the fastest CAGR because of increasing prevalence of different types of cancers in the region, thus boosting the market growth of targeted cancer therapies market throughout the forecast period.

Key players of targeted cancer therapies market includes Abbott Laboratories, Bayer HealthCare AG, GlaxoSmithKline plc, OncoGenex Pharmaceuticals Inc., Hospira Inc., Boehringer Ingelheim GmbH, AstraZeneca, Aveo Pharmaceuticals and many more. The companies in targeted cancer therapies market are increasingly engaged in strategic partnerships, collaborations, mergers and acquisitions to capture a greater pie of market share as the market is in the nascent stage.

The research report presents a comprehensive assessment of the market and contains thoughtful insights, facts, historical data, and statistically supported and industry-validated market data. It also contains projections using a suitable set of assumptions and methodologies. The research report provides analysis and information according to categories such as market segments, geographies, types, technology and applications.

The report covers exhaustive analysis on: Market Segments Market Dynamics Market Size Supply & Demand Current Trends/Issues/Challenges Competition & Companies involved Technology Value Chain

Regional analysis includes North America (U.S., Canada) Latin America (Argentina, Mexico, Brazil, Rest of Latin America) Europe (Germany, Italy, France, U.K., Spain, Russia, Rest of Europe) Asia Pacific (China, India, Japan, Rest of APAC) Middle East and Africa (Rest of MEA, S. Africa)

The report is a compilation of first-hand information, qualitative and quantitative assessment by industry analysts, inputs from industry experts and industry participants across the value chain. The report provides in-depth analysis of parent market trends, macro-economic indicators and governing factors along with market attractiveness as per segments. The report also maps the qualitative impact of various market factors on market segments and geographies.

Report Highlights: Detailed overview of parent market Changing market dynamics in the industry In-depth market segmentation Historical, current and projected market size in terms of volume and value Recent industry trends and developments Competitive landscape Strategies of key players and products offered Potential and niche segments, geographical regions exhibiting promising growth A neutral perspective on market performance Must-have information for market players to sustain and enhance their market footprint.

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Targeted Cancer Therapies Market Regional Landscape, Production, Sales & Consumption Status and Prospects 2025 - Commerce Gazette

Precision Cancer Therapies Market to Witness Comprehensive Growth by 2017 2025 – Technology Trend

Precision medicine (PM) can be defined as predictive, personalized, and preventive healthcare services delivery model. Precision cancer therapies is an additional option for patients suffering from cancer however it cannot completely replace the existing cancer treatments. Currently, researchers are making progress in the field of precision cancer therapies however many new and innovative drugs are currently in clinical trials. Precision cancer therapies include drugs or other substances which block the growth of cancer. Precision cancer therapies are also termed as molecular targeted therapy, or targeted molecular therapies, and precision medicines. Researchers are involved in developing anticancer drug developments via precision cancer therapies.

Precision Cancer Therapies Market: Segmentation

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Precision cancer therapies market can be segmented on the basis of the type of therapies, end users, and regions: Hormone Therapy Immunotherapies Targeted Therapy Monoclonal Antibody Therapy Gene Therapy

Precision cancer therapies market can be segmented on the basis of different end users in the market: Hospitals Diagnostic Centers Oncology Clinics Research Institutes

Precision Cancer Therapies Market: Dynamics

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Precision cancer therapies market is primarily driven by a few key factors such as the increasing prevalence of cancers, such as lung cancer, breast cancer, prostate cancer, melanoma and other types of cancers. The market is likely to grow owing to the increasing awareness regarding molecular diagnostic techniques which is expected to fuel the growth of precision cancer therapies market. The rising insurance coverage and growing healthcare expenditure by the government are among the factors which would aid the growth of precision cancer therapies market over the forecast years.

Precision cancer therapies market, however, faces various challenges such as the high cost of new and innovative therapies which prevent the wide prevention of these diseases. Precision cancer therapies market has various drugs which are still in various stages of clinical trials which refrain the products from the market. Precision cancer therapies market faces tremendous challenges due to the low awareness regarding the new diagnosis and treatment measures. Low-income countries and rising economies are coming forward to address such issues for precision cancer therapies market.

Precision Cancer Therapies Market: Region-wise Outlook

Based on geography, the precision cancer therapies market can be segmented into five major regions: North America, Europe, Asia-Pacific, Latin America and Middle East & Africa. At present, North America holds a leading position in the precision cancer therapies market due to the increasing incidence of cancer in the region which is followed by Europe. The major driving factors which have driven the growth of the precision cancer therapies market in this region is constant support of healthcare organizations in the development of new treatment methods, technological advancement in finding innovative treatment measures, and a rise in funding in public and private sector. Following North America, European countries are also anticipated to show steady growth in the precision cancer therapies market. Asia Pacific is expected to grow at the fastest CAGR because of increasing prevalence of different types of cancers in the region, thus boosting the market growth of precision cancer therapies market throughout the forecast period. The factors which would fuel the growth of precision cancer therapies market in Asia-Pacific are various multinational companies are setting up their operations in this region and aiming to gain huge revenue share from emerging countries, rising healthcare concerns, and improving healthcare scenario of the region. Precision cancer therapies market would evolve at a rapid rate across the regions. However, North America would maintain its position in the precision cancer therapies market, though, we are anticipating emerging economies such India, China, Brazil, Russia to have the highest growth in precision cancer therapies market.

Precision Cancer Therapies Market: Key Players

Precision cancer therapies market holds a huge number of players operating in the segment for years with expertise and experience. Various multinational companies are involved in the manufacturing of products which are utilized in the treatment of cancer. Such companies are Abbott Laboratories, Bayer HealthCare AG, GlaxoSmithKline plc, OncoGenex Pharmaceuticals Inc., Hospira Inc., Boehringer Ingelheim GmbH, AstraZeneca, Aveo Pharmaceuticals among others. Precision cancer therapies market has the presence of many regional players which have a huge market share in the emerging countries.

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Precision Cancer Therapies Market to Witness Comprehensive Growth by 2017 2025 - Technology Trend

Biological Product Manufacturing Market Analysis, Size, Regional Outlook, Share, Trend, Growth, Analysis and Forecast – Rapid News Network

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Biological products or biologics are therapeutic preparations that consist of natural complex biomolecules derived from living things. Active pharmaceutical ingredients (API), vaccines serum, and hematological products (whole blood and plasma derivatives), recombinant DNA products, cell cultures (micro-organisms or eukaryotic cells), gene therapy and cell therapy products, antigens, allergens, antivenoms, etc. are some examples of biological products. Due to the recent advances in supply chain management and favorable federal regulations, the biological products manufacturing industry has become a lucrative market for startups, contractual manufacturing companies, and strategic collaborations, equipped with skilled workers and affordable pricing. Increase in investments for R&D by various organizations, with an aim of manufacturing cost reduction and economical yet sustainable biological product manufacturing are serving as opportunities for many companies and collaborations in biological product manufacturing industries.

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Major market players in the global biological product manufacturing market have various advantages such as cutting edge technologies, superior research and development, technologically advanced instruments, and skilled workforce to ensure proper assembly and delivery of the product. The biological product manufacturing market is driven by extensive R&D, along with increasing demand from health care providers across the world for advanced biological products, and growing focus by market players to provide quality products. However, competitive costs of therapeutic products, requirement of highly skilled labor for high value low volume biological product manufacturing, limited availability foreign capital, and stringent regulatory affairs regarding the manufacture of biological products are restraining the global biological product manufacturing market.

The global biological product manufacturing market has been segmented based on product type, end-user, application, and region. In terms of product type, the market is classified into bio-pharmaceutical products and biotechnological/biological products. The bio-pharmaceutical products segment includes vaccines, immunoglobulins, serum and other blood related product, allergens, antigens, antivenoms, and toxoids. The biotechnological/biological products segment includes micro-organism or eukaryotic cell culture, recombinant DNA technology products, gene therapy product, and cell therapy product. The biopharmaceuticals products segment accounted for the largest share of the global biological product manufacturing market. Based on end-user, the biological product manufacturing market has been segmented into hospitals, research and academic institutes, clinics and specialty trials, diagnostic labs, and others. The hospitals end-user segment accounted for the largest share of the global biological product manufacturing market, followed by research and academic institutes.

Superior technological advancements serve as a major opportunity in the biological product manufacturing market. Rising incidence of chronic diseases across the world, availability of better diagnostic facilities, advances in the drug discovery and pharmaceutical R&D sector, and rising government initiatives are some of the factors attributed to the high growth of the biological product manufacturing market. Increasing focus on discovery of heat labile or temperature sensitive products, advanced biopharmaceutical research in medicine, and invention of effective means to treat various diseases are expected to boost the growth of the biological product manufacturing market.

In terms of region, the global biological product manufacturing market has been segmented into five regions: North America, Europe, Asia Pacific, Latin America, and Middle East & Africa. The market in Asia Pacific is projected to expand at a higher CAGR during the forecast period driven by factors such as low labor cost, less capital investment for manufacturing, increasing adoptions of new techniques in manufacturing of biological product, and favorable governmental policies. North America dominated the global biological product manufacturing market in 2015 due to factors such as new and technologically advanced products introduced in the market, significant investments in research and development of advanced products, and increasing patient demand for better health care facilities.

Key players in the biological product manufacturing market are Lonza, Advanced Life Sciences Holdings, Inc., Pfizer, Inc., Johnson & Johnson, Invitrogen, Amgen, Abbott Laboratories, Piramal Healthcare, and Shenhua Group Corp. Ltd. The report offers a comprehensive evaluation of the market. It does so via in-depth qualitative insights, historical data, and verifiable projections about market size. The projections featured in the report have been derived using proven research methodologies and assumptions. By doing so, the research report serves as a repository of analysis and information for every facet of the market, including but not limited to: Regional markets, technology, types, and applications. The study is a source of reliable data on: Market segments and sub-segments Market trends and dynamics Supply and demand Market size Current trends/opportunities/challenges Competitive landscape Technological breakthroughs Value chain and stakeholder analysis The regional analysis covers: North America (U.S. and Canada) Latin America (Mexico, Brazil, Peru, Chile, and others) Western Europe (Germany, U.K., France, Spain, Italy, Nordic countries, Belgium, Netherlands, and Luxembourg) Eastern Europe (Poland and Russia) Asia Pacific (China, India, Japan, ASEAN, Australia, and New Zealand) Middle East and Africa (GCC, Southern Africa, and North Africa) The report has been compiled through extensive primary research (through interviews, surveys, and observations of seasoned analysts) and secondary research (which entails reputable paid sources, trade journals, and industry body databases). The report also features a complete qualitative and quantitative assessment by analyzing data gathered from industry analysts and market participants across key points in the industrys value chain. A separate analysis of prevailing trends in the parent market, macro- and micro-economic indicators, and regulations and mandates is included under the purview of the study. By doing so, the report projects the attractiveness of each major segment over the forecast period. Highlights of the report: A complete backdrop analysis, which includes an assessment of the parent market Important changes in market dynamics Market segmentation up to the second or third level Historical, current, and projected size of the market from the standpoint of both value and volume Reporting and evaluation of recent industry developments Market shares and strategies of key players Emerging niche segments and regional markets An objective assessment of the trajectory of the market Recommendations to companies for strengthening their foothold in the market Note:Although care has been taken to maintain the highest levels of accuracy in TMRs reports, recent market/vendor-specific changes may take time to reflect in the analysis.

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Biological Product Manufacturing Market Analysis, Size, Regional Outlook, Share, Trend, Growth, Analysis and Forecast - Rapid News Network

Google Bans Advertising on Unproven Medical Treatments (like Stem Cells) – Bedford Bulletin

Closing out the first week of September, Google said it will no longer allow the posting of ads for unproven or experimental medical techniques.This includes, mostly, advertising that discusses or describes stem cell therapy, cellular therapy, and gene therapy.The Mountain View, CA-based technology giant said that this complex decision comes as a means to quell a rise in bad actors who try to take advantage of vulnerable people by offering untested, deceptive treatments.

In a recent blog post, Google said, These treatments can lead to dangerous health outcomes and we feel they have no place on our platforms, specifically ads for medical treatments with no established biomedical or scientific basis.

If this seems arbitrary to you then you may not have seen any of the onslaught of new ads from stem cell clinics across the United States looking to sell unapproved therapies which, they claim, can treat a wide range of ailments. This might include everything from arthritis to Alzheimers disease, from macular degeneration to multiple sclerosis.

And if you have not seen any of this type of advertising, you might want to be prepared to start.Stem cell clinics have been growing quickly as an emerging direct-to-consumer industry.And their growth may be largely due to the excitement generated by advertising the vast number of conditions that stem cells can supposedly treat.As a matter of fact, scientists and medical associations alike have commented that these unsupported claims make stem cell therapy like a modern snake oil that specifically aims to prey on seriously illand terribly vulnerablepatients.

While stem cell research has certainly had its breakthroughs, claiming that it can treat such a broad canvas of ailments is dangerous. Unfortunately, some stem cell treatments have already resulted in serious injury in some patients. Specifically, at least five women have reported going blind after a stem cell clinic injected their product directly into their eyes.

At the same time, some stem-cell industry representatives are criticizing Googles new ad policy. The argument is that this ban unfairly discriminates against good companies because there is no determination as to which companies actually provide a safe, FDA-verified procedure.Of course, Google should not have be a regulator in this industry, so the ban is more of an attempt to avoid any involvement with the potential risks.

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Google Bans Advertising on Unproven Medical Treatments (like Stem Cells) - Bedford Bulletin

4 Barriers To Cell And Gene Therapy Development For Rare …

By Ben Solaski and Perry Yin, Ph.D., PA Consulting

Rare diseases, as defined by the Orphan Drug Act, are diseases that affect less than 200,000 people. Given that approximately 80 percent of the 7,000 known rare diseases are caused by a single-gene defect,1 there has been increased research in the development of cell and gene therapies to treat rare diseases.

However, a number of challenges hinder these efforts, including pricing and reimbursement, the high cost of bringing these drugs to market, unique manufacturing and supply chain challenges, and our current limited understanding of disease pathology and progression. While these challenges may seem common across other drug markets, in the case of rare diseases, these challenges are exacerbated by limited patient populations. In this article, we look at the four challenges in greater depth and explore potential responses to help pharma companies be successful in bringing these products to market.

1. Making Commercialization Viable By Tackling High Costs Together

Given the small patient population, and the high price of drugs aimed at rare diseases, how can we ensure the long-term commercial viability of these drugs? This challenge can be explored from two points of view - how health authorities can promote scientific advancements while also protecting investments in rare disease development and how pharma can collaborate with payers to find better pricing solutions to reduce hurdles for patients to receive treatment.

Over the years, the FDA has taken concrete steps to incentivize the industry to develop drugs for rare diseases. In 2017, the FDA sought to eliminate the backlog for orphan drug requests by responding to future requests within 90 days.2 More recently, the FDA released a Draft Guidance on Human Gene Therapy for Rare Diseases, which pledges that the FDA will be involved with drug companies earlier in the development process. This will not only help streamline development by helping limit the number of preclinical or other preparatory studies but will also lower development costs and increase speed to market.3 But is this enough? There is ongoing debate in the pharma industry that the FDA needs to go even further. For example, while the agency already grants a longer exclusivity period for orphan drugs, this seven-year period is usually outlasted by the 20-year protection offered by patents.4 To sweeten the deal, the FDA may need to consider offering increased protection by expanding this exclusivity period. This would make these drugs more commercially viable, better ensuring capture of initial and ongoing investment in small markets or providing an option for improved pricing scenarios.

On the payer front, as the healthcare industry shifts toward value-based healthcare, orphan drugs and cell and gene therapies that have been prohibitively expensive will be prime candidates for emerging pricing models derived from measuring health outcomes against the cost of treatment. One great example is Novartis CAR-T treatment, Kymriah. For this treatment, Novartis only receives payment if the patient shows significant improvement within a month; otherwise, Novartis bears the cost. The use of value-based pricing models for cell and gene therapies would ease the amount of risk that payers take on when reimbursing these treatments, while also increasing the likelihood that patients will have access to these drugs.

With higher rates of approvals, longer periods of exclusivity, and greater utilization of value-based pricing, cell and gene therapies for rare diseases will have a greater chance of both reaching patients and being commercially successful.

2. Improving Clinical Development: A New Age In Clinical Trial Design And Recruitment

Companies developing cell and gene therapies for rare diseases are confronted with many of the same challenges faced by more traditional drugs; however, these challenges are amplified. These challenges include small patient populations, high mortality rates, and lack of disease state understanding, making it difficult to set clinical endpoints.

Seeking to address this, the FDAs Draft Guidance on Human Gene Therapy for Rare Diseases focuses on new clinical trial designs. What will these trials of the future look like? Gone are the days of three-phase randomized, controlled clinical trials. New age trials for rare diseases will be shorter, combining phases to show both safety and efficacy. Later stage trials will be replaced with rollover studies to see longer-term effects of treatment. Control groups will be replaced with natural history studies to illustrate what happens when patient groups go untreated. Natural history studies will also help to identify surrogate endpoints that can serve as early indicators of future outcomes to help expedite trials.

While these trial designs will help improve the process, there is still the inherent issue of recruiting from such small and geographically diverse patient populations. To ease this, there will be increasing demand for accurate patient registries that include relevant information about potential biomarkers for treatment. GSKs partnership with 23andMe is a good example of how this would work. Genetic data is captured through commercial genetic testing, then used to drive novel drug development and identify patients with specific rare diseases for trial recruitment. Pharma and CROs will also leverage increased use of digital technology to execute remote or highly fragmented multisite trials, making trial participation easier for patients.

Streamlining the clinical trial pathways for gene therapy and rare diseases, as well as reducing the burden on the patient, allows pharma companies to accelerate products to market.

3. Overcoming The Challenges Of Manufacturing And Supply Chain By Partnering With Contract Manufacturer Organizations

There are two major manufacturing challenges. The first is addressing the need for new infrastructure such as advanced supply chains, since the effective handling of these treatments will often require a high degree of customization for the patient (e.g., CAR T cell therapies). The other challenge lies with rare disease and cell and gene therapy products, whose manufacturing requires specialized skills where there is little room for error. As such, organizations will need to decide if they will build the capability or leverage contract organizations.

To address these challenges, in the short term, it is essential that companies have robust chain of custody protocols and supporting technologies to track and monitor these drug products from factory to patient. This ensures the correct patient is getting the therapy that was specifically designed for them, and that the conditions in transit do not damage the drug product. Longer term, the rise of a larger number of small manufacturing sites spread across the country is expected. Smaller manufacturing sites distributed in key geographic regions reduce shipping time, thus reducing the possibility for delays. Taking this one step further, imagine a world where manufacturing sites do not exist, and hospitals or clinics will have the capability and infrastructure to perform specialized manufacturing on-site.

How can pharma get to a commercial scale to support successful complex manufacturing requiring specialized skills? One solution is to outsource manufacturing to contract manufacturing organizations (CMOs) that specialize in gene therapies and rare diseases, similar to the way that clinical research has increasingly relied on contract research organizations (CROs). CMOs manufacture the product as a service and use their expertise to produce high-quality product at a reduced cost.

By using specialists to support the manufacturing process and technology to monitor and localize the supply chain, companies can reduce the risks involved in getting high-quality products to patients.

4. Increasing Our Understanding Of Disease States: The Rise Of Natural History Studies And Companion Diagnostics

Currently, there is a lack of understanding of rare diseases, especially around diseases variations and subtypes. This creates the challenge of how to better identify these variations to develop treatments that are then targeted at a specific disease subtype.

Pharma companies will need to spend more time and effort understanding disease states. For rare diseases, natural history studies are critical to provide insight that could help to drive early development, and even serve as a control group in single-arm studies if randomized, concurrent controlled trials are not feasible.5 Natural history studies may also help identify biomarkers that will help tailor these cell and gene therapies to be more personalized to specific subgroups of patients, allowing companies to be more focused in the development process.

Furthermore, to get the best results from treatment, the patient population that would benefit most from treatment needs to be identified. Thus, the industry will likely see an increase in products entering the market that include a companion diagnostic. Both the FDA and payers have an incentive to require drug manufacturers to develop these diagnostics in parallel with drug projects to ensure the best patient outcomes possible. Advancements in next-generation sequencing techniques will make identifying these subgroups easier and more accurate, potentially leading to a one size fits all genetic test that could be applied to all rare disease products.

Genetic tests, combined with an increase in understanding of natural history and disease biomarkers, will ensure the correct patients are receiving the therapies being developed.

Conclusion

Cell and gene therapies for the rare disease space are still emerging and will continue to face new challenges around development, the evolving regulation landscape, pricing and reimbursement, and manufacturing. Despite these challenges, the first products have already reached the market. New approaches and solutions, such as some of those outlined in this article, will go a long way to meeting these challenges and reducing the barriers to entry, allowing pharma to bring these products to market more quickly and affordably.

References:

About The Authors:

Ben Solaski is a life sciences expert at PA Consulting. With his training as a biomedical engineer, he has extensive experience with the development of gene editing technologies and an understanding of their potential to disrupt the industry. Contact him on LinkedIn at https://www.linkedin.com/in/benjaminsolaski/.

Perry Yin, Ph.D., is a life sciences expert at PA Consulting, where he leads the Cell and Gene Therapy group. He has experience developing technologies like CRISPR and stem cell-based therapies from concept to animal testing for both cancer and regenerative medicine applications. Contact him on LinkedIn at https://www.linkedin.com/in/yinperry/.

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Gene Therapy: The New Frontier for Inherited Retinal Disease

In the past 15 years, research in the field of retinal gene therapy has exploded. While no treatments have yet been approved for any inherited retinal dystrophies, clinical trials involving retinal gene therapy are creating hope for future therapies for afflicted patients. Consequently, retina specialists must now be able to appropriately diagnose counsel patients with retinal dystrophies who may be candidates for clinical trials.

This article will focus on updates in retinal gene therapy with an introduction to viral-based gene therapy, followed by a discussion of current retinal gene therapy clinical trials. The goal is to give the retina specialist a framework for evaluating and counseling these patients as they come through our clinics.

Inherited Retinal Disease: A Brief Review Inherited retinal diseases can be categorized by anatomic location in the eyethe macula, fovea, choroid or vitreous. Some diseases are more diffuse and affect all photoreceptors in the retina with varying degrees of insult to either rods or cones.

stationary or progressive. Stationary diseases are typically early onset, such as congenital stationary night blindness, whereas progressive diseases tend to be of later onset, such as retinitis pigmentosa (RP). Other inherited retinal diseases are part of larger syndromes or associated with systemic disease (Table 1).

Multiple clinical trials are ongoing for many of the diseases listed in Table 1. RP, the most common retinal dystrophy, has a prevalence of roughly 1:4,000.1 RP associated with the MERTK gene (for MER proto-oncogene tyrosine kinase) is an autosomal recessive form of the disease that is the subject of a retinal gene therapy clinical trial.2

Stargardt disease is another common retinal dystrophy (prevalence: roughly 1:8,000)3 that is the focus of multiple clinical trials, including a subretinal lentivirus gene therapy trial,4 a stem cell therapy trial5 and an oral drug trial.6 Less prevalent diseases, including Leber congenital amaurosis (LCA), achromatosopia, X-linked retinoschisis (XLRS), Usher syndrome and choroideremia, are all subjects of current gene therapy clinical trials. Given these clinical trials, the need for accurate diagnosis and counseling has substantially increased.

A typical examination of a retinal dystrophy patient starts with a detailed history, with a particular focus on family history, followed by a comprehensive ophthalmologic exam. Imagingparticularly optical coherence tomography, fundus photography and autofluorescenceelectrophysiologic testing and visual field testing can also play an important role in the evaluation.

A common misconception about inherited retinal disease is that the lack of a family history argues against a genetic origin of disease. The majority of inherited retinal diseases are passed on in an autosomal recessive pattern, and often the proband (or affected individual) is the only reported person in a large family pedigree. Children of carriers of a recessive disease have only a one-fourth chance of having the two mutated alleles.

Similarly, the likelihood for a patient with autosomal recessive disease to pass the disease to offspring is remarkably low if the other parent is unaffected, and the prevalence of the carrier state of most retinal dystrophy mutations is quite low in the general population. Obviously, consanguinity can markedly increase the likelihood of seeing recessive disease manifesta phenomenon known as pseudo-dominance. Eliciting this history in the clinical examination can help us better predict the inheritance pattern.

Once we establish a clinical diagnosis and an inheritance pattern, we may offer genetic testing for confirmation of disease.

Genetic Testing for Retinal Dystrophies The key to developing possible gene-based therapies is efficient and accurate genotyping. Gene therapy is effective only when the genetic defect is identified in a given inherited retinal dystrophy. In the past 35 years, more than 200 retinal dystrophy genes have been identified and another 50 have been mappedthat is, the chromosomal location is known but the gene has not been identified (Figure 1).

Research-based or commercially available testing has its pluses and minuses. Typically, research-based testing can be at least partially funded by grants, resulting in lower patient cost. However, not all patients are candidates for grant-funded genetic testing options and results typically take much longer to receive.

Commercial l

Gene Therapy 101 Gene therapy involves use of a vector to carry the gene of interest into the host cell. Bare DNA, nanoparticles or viruses are examples of vectors, with viruses the most commonly used in clinical gene therapy (Figure 2). Existing techniques for viral vector delivery involve intravitreal and subretinal administration (Figure 3). Future techniques may include suprachoroidal and sub-internal limiting membrane techniques.

Once a viral vector is inside the nucleus, the host cell machinery can mediate the gene expression and translation into a protein product.

Adeno-associated virus (AAV) is particularly well suited for gene therapy because it is nonpathogenic, nonimmunogenic and episomal. That is, it does not integrate into the host DNA, but rather remains separate inside the nucleus where it is effectively expressed and translated into protein.

One limitation of AAV is its packaging size; this vector can only hold a 4.7-kb transgene. Scientists have taken advantage of the ability of AAV to encapsulate and deliver DNA into human cells by manipulating the virus genome to remove genes that cause disease and insert therapeutic ones. To create an AAV vector carrying a transgene of interest, the transgene is co-transfected with the rep (or replication) and cap (or capsid) viral DNA into a packaging cell, along with helper adenovirus required for replication.

Once the helper adenovirus is eliminated, the end product is the transgene of interest carried inside a viral capsid. AAV capsids can be modified (by introducing point mutations in the viral capsid genome) to make them more efficient at transduction.

The SAR422459 trial4 (previously known as StarGen) and UshStat trials8 are using lentivirus as the vector. UshStat is a gene therapy developed by Sanofi for Usher Syndrome type 1B (USHB1).9

Lentivirus is a subclass of retrovirus in which viral genome in the form of RNA is reverse-transcribed when the virus enters the cell to produce DNA. Lentivirus is believed to integrate into the genome and can infect both dividing and non-dividing cells. Lentivirus has a much larger carrying capacity than AAV (packaging capacity of 8 to 10 kb), making it the ideal vector for treating retinal genetic disorders with larger affected genes (such as the ABCA4 gene implicated in Stargardt disease).

Replacement gene therapy is the most common clinically relevant gene therapy. It involves replacing a protein that a cell no longer expresses due to a genetic mutation in an autosomal recessive condition. This article will focus on replacement gene therapy.

Other Forms of Gene Therapy Multiple other forms of gene therapy exist. For example, a growth factor can be added in conditions where we do not know the genetic mutation or the conditions are genetically multifactorial. The Oxford Biomedica-sponsored RetinoStat trial for age-related macular degeneration involves expressing endostatin and angiostatin to provide sustained release of an anti-VEGF protein.7

Optogenetics (Box) involves genetically altering ganglion cells to become photosensitive. This would be useful in retinal degenerations in which the photoreceptors have already suffered extensive damage. For dominant conditions, we cannot replace a missing gene, so the option of suppression gene therapy arises, which involves small or short interfering RNA (siRNA).

Gene-editing techniques, such as CRISPR (clustered regularly interspaced short palindromic repeats), aim to genetically alter or modify DNA. This has been done in vitro and in mouse models, and has been used as a technique for controlling dominant/negative effect.

Surgical Considerations As we gain experience from human retinal gene therapy clinical trials, we are learning that the mode of gene therapy delivery is an important determinant of both safety and potential efficacy. The majority of retinal gene therapy trials use subretinal delivery of a viral vector to efficiently transduce photoreceptors. Preclinical animal models have reported success with subretinal delivery for transduction efficiency and rescue of the condition, so logic dictates that subretinal induction would follow in human trials.

We do not yet have a viral vector that can efficiently transduce photoreceptors via intravitreal delivery in any of the inherited retinal diseases currently in human gene therapy trials. The XLRS study utilizes an AAV vector and an intravitreal mode of delivery, but given the ubiquitous intraretinal expression of RS1 in this disease, the photoreceptors do not need to be transduced.10

The LCA2 studies offered some insight into the importance of localization of the subretinal bleb. In most of the LCA2 Phase I/II trials, subretinal blebs were placed in variable locations; some involved the fovea, others were extramacular. However, some investigators have raised concerns over the mechanical trauma that foveal detachment may induce to photoreceptors.11 Patients in gene therapy clinical trials are often young, phakic and do not have a posterior vitreous detachment, all of which are certainly considerations in surgical planning.

Instrument selection for creating the subretinal bleb is also important. Options include extendible or nonextendible cannulas, probes of 38 to 41 gauge, and manual vs. automated vector delivery. The surgeon can use the viscous fluid injector system for a foot-pedal automated injection or have a second surgical assistant manually inject the vector via a syringe and tubing system.

Another option is to create a pre-bleb with basic salt solution prior to injection of the vector to minimize the risk of losing the vector into the vitreous. Lifting the retina can take several attempts once the retinotomy is made with the cannula. Intraoperative OCT can help confirm the subretinal location of the vector.

Retinal tissue with degeneration and thinning is more prone to macular hole formation and iatrogenic retinal tears than healthy, thick retinal tissue. Typically surgeons try to not use air or gas to avoid bleb displacement. Postoperative supine positioning can maximize settlement of the bleb over the posterior pole. The timing for blebs to settle after surgery varies depending on the health of the retinal pigment epithelium and other factors.

Clinical Gene Therapy Trials Active clinical gene replacement trials are targeting Stargardt disease, Usher syndrome, RP, XLRS, choroideremia, achromatopsia and Leber congenital amaurosis 2 (LCA2) (Table 2). These trials use either AAV or lentivirus as viral vectors.

Stargardt Degeneration Trials Stargardt disease is one of the most common inherited retinal dystrophies, with a prevalence of approximately 1:8,000.3 Typical autosomal recessive Stargardt disease is associated with mutations in ABCA4 gene expressing the photoreceptor-specific ABCA4 protein, a member of the superfamily of ATP-binding cassette (ABC) transporters. Clinically, patients typically develop central visual loss as a result of progressive accumulation of lipofuscin in the RPE with the development of yellowish pisciform flecks and eventual macular atrophy.

Depending on the severity of the mutations in the ABCA4 gene, there may be a wide spectrum of phenotypes, ranging from relatively mild and late-onset localized macular disease to earlier-onset diffuse cone-rod disease. A 48-week, Phase I/IIA dose-escalation trial is investigating SAR422459, a lentiviral vector gene therapy carrying the ABCA4 gene formerly known as StarGen, for the treatment of Stargardt disease.12 Eligible patients must have two pathogenic ABCA4 gene variants confirmed by segregation analysis of parental samples.

This study is investigating vitrectomy with subretinal injection of SAR422459. The primary objective is to assess the safety and tolerability of SAR422459, with the secondary objective to evaluate biological activity. After 48 weeks, patients are encouraged to continue follow-up in a long-term safety study. At this writing, 23 patients have been enrolled, and no significant changes in best-corrected visual acuity have been reported in either the treated or untreated fellow eyes. The plan is to continue enrollment in the cohort of youngest patients with early-onset Stargardt disease and evidence of rapid progression of disease (ages 6 to 26 years; all other cohorts involve patients 18 years or older).12

Usher Syndrome Usher syndrome refers to a clinically and genetically heterogeneous group of autosomal recessive disorders which account for the most frequent cause of combined deafness and blindness in humans, with an estimated prevalence of 36:100,000.13

Usher syndrome has three clinical subtypes: USH1; USH2; and USH3. The severity and progression of hearing loss and the presence or absence of vestibular dysfunction distinguish these subtypes. USH1 is the most severe form in terms of the onset/extent of hearing loss and RP. The genetic mutation MYO7A (Usher 1B) accounts for approximately 30 to 50 percent of all USH1 cases.9

MYO7A (Myosin 7A) encodes an actin-based protein that performs critical motility functions in both the inner ear and retina. Patients with USH1B are born with profound neurosensory deafness, have vestibular dysfunction (that is, they often have a history of delay in walking), and develop early retinal degeneration in childhood.

A trial is investigating SAR421869 (UshStat), a lentiviral gene therapy administered via subretinal injection for the treatment of RP in patients with Usher syndrome type 1B (MYO7A gene defect). All patients must have two confirmed mutations in MYO7A.14 As of this writing, nine adult patients have been treated.15 A majority of these patients have shown an initial postoperative drop in BCVA and visual fields that improved to baseline within two weeks in early unpublished results. The vision was stable (in either the treated or untreated fellow eyes) after 48 weeks in a majority of patients. A separate cohort will provide the opportunity to extend the study to include pediatric patients ages 6 years and up.

X-linked Retinoschisis XLRS is an X-linked disorder that affects approximately 1:5,000 to 1:20,000 individuals.16 The disease begins early in childhood, and affected boys typically have BCVA of 20/60 to 20/120 at initial diagnosis. Severe complications such as vitreous hemorrhage or retinal detachment occur in up to 40 percent of patients, especially in older individuals.16

The causative gene was identified in 1997 and named retinoschisin 1 (RS1).15 The gene codes for the retinoschisin protein, which normally provides lateral adhesion that holds retinal cells together. RS1 gene mutations alter the protein to disrupt cell structure. Without normal retinoschisin, the layers of the retina split. Affected individuals typically have early central vision loss and can develop peripheral schisis, exudate or retinal detachment. This damage often forms a spoke-wheel pattern in the macula as seen on clinical examination and OCT.

Research has shown that intravitreal AAV delivery can rescue the condition in mice, likely due to the diffuse expression of RS1 throughout the retina as well as the relatively increased retinal permeability that abnormal retinal morphology causes.18 This is the first replacement gene therapy trial investigating the safety and efficacy of intravitreal gene delivery for an inherited retinal dystrophy.

Ongoing are two Phase I/II studies of an intravitreal-administered AAV-RS1 vector. The National Eye Institute is evaluating three different increasing dose levels of an AAV-RS1 vector in up to 24 adult patients with VA of 20/63 or worse in one eye.19 In the second study, the biotechnology company AGTC is evaluating an AAV-RS1 vector in up to 27 patients.10 The latter study involves three initial groups of adult patients receiving increasing dose levels of the vector and will also evaluate the maximum tolerated dose level in patients 6 years and older.

Choroideremia Choroideremia is an X-linked recessive disorder of a genetic defect in RAB escort protein 1 (REP1) that causes degeneration of RPE and photoreceptors. It can lead to severe and diffuse chorioretinal degeneration. Patients experience gradual vision loss starting from the periphery and advancing toward the fovea. Multiple Phase I and II trials of the AAV.REP1 vector are ongoing at several sites.

In a Phase I/II study, two patients with advanced choroideremia who had low baseline BCVA gained 21 and 11 letters in vision, respectively, despite undergoing retinal detachment.2 Four other patients with near normal BCVA at baseline recovered to within 1 to 3 letters. Maximum sensitivity measured with dark-adapted microperimetry increased in the treated eyes.

In all patients, the increase in retinal sensitivity over six months in the treated eyes correlated with the vector dose administered per area of surviving retina.20 The early improvement observed in two of the six patients was sustained at 3.5 years after treatment despite progressive degeneration in the control eyes.21

Other trials of subretinal placement of the AAV.REP1 vector are ongoing, including a Phase I/II trial Spark Therapeutics is sponsoring.22

Achromatopsia Achromatopsia is an autosomal recessive disease that affects approximately 1:30,000 individuals and is associated with the complete loss of cone function.23 Achromatopsia is of congenital-onset and relatively stationary, with clinical findings of poor central visual acuity (usually 20/200), nystagmus, severe photophobia and complete loss of color discrimination. On electrophysiology testing, patients have nonrecordable cone-mediated responses.

The two genes most commonly associated with achromatopsia are CNGB3 and CNGA3. A Phase I/II dose-escalation study sponsored by AGTC evaluating an AAV-CNGB3 subretinal vector in patients with CNGB3 achromatopsia is ongoing at four sites in the United States.24

MERTK-RP The MERTK-associated form of autosomal recessive RP is very rare, with isolated patient populations identified in the Middle East and most recently the Faroe islands.2 A Phase I clinical trial utilizing an AAV2 vector with an RPE-specific promoter driving MERTK was recently completed in Saudi Arabia.2 Six patients were treated with subretinal injection of an AAV vector expressing MERTK, without any serious adverse events. Three of these patients displayed measurably improved visual acuity in the treated eye following surgery, although two of them had lost that improvement by two years.

LCA2 (RPE65-associated LCA) Because of its early onset and the availability of multiple animal models, innovators have focused a tremendous amount of attention on developing a gene-based therapy for RPE65-associated LCA, or LCA2 (prevalence 1:100,000).25 Multiple Phase I/II trials for RPE65-associated LCA have been either completed or are ongoing. These trials have suggested that improvement in retinal function, as

Despite these promising results of early visual gain, reports of visual acuity loss after treatment30 and continued photoreceptor degeneration at three years have emerged.31 Although these findings of progressive degeneration are somewhat discouraging, they do provide context for an educated and realistic interpretation of findings from these exciting Phase I/II trials as we move into treatment trials for other inherited retinal disorders.

The recently completed Phase III trial of SPK-RPE65 for treatment of RPE65-associated LCA reported that treated patients displayed improved sensitivity to dim light compared to controls (P<0.001) with no significant difference in visual acuity between the two groups.27 The 31 subjects were randomized 2:1 to an early treatment arm or a one-year treatment- delayed arm.27 Both eyes received a subretinal injection of 300 L of AAV, with the second eye treated within 18 days of the first.

The primary endpoint for this trial was mobility testing in an obstacle course with one eye patched. Treated patients scored better than controls (P<0.001), meaning that these treated patients could navigate the maze in lower-light conditions. The secondary outcome was full-field light sensitivity, which was done with both eyes open.

The trial reported no serious adverse events. All ocular events were mild. They included transient elevated intraocular pressure in four subjects, cataract formation in three, retinal tears that resolved after laser in two subjects and transient mild eye inflammation in two subjects. Spark Therapeutics has filed a Food and Drug Administration application for approval of this therapy. That could pave the way for future retinal gene therapies and certainly raise awareness of the need for accurate clinical diagnosis of retinal dystrophies and genetic confirmation of disease.27

Optimizing Vectors, Delivery Groups are also continuing to work on optimizing vectors for potency to possibly increase the therapeutic effect of gene transfer.32 Some investigators believe that earlier treatment in these progressive retinal dystrophies may offer the best chance of sustained visual recovery. Phase I/II trials have shown no direct correlation between patient age and treatment response, although they did report less dramatic improvements in retinal sensitivity in younger patients who had the greatest preservation of retinal structure.30

The mechanism for surgically delivering gene therapy to the retina is under much discussion because of the potential trauma subretinal injections may cause, particularly those involving the macula. Some of the phase I/II LCA trials suggested that patients lost visual acuity and retinal thickness after subfoveal injections, potentially due to mechanical trauma to the fovea from inducing a retinal detachment.11

Keep in mind that these trials involving subretinal injections are targeting only cells in the region of the surgically induced subretinal bleb, which make up a small percentage of the entire retina (gene therapy clinical trial bleb sizes range from 150 m to 450 m).

Zones of retina treated, as well as viral vector dosing, play important roles in the long-term restoration of function. We may yet learn that concomitant neuro-protectant treatments are also going to be useful, if not mandatory, in treating inherited retinal degenerative disease.

Future Trials AGTC expects to begin enrollment soon of a Phase I/II dose-escalation study for treatment of CNGA3-achromatopsia with AAV (using the same AAV vector and promoter as used in the CNGB3 study).33 AGTC is also developing an AAV-RPGR vector for X-linked RP for which it plans to submit an investigational new drug application to the FDA in 2017.34

Although most phase I/II trials for LCA2 show initial improvement in retinal sensitivity in patients after gene therapy, these improvements were modest even in participants with relatively mild retinal degeneration and failed to protect against ongoing degeneration,30 suggesting that we still have much room for improvement in the field.

Research into new optimized vectors for therapeutic efficacy and longevity needs to continue. From a clinical standpoint, we still do not fully understand which patients may benefit most from therapy and how therapeutic intervention will alter the natural history of retinal degeneration and progression of vision loss. From a surgical standpoint, more attention is being placed on optimal delivery to minimize mechanical trauma and perioperative inflammation.

Retinal gene therapy has advanced eons in the past 10 years. We will likely see FDA approval in the near future for the first viral-based retinal gene therapy for LCA2. With innovations like optogenetics we can imagine a future where multiple different diseases can be treated with a larger window of opportunity for therapeutic effect. While exciting to the clinical community, these advances will be even more attractive to our patients who, until very recently, have been told at yearly follow-ups, There is nothing that can be done. We are finally at a point where we can offer realistic hope. RS

REFERENCES 1. Fahim AT, Daiger SP, Weleber RG. Nonsyndromic retinitis pigmentosa overview. In: Pagon RA, Adam MD, Ardinger, HH, et al., eds. GeneReviews [Internet]. Seattle, WA:University of Washington, Seattlel 1993-2017: https://www.ncbi.nlm.nih.gov/books/NBK1417/. Accessed February 7, 2017. 2. Ghazi NG, Abboud EB, Nowilaty SR, et al., Treatment of retinitis pigmentosa due to MERTK mutations by ocular subretinal injection of adeno-associated virus gene vector: results of a phase I trial. Hum Gene. 2016;135:327-343. 3. Walia S, Fishman GA. Natural history of phenotypic changes in Stargardt macular dystrophy. Ophthalmic Genet. 2009;30: 63-68. 4. Sanofi. A study to determine the long-term safety, tolerability and biological activity of SAR422459 ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed January 30, 2017. Available at: https://clinicaltrials.gov/ct2/show/NCT01736592?term=NCT01736592&rank=1 NLM Identifier: NCT01736592. 5. Astellas Institute for Regenerative Medicine. Safety and tolerability of sub-retinal transplantation of human embryonic stem cell derived retinal pigmented epithelial (hESC-RPE) cells in patients with Stargardts macular dystrophy (SMD). In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed January 30, 2017. Available at: https://clinicaltrials.gov/ct2/show/NCT01469832?term=NCT01469832&rank=1 Identifier: NCT01469832. 6. Alkeus Pharmaceuticals. Phase 2 tolerability and effects of ALK-001 on Stargardt Disease. In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed January 30, 2017. Available at: https://clinicaltrials.gov/ct2/show/NCT02402660?term=NCT02402660&rank=1 NLM Identifier: NCT02402660. 7. Oxford BioMedica. Phase I dose escalation safety study of RetinoStat in advanced age-related macular degeneration (AMD). In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed January 30, 2017. Available at: https://clinicaltrials.gov/ct2/results?term=NCT01301443&Search=Search. NLM Identifier: NCT01301443. 8. Sanofi. A study to determine the long-term safety, tolerability and biological activity of UshStat in patients with Usher syndrome type 1B. In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed January 30, 2017. Available at: https://clinicaltrials.gov/ct2/results?term=UshStat&Search=Search. NLM Identifier: NCT02065011. 9. Hashimoto T, Gibbs D, Lillo C, et al. Lentiviral gene replacement therapy of retinas in a mouse model for Usher syndrome type 1B. Gene Ther. 2007;14: 584-594. 10. Applied Genetics Technology Corp. Safety and efficacy of rAAV-hRS1 in patients with X-linked retinoschisis (XLRS). In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed February 7, 2017. Available at: https://www.clinicaltrials.gov/ct2/show/NCT02416622?term=agtc+rs1&rank=1. 11. Jacobson SG, Cideciyan AV, Ratnakaram R, et al. Gene therapy for leber congenital amaurosis caused by RPE65 mutations: safety and efficacy in 15 children and adults followed up to 3 years. Arch Ophthalmol. 2012;130:9-24. 12. Sanofi. Phase I/IIa study of SAR422459 in patients with Stargardts macular degeneration. In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Available at: https://clinicaltrials.gov/ct2/results?term=NCT+01367444&Search=Search. NLM Identifier: NCT 01367444. 13. Rosenberg T, Haim M, Hauch AM, Parving A. The prevalence of Usher syndrome and other retinal dystrophy-hearing impairment associations. Clin Genet. 1997;51: 314-321. 14. Sanofi. Study of UshStat in patients with retinitis pigmentosa associated with Usher syndrome type 1B. In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Available at: https://clinicaltrials.gov/ct2/results?term=NCT01505062&Search=Search. NLM Identifier: NCT01505062. 15. Email communication from R. Buggage, MD (February 2017). 16. Sieving PA, MacDonald IM, Chan S. X-linked Retinoschisis In: Pagon RA, Adam MD, Ardinger, HH, et al., eds. GeneReviews [Internet]. Seattle, WA:University of Washington, Seattlel 1993-2017: https://www.ncbi.nlm.nih.gov/books/NBK1222/. Accessed February 7, 2017. 17. Sauer CG, Gehrig A, Warneke-Wittstock R, et al. Positional cloning of the gene associated with X-linked juvenile retinoschisis. Nat Genet. 1997;17:164-170. 18. Min SH, Molday LL, Seeliger MW, et al. Prolonged recovery of retinal structure/function after gene therapy in an Rs1h-deficient mouse model of X-linked juvenile retinoschisis. Mol Ther. 2005;12:644-651. 19. National Eye Institute.; Turriff AE, Sieving PA. Study of RS1 ocular gene transfer for X-linked retinoschisis. In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed February 7, 2017. Available at: https://www.clinicaltrials.gov/ct2/show/NCT02317887?term=retinoschisis&rank=7. 20. MacLaren RE, Groppe M, Barnard AR, et al. Retinal gene therapy in patients with choroideremia: initial findings from a phase 1/2 clinical trial. Lancet, 2014. 383:1129-1137. 21. Edwards TL, Jolly JK, Groppe M, et al. Visual Acuity after retinal gene therapy for choroideremia. N Engl J Med, 2016. 374:1996-1998. 22. Spark Therapeutics. Safety and dose-escalation study of AAV2-hCHM in subjects with CHM (choroideremia gene mutations. In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed February 7, 2017 Available at: https://www.clinicaltrials.gov/ct2/show/NCT02341807?term=spark+choroideremia&rank=1. 23. Sharpe LT, Stockman A, Jagle H, Nathans J. Opsin genes, cone photopigments, color vision, and color blindness. In: Gegenfurtner K, Sharpe LT, eds. Color Vision: from Genes to Perception. Cambridge, UK: Cambridge University Press; 1999:3-52. 24. Applied Genetic Technologies Corp. Safety and efficacy trial of AAV gene therapy in patients with CNGB3 achromatopsia. In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed February 7, 2017. Available at: https://clinicaltrials.gov/ct2/show/NCT02599922?term=cngb3&rank=3. 25. Allikmets R. Leber congenital amaurosis: a genetic paradigm. Ophthalmic Genet. 2004;25:67-79. 26. Bainbridge JW, Smith AJ, Barker SS, et al. Effect of gene therapy on visual function in Lebers congenital amaurosis. N Engl J Med. 2008;358:2231-2239. 27. Maguire AM, Simonelli F, Pierce EA. Safety and efficacy of gene transfer for Lebers congenital amaurosis. N Engl J Med. 2008;358:2240-2248. 28. Cideciyan AV, Aleman TS, Boye SL, et al. Human gene therapy for RPE65 isomerase deficiency activates the retinoid cycle of vision but with slow rod kinetics. Proc Natl Acad Sci USA. 2008;105:15112-15117. 29. Cideciyan AV, Hauswirth WW, Aleman TS, et al. Human RPE65 gene therapy for Leber congenital amaurosis: persistence of early visual improvements and safety at 1 year. Hum Gene Ther. 2009;20:999-1004. 30. Bainbridge JW, Mehat MS, Sundaram V, et al. Long-term effect of gene therapy on Lebers congenital amaurosis. N Engl J Med. 2015;372:1887-1897. 31. Jacobson SG, Cideciyan AV, Roman AJ, et al. Improvement and decline in vision with gene therapy in childhood blindness. N Engl J Med. 2015;372:1920-1926. 32. Georgiadis A, Duran Y, Ribeiro J, et al. Development of an optimized AAV2/5 gene therapy vector for Leber congenital amaurosis owing to defects in RPE65. Gene Ther. 2016;23:857-862. 33. Applied Genetic Technologies Corp. Safety and efficacy trial of AAV gene therapy in patients with CNGA3 achromatopsia. In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed February 7, 2017. Available at: https://www.clinicaltrials.gov/ct2/show/NCT02935517?term=cnga3&rank=2. 34. AGTC files investigational new drug application for the treatment of achromatopsia caused by mutations in the CNGA3 gene. [press release] Gainesville, FL, and Cambridge, MA. Applied Genetic Technologies Corp. October 19, 2016. 35. RetroSense Therapeutics. RST-001 Phase I/II trial for retinitis pigmentosa. In: ClinicalTrials.gov. Bethesda, MD: National Library of Medicine. Accessed February 7, 2017. Available at: https://www.clinicaltrials.gov/ct2/show/NCT02556736?term=retrosense&rank=1.

See the rest here:
Gene Therapy: The New Frontier for Inherited Retinal Disease

Nutrition : The Addiction Recovery Guide

In dealing with the chemical imbalances that are both a cause of substance abuse and a result of long-term substance addiction, nutritional therapy can be helpful in several ways.

Food and Addiction

Radiant Recovery (radiantrecovery.com/resourcecenter/alcdrug.html) This site was developed by Kathleen DesMaisons, PhD., the author of Potatoes not Prozac which charts the relationship between sugar addiction and alcoholism. It includes resources related to substance addiction plus an online program to help people deal with sugar addiction. There is also an online forum and a series of Internet-based two-week classes for $24.95 each which deal with various aspects of addiction including brain chemistry. Out-patient treatment based on this approach is also available in Albuquerque (call 505 345-3737 for further information).

Intravenous Amino Acids

Agora Regeneration Clinics (agoraforlife.net) Based in Vancouver, BC, this outpatient program focuses on biochemical detoxification of the body and brain. It includes Amino Acid IV Therapy, a Naturopathic physical work-up, infrared sauna detoxification, auricular acupuncture, massage therapy and the Agora For Life Program which deals with the emotional and mental aspects of addiction. The 10 day intensive program costs $9,800 (plus GST) and the 15 day intensive costs $13,500 (plus GST). Both program fees include the Agora for Life Aftercare program.

Nutritional Supplements, Vitamins and Herbs

Nutritional supplements such as herbs, amino acids (see chart below), vitamins and other nutrients restore the proper biochemical balance in the brain.

Supplements, vitamins and herbs can be purchased online through various websites such as Vitacost.com, iHerb.com, Swansonvitamins.com, Luckyvitamin.com, evitamins.com and Vitamin Shoppe.

Books on Nutrition

End Your Addiction Now: The Proven Nutritional Supplement Program That Can Set You Free by Charles Gant and Greg Lewis, published by Square One (2009) can be purchased at amazon.com. Nutritional supplements such as herbs, amino acids (see chart below), vitamins and other nutrients restore the proper biochemical balance in the brain. These supplements are specified, according to your addiction, in an excellent book written by Charles Gant, MD, PhD, who has helped over 7,500 patients with his innovative nutritional program designed to help people addicted to drugs, alcohol, nicotine, or pain medication.

In addition, eliminating certain substances such as sugars and simple starches and increasing protein intake can help to rebalance brain chemistry. Good nutrition can also help heal damage to the body caused by the depletion of nutrients common in substance abuse.

Natural Highs by Hyla Cass M.D. and Patrick Holford published by Avery Books/Penguin Putnam in 2002 can be purchased at amazon.com. This book usefully reviews and gives specific doses of herbs, amino acids, nutritional supplements and foods that help a person have a sharp mind and feel happy, calm, energetic and connected to people. The main tips from this book including specific doses of herbs and amino acids can be found at cassmd.com/books/naturalhighs/.

Another helpful book which has benefited many people with its nutritional advice is Seven Weeks To Sobriety: The Proven Program to Fight Alcoholism Through Nutrition by Joan Mathew Larson Ph.D. This book can also be purchased at amazon.com.

To Find a Nutritionist:

Academy of Nutrition and Dietetics (eatright.org) Some people may decide to work directly with a nutritionist. The Academy of Nutrition and Dietetics web site can help you locate a nutritionist. This is the nation's largest organization of food and nutrition professionals. Click on the red Find an Expert button at the top of the page to locate dietitians in the United States by zip code. Descriptions include areas of practice or specialty for each dietitian.

AMINO ACID NUTRITION THERAPY

Another important area of the use of nutrition in recovery and relapse prevention is the addition of appropriate amino acids that serve as the building blocks for powerful chemicals in the brain called neurotransmitters. These neurotransmitters, including epinephrine and norepinephrine, GABA, serotonin and dopamine, are closely tied to addiction behavior. With the use of various amino acids, brain chemistry can be changed to help normalize and restore deficiencies in the neurotransmitters that spur cravings that can lead to addiction andrelapse.

This chart was originally published in the following article. Blum K, Ross J, Reuben C, Gastelu D, Miller DK. "Nutritional Gene Therapy: Natural Healing in Recovery. Counselor Magazine, January/February, 2001

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Nutrition : The Addiction Recovery Guide

F.D.A. Speeds Review of Gene Therapies, Vowing to Target …

So far, the drug agency has approved only two products that qualify as gene therapy Kymriah, from Novartis, and Yescarta, made by Kite Pharma. Both treatments involve genetically altering a patients own immune cells to fight leukemia or lymphoma. An advisory panel to the F.D.A. recommended approval for a third product, made by Spark Therapeutics, to correct a gene defect that causes a blinding hereditary eye disease. All three agency actions occurred this year.

Such treatments are extremely expensive, costing hundreds of thousands of dollars.

The prospect of faster approvals disturbs Michael Carome, director of Public Citizens health research group, an advocacy organization. Dr. Carome believes that the industry, still quite young, needs careful F.D.A. oversight.

I think there is excessive hype, Dr. Carome said. We are talking about rushing to market very complex biologics products where we are still in the infancy of this field.

The agencys announcements included two final guidelines and two drafts that will be open for public comment. They are designed to help developers sort out whether they need to submit a licensing application to the F.D.A. to get approval for their treatments or fall into a lower risk category, which does not need premarket approval.

One of the proposals would be a boon to small clinics and independent researchers. It would permit them to apply as a group and to pool data. If approved, each would end up with a license for biologics, a category that refers to treatments like cell, tissue and gene therapies that come from natural sources rather than being chemically synthesized.

The guidelines also detail steps to rein in the hundreds of stem-cell clinics that treat ailments by liposuctioning belly fat from patients and processing it to extract so-called stem cells, which are then injected back into the patients. These largely unregulated procedures have been offered for arthritic knees, back pain, heart disease and other problems.

Several patients have been blinded after fat-derived cells were injected into their eyes.

Practitioners who perform these procedures have argued that they do not come under the agencys jurisdiction. But the new guidance suggested that at least some of the fat-derived injections will be more tightly controlled by the F.D.A. The document stated that if the fat tissue is processed specifically to isolate stem cells as the stem-cell clinics do then the procedures must meet F.D.A. safety requirements.

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F.D.A. Speeds Review of Gene Therapies, Vowing to Target ...

Cell and Gene Therapy Center – IQVIA

Developing advanced therapies involves making critical Chemistry, Manufacturing and Controls (CMC) decisions and managing complex clinical studies while navigating through an evolving regulatory and reimbursement environment.

The Cell and Gene Therapy team from IQVIA can provide the data, expertise, and services that help you transcend the challenges faced in the development and commercialization of cell and gene therapies.

Strategic and operational services customized to your therapy:

Our dedicated team of experts combine cell and gene therapy expertise with the capabilities of the IQVIA COREto address your needs throughout the development pathway.

We have a proven track record supporting a range of clients, from academics to emerging biotech and established pharmaceutical companies, in:

Comprehensive network of partners to respond to your needs:

The Cell and Gene Therapy group works in close collaboration with our alliance partners to address the unique challenges in cell and gene therapy manufacturing and nonclinical research.

Through our partnership with the California Institute for Regenerative Medicine (CIRM), we have access to the Alpha Stem Cell Clinics network that provides experienced sites for your stem-cell based therapies for more reliable and rapid study startup.

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Cell and Gene Therapy Center - IQVIA