FDA Okays First Generic Naloxone Nasal Spray for Opioid Overdose

The US Food and Drug Administration (FDA) has granted final approval for the first generic naloxone hydrochloride nasal spray (Narcan, Teva Pharmaceuticals) that can stop or reverse the effects of an opioid overdose.

The FDA tentatively approved this generic drug product in June 2018.

Teva’s generic naloxone nasal spray is the first for use in the community setting by individuals who have no medical training. The name-brand spray was approved in 2015.

Generic versions of injectable naloxone products that are used strictly in medical settings are already available.

Naloxone nasal spray does not require assembly and delivers a consistent, measured dose when used as directed. It can be used for both adults and children, the FDA said. The drug is sprayed into one nostril while the patient is lying on his or her back. Administration can be repeated if necessary.

The FDA is also planning steps to prioritize the review of additional generic drug applications for products intended to treat opioid overdose.

“In the wake of the opioid crisis, a number of efforts are underway to make this emergency overdose reversal treatment more readily available and more accessible. In addition to this approval of the first generic naloxone nasal spray, moving forward, we will prioritize our review of generic drug applications for naloxone,” Douglas Throckmorton, MD, deputy center director for regulatory programs in the FDA’s Center for Drug Evaluation and Research, said in a news release.

“The FDA has also taken the unprecedented step of helping to assist manufacturers to pursue approval of an over-the-counter naloxone product and is exploring other ways to increase the availability of naloxone products intended for use in the community, including whether naloxone should be coprescribed with all or some opioid prescriptions to reduce the risk of overdose death,” Throckmorton said.

“All together, these efforts have the potential to put a vital tool for combating opioid overdose in the hands of those who need it most — friends and families of opioid users, as well as first responders and community-based organizations,” he added.

Throckmorton noted that the agency is “committed to working with other federal, state, and local officials as well as healthcare providers, patients, and communities across the country to combat the staggering human and economic toll created by opioid abuse and addiction.”

According to federal data, close to 400,000 people died from an opioid overdose from 1999 to 2017. On average, more than 130 Americans die every day from overdoses involving opioids, a class of drugs that includes prescription medications such as fentanyl, oxycodone, hydrocodone, and morphine, as well as illegal drugs such as heroin or drugs sold as heroin.

Last April, Surgeon General Vice Admiral Jerome Adams, MD, MPH, issued an advisory encouraging more individuals, including family, friends, and those who are personally at risk for an opioid overdose, to carry naloxone, as reported by Medscape Medical News.

https://www.medscape.com/viewarticle/912027

Dangers of Fasting and Feasting With Diabetes

‘Could I Have Averted This Disaster?’

I was a young resident in August 2009 when I saw Mr Khan (name changed to protect patient privacy) in the primary care continuity clinic. He was a 52-year-old man with type 2 diabetes. In the past year that I had known him, he had turned a new leaf, making every effort to follow dietary and physical activity recommendations, and he was always adherent to his medications. In essence, he was a “model patient.”

Akshay B. Jain, MD

His A1c at that time was 6.8% on metformin and glyburide, with excellent home glucose readings on self-monitoring. I congratulated him on his glycemic control, made no changes to his meds, and booked an appointment to follow up after 3 months.

About 15 days later, I was rotating in the emergency department when EMS brought in a patient with severe hypoglycemia who was found unconscious. Quickly scanning the EMS note, I noticed that the patient was on glyburide. “The PCP should have known better than to use a sulfonylurea in a patient at risk for such severe hypos,” I said to my attending. Imagine my consternation when I walked into the room and saw my patient, Mr Khan, lying in the bed being revived.

I later found out that Mr Khan had been fasting for Ramadan, as he did every year. That fateful afternoon, he had been fasting for about 11 hours when he started noticing symptoms of hypoglycemia. His blood sugar was 65 mg/dL, which he knew was low, but it was still another 3 hours before he could break his religious fast, at sunset.

Helpless, he lay in bed while his worried family monitored his blood sugar every 15 minutes, watching in horror as it started dipping into the 40s and he became increasingly incoherent.

They called my clinic, where the nurse–diabetes educator appropriately informed them to give Mr Khan 15 g of carbohydrate and repeat if blood sugars remained low. However, even in his state of incoherence, Mr Khan refused to take any food or beverage orally, and the family wasn’t sure if they could give him oral glucose and dishonor his fast. The last straw was when he lost consciousness, and they frantically called 911.

Standing there in the emergency department, watching Mr Khan, I couldn’t help but feel responsible in a way for what had happened. Was there anything I could have done to avert this disaster?

Fasting and feasting can present conundrums for the healthcare professional (HCP) caring for patients with diabetes. Often, the HCP may not know much about the intricacies of the specific fast that the patient plans on following and may therefore be hesitant to counsel the patient.

Patients, in turn, may fear that their HCP is not knowledgeable about their fasting and will hesitate to ask for advice, relying instead on information from friends, family, and the Internet. Worse, some may stop taking diabetes medications altogether during the time of fasting.

What Is Ramadan?

Ramadan is the ninth month of the Islamic year during which Muslims worldwide observe a strict fast between sunrise and sunset. Because the Islamic calendar is lunar, each Ramadan starts about 10 days earlier than the previous year. This means that sometimes it falls in winter months when the days—and fasts—are short. In the summer months, when there are more daylight hours, the fasts are long. This year, Ramadan will start on May 5 and continue until June 4.

Those exempt from fasting include children younger than 12 years; people who are ill; travelers; and menstruating, pregnant, or nursing women.

Healthy Muslims are obliged to abstain from all food, drink, and oral medications from dawn to sunset throughout the month. Most people eat two major meals a day—suhoor (meal before dawn) and iftar (meal after sunset). Many people also have snacks well into the night, which are often foods that are high in fat and have a high glycemic index.

There can be significant glycemic variability of blood sugars during Ramadan, with studies showing up to a 7.5-fold rise in hyperglycemia and 5-fold rise in hypoglycemia in patients with type 2 diabetes.^[1,2]

Another important consideration is that certain Muslims may also follow an up to 3-day-long Sugar Feast (Şeker Bayramı or Eid al-Fitr) at the end of the holy month, which marks the end of Ramadan. This is a celebratory period where gifts are exchanged and there is increased consumption of high-carb celebratory treats. Many Muslims will indulge in communal feasting, with family and friends eating together from a single large platter. This may cause one to lose judgement of individual portion sizes, leading to glycemic surges.

I strongly encourage patients to practice portion control, ensure hydration, restart their pre-Ramadan diabetes medication regimen, and monitor blood sugars closely during the time of the Sugar Feast.

It is important to note that Muslims who did not fast may also participate in the Sugar Feast. Therefore, the above recommendations need to be discussed even with those who say that they do not plan to fast during Ramadan.

Islamic scholars advise Muslims to ask their HCPs about their ability to fast safely during Ramadan; therefore, it is very important that all HCPs have a working knowledge of Ramadan-specific counseling of patients with diabetes.

How Do You Know Who Will Be Fasting?

Ask whether your patient plans on fasting during Ramadan. Being a non-Muslim myself, I have seen that many patients do not volunteer this information because they might feel that I wouldn’t understand their practices.

If they answer in the affirmative, it is okay to ask how many days they intend to fast. Often, this will lead them to ask me if I feel that it is safe for them to do so. Asking patients specifically about their plans during Ramadan helps to create an environment where they feel that all stakeholders are invested in ensuring healthy fasting.

Data from the CREED study^[3] indicate that about 95% of Muslims with type 2 diabetes fast for at least 15 days during Ramadan. However, only about 64% fast for all days of the month, while 31% fast for less than 30 days. Hence, there is significant risk for intraday and interday glycemic variability on the basis of whether the patient is fasting or not and what medication adjustments have been made.

Is Your Patient Too Sick to Fast?

The Koran specifically exempts the sick from the duty of fasting, especially if fasting might lead to harmful consequences for the individual. Patients with diabetes can fall under this category, and it is strongly recommended that physicians do a risk preassessment for the patient at least 3-4 weeks before the start of Ramadan.

• Very high-risk patients include those with poorly controlled type 1 diabetes, advanced renal disease, cognitive dysfunction, or recent history of hypo/hyperglycemic emergencies.
• High-risk patients include those with poorly controlled type 2 diabetes or who are on multiple daily injections of insulin.
• Moderate/low-risk patients are those with well-controlled type 2 diabetes who are on oral agents and/or basal insulin therapy.

HCPs are recommended to advise that very high-risk patients must not fast, high-risk patients should not fast, and moderate/low-risk patients can fast with medical advice.^[4,5]

Some Tips for Safely Observing Ramadan

• To fast or not to fast is ultimately the patient’s decision, and HCPs are encouraged to respect the patient’s wishes while counseling on safe practices.
• Develop an individualized plan for each patient before the start of Ramadan wherein the dose of hypoglycemia-inducing medications can be adjusted appropriately according to the current guidelines.^[4]
• Patients should be advised to check their blood sugars two to six times a day (including during the daytime, when they are not eating), depending on their risk for hypo- or hyperglycemia. Consider the use of flash or continuous glucose monitoring during the month of fasting in high-risk patients or those with significant glycemic variability.
• Patients should be clearly counseled to break the fast if their blood sugar goes below 70 mg/dL (3.9 mmol/L) or above 300 mg/dL (16.6 mmol/L); if they develop nausea, vomiting, or orthostatic dizziness; or if they notice elevated ketone levels on testing or suddenly fall ill. Consider giving high-risk patients a prescription for a glucagon emergency kit and educate family members.
• For patients who prefer not to take any insulin before breaking the fast, consider the use of ultra-short-acting mealtime insulins (eg, Fiasp), which can be taken with the first bite or within 20 minutes of initiating a meal.
• SGLT2 inhibitors: Caution patients about dehydration and signs of diabetic ketoacidosis. For those with polyuria, take at the night meal (iftar) or consider discontinuing temporarily.
• GLP-1 receptor agonists: Avoid initiating or increasing the dose within 4 weeks of onset of fasting because of the increased risk for gastrointestinal side effects.
• Aim for relaxed glycemic targets (5.5-7.5 mmol/L or 100-135 mg/dL for fasting/premeal) in patients at risk for hypoglycemia.
• There is an increased risk of stacking insulin when the duration of daytime hours is >15.
• Advise patients to consume simple carbs at the evening meal and complex carbs during the morning meal. Low-glycemic-index, high-fiber carbohydrates are preferable. Low-calorie snacks such as nuts, fruits, or vegetables can be consumed between meals at night.
• Watch for hyperglycemia during the 1- to 3-day Sugar Feast at the end of Ramadan.
• A post-Ramadan medical assessment to discuss glycemic excursions and to formulate a plan for future fasting would be ideal.

With proper medical guidance, it can be possible to achieve safe fasting practices for the appropriate patient during Ramadan.

https://www.medscape.com/viewarticle/911752#vp_1

Harpoon Therapeutics initiates HPN536 Phase 1/2a clinical trial

Harpoon Therapeutics, Inc. (NASDAQ: HARP), a clinical-stage immunotherapy company developing a novel class of T cell engagers, announced today that the first patient has been dosed with HPN536 in a Phase 1/2a clinical trial initially focused on ovarian cancer.

HPN536 targets mesothelin, which is expressed on malignant cells of ovarian and pancreatic carcinoma, mesothelioma, non-small cell lung cancer and breast cancer. HPN536 is Harpoon’s second product candidate to enter the clinic and is based on Harpoon’s proprietary Tri-specific T cell Activating Construct (TriTAC) platform that has been designed to recruit a patient’s own immune cells to destroy tumors.

https://www.marketscreener.com/HARPOON-THERAPEUTICS-INC-54488892/news/Harpoon-Therapeutics-initiates-HPN536-Phase-1-2a-clinical-trial-28451076/

Diabetes drug may reverse heart failure

Researchers at the Icahn School of Medicine at Mount Sinai have demonstrated that the recently developed antidiabetic drug empagliflozin can treat and reverse the progression of heart failure in non-diabetic animal models. Their study also shows that this drug can make the heart produce more energy and function more efficiently. The results were published in the April 23 issue of the Journal of American College of Cardiology.

“This drug could be a promising treatment for heart failure in both non-diabetic and diabetic patients,” said lead author Juan Badimon, MD, Professor of Cardiology and Director of the Atherothrombosis Research Unit at the Cardiovascular Institute at the Icahn School of Medicine at Mount Sinai. “Our research can lead to a potential application in humans, save lives, and improve quality of life.”

Empagliflozin was approved by the U.S. Food and Drug Administration in 2014. It limits renal sugar resorption and is the first drug in the history of type 2 diabetes proven to prolong survival. While diabetes patients are typically at higher risk of heart failure, past studies have suggested that those who take empagliflozin don’t commonly develop heart failure. Those observations led a team of researchers to question if the drug contains a mechanism, independent of anti-diabetic activity that is linked to heart failure prevention, and whether it could have the same impact on non-diabetics.

Investigators from the Atherothrombosis Research Unit tested the hypothesis by inducing heart failure in 14 non-diabetic pigs. For two months, they treated half of the animals with empagliflozin and the other group with a placebo. The team evaluated the pigs with cardiac magnetic resonance, 3D-echocardiography, and invasive catheterization at three different points in the study (before inducing, one day after inducing, and at the two-month mark). At two months, all animals in the group treated with empagliflozin experienced improved heart function. Specifically, those pigs had less water accumulation in the lungs (less pulmonary congestion, which is responsible for causing shortness of breath) and lower levels of biomarkers of heart failure. Importantly, the left ventricles had stronger contractions (enhanced systolic function), got smaller (less dilated), and were less thick (less hypertrophy), and the heart was a normal shape (less architectural remodeling).

The researchers also found that the drug addressed heart failure by improving cardiac metabolism. The hearts of pigs on the medication were consuming more fatty acids and ketone bodies (three related compounds — acetone, acetoacetic acid, and beta-hydroxybutyric acid — produced during the metabolism of fats) and less glucose, as contrasted with heart failure patients (diabetic and non-diabetic), whose hearts consume more glucose and almost no fatty acids and produces less energy. This boost in metabolism helped the hearts produce more energy and function more strongly and efficiently.

“This study confirmed our hypothesis that empagliflozin is an incredibly effective treatment for heart failure and not only an antidiabetic drug. Moreover, this study demonstrated that empagliflozin is useful for heart failure independently of a patient’s diabetic status. Importantly, empagliflozin switches cardiac metabolism toward fatty acid and ketone body consumption, thus allowing the production of more energy in the heart,” explained co-lead author Carlos Santos-Gallego, MD, postdoctoral fellow at the Icahn School of Medicine at Mount Sinai. “Empagliflozin may be a potentially effective treatment for heart failure patients. This is extremely important because heart failure is a disease with a mortality above 50 percent at 5 years. This study offers a new therapeutic strategy in heart failure, something badly needed given that there have not been new effective drugs for heart failure since the 1990s.”

The authors are currently studying whether empagliflozin is an effective heart failure treatment in non-diabetic human patients in the EMPATROPISM clinical trial.

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Story Source:

Materials provided by The Mount Sinai Hospital / Mount Sinai School of Medicine. Note: Content may be edited for style and length.

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Journal Reference:

1. Carlos G. Santos-Gallego, Juan Antonio Requena-Ibanez, Rodolfo San Antonio, Kiyotake Ishikawa, Shin Watanabe, Belen Picatoste, Eduardo Flores, Alvaro Garcia-Ropero, Javier Sanz, Roger J. Hajjar, Valentin Fuster, Juan J. Badimon. Empagliflozin Ameliorates Adverse Left Ventricular Remodeling in Nondiabetic Heart Failure by Enhancing Myocardial Energetics. Journal of the American College of Cardiology, 2019; 73 (15): 1931 DOI: 10.1016/j.jacc.2019.01.056

https://www.sciencedaily.com/releases/2019/04/190418135039.htm

Experimental antiplatelet compound for acute stroke shows promise

An experimental antiplatelet compound inhibited clot formation without increasing bleeding, a common and potentially dangerous side effect of current anticlotting therapies, according to new phase I research in Arteriosclerosis, Thrombosis and Vascular Biology, an American Heart Association journal.

The results of the industry-sponsored trial are based on a first-in-human study of the new compound called ACT017. The findings suggest that the drug may provide an effective and safer alternative to current antiplatelet therapies used in stroke patients, which can also increase the risk for dangerous bleeding in the brain.

“There is a clear need for a novel antiplatelet agent that resolves platelet aggregation and clot formation without raising the risk for bleeding. Such a therapy would considerably improve and expand our current therapeutic arsenal for the treatment of acute stroke,” said Martine Jandrot-Perrus, M.D., Ph.D., study senior author and scientist at France’s National Institute of Health and Medical Research (INSERM) and a consultant for Acticor-Biotech, the company that developed the compound and funded the trial.

The drug is an antibody-based compound that inhibits blood platelet aggregation (or clumping) and clot formation by precisely-targeting a protein called platelet glycoprotein VI (GPVI) found in platelets. This protein is critical for clot formation — a process marked by the clumping of platelets — but it does not play a role in regulating bleeding. This feature renders the GPVI protein an ideal target for a drug that inhibits the clumping of platelets but does so without increasing the risk for bleeding.

The trial involved 36 healthy volunteers (23 women and 13 men), ages 22 to 65, divided into six groups. In each group, six participants received intravenous infusions over six hours with various doses of the drug (ranging from 62.5 milligrams (mg) to 2,000 mg).

The drug was well-tolerated at all doses, without serious side effects. Notably, the compound did not appreciably prolong bleeding time, a marker indicating increased risk for dangerous bleeds. The study also showed that the extent and duration of the therapeutic effect was dose-dependent, reaching maximum effectiveness and duration at 2,000 mg. The most common side effects were mild to moderate headache and head discomfort, which resolved during the study.

“Our results are quite encouraging because they show the candidate compound is well-tolerated at doses even twice as high as the ones targeted for a future treatment and without any signs of bleeding,” Jandrot-Perrus said. “Another encouraging finding is the fact that the drug’s action on platelets is rapid, specific and largely reversible within 24 hours.”

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Story Source:

Materials provided by American Heart Association. Note: Content may be edited for style and length.

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Journal Reference:

1. Christine Voors-Pette, Kristell Lebozec, Peter Dogterom, Laurie Jullien, Philippe Billiald, Pauline Ferlan, Lionel Renaud, Olivier Favre-Bulle, Gilles Avenard, Matthias Machacek, Yannick Plétan, Martine Jandrot-Perrus. Safety and Tolerability, Pharmacokinetics, and Pharmacodynamics of ACT017, an Antiplatelet GPVI (Glycoprotein VI) Fab. Arteriosclerosis, Thrombosis, and Vascular Biology, 2019; DOI: 10.1161/ATVBAHA.118.312314

https://www.sciencedaily.com/releases/2019/04/190418080749.htm

$100M for Talaris Gives Surgeon a Shot to Reinvent Organ Transplants

When Novartis dissolved its gene and cell therapy unit a few years ago, a bunch of projects the Swiss pharma giant had incubated were tossed aside. One of them was the work of surgeon Suzanne Ildstad, who has spent decades trying to develop a new way to improve the health outcomes of patients who need organ transplants.

That work has just been salvaged. If it plays out as Ildstad hopes, her company might not only help transform treatment for kidney failure patients—but possibly, for people suffering from other illnesses, such as autoimmune disorders.

Talaris Therapeutics, a Louisville, KY, startup founded by Ildstad (pictured) in 2002 and long known as Regenerex, has secured a $100 million Series A investment led by Blackstone Life Sciences, the biopharma investing arm of private equity firm Blackstone Group. The cash breathes new life into an experimental cell therapy known as FCR001, a one-time treatment meant to make it possible for patients who need a kidney transplant to get one from any donor—without the need for a life-long regimen of immunosuppressive drugs afterwards to prevent rejection of the outsider’s organ. There may be a significant bonus effect—the treatment might also block the continuing threat from underlying autoimmune diseases that, in some patients, caused their own kidneys to fail in the first place.

Ildstad has already tested the technique in humans and seen some promising results. But the work had stalled amidst the cell therapy unit’s revamp at Novartis, which licensed the technology from Regenerex in 2013. With the new cash, Talaris can now fund a Phase 3 study that should start by the end of the year, says CEO Scott Requadt, a former Clarus Ventures managing director and, most recently, a Blackstone venture partner.

There are more than 113,000 people currently on the waiting list for organ transplants in the US alone, and 84 percent of them (94,973) need a donor kidney because one of their kidneys has failed, according to the Organ Procurement & Transplantation Network. The nonprofit group Donate Life America estimates that patients have to wait an average of three to five years for a kidney from a deceased donor.

The wait is shorter—a year or less—if a workable living donor is found, and volunteers. But securing the right organ is still very difficult. Patients have to be “matched” with a donor, a complex process that involves a variety of factors. One of them is finding compatibility between both parties’ immune systems, a test known as “HLA (human leukocytic antigen) typing.” The more mismatched patients are—and a perfect match is rare—the more likely the body will see the donated organ as a threat, and try to destroy it—a condition called graft versus host disease. This threat of rejection is why many transplant patients have to take immunosuppressive drugs for life.

Those drugs come with a cost, something Ildstad—a longtime transplant surgeon, director of the Institute of Cellular Therapeutics, and a professor of surgery at the University of Louisville—has seen first-hand. Suppressing a patient’s immune system with drugs can lead to heart problems or malignancies, and boost the risk of dangerous infections. Heart disease was the leading cause of death among US kidney transplant recipients between 1996 and 2014, according to a paper published last year in the American Journal of Nephrology. “Transplants are wonderful and life enhancing, but the immunosuppressive drugs really take their toll,” Ildstad says in an interview.

Scientists have spent decades trying to find ways to get our bodies to tolerate implanted donor organs—to accept that two kinds of genetically different tissues, from donor and recipient, are inhabiting the same body, a condition called chimerism.

Agnieszka Czechowicz, an assistant professor of pediatrics at Stanford University’s Division of Stem Cell Transplantation and Regenerative Medicine, who isn’t associated with Talaris, notes that the field has made strides. “Various [academic] groups,” she says, have shown that tolerance to transplanted solid organs is possible through cell therapy procedures and other methods. This 2017 paper in the Journal of Organ Transplantation, for instance, highlights some of those efforts at Stanford, Northwestern University, Massachusetts General Hospital, and elsewhere.

Such a therapy, if shown to be safe and effective, “would be a game changing thing for patients,” she says. But it’s been tough to scale that work up and test it in studies large enough to prove their worth.

“Now these efforts are trying to get more rigorous,” Czechowicz says.

Ildstad’s FCR001 is among those efforts, and it’s been in development since she founded her company in 2002.

In her treatment approach, patients not only receive a donor’s kidney, but they also receive an infusion of the same donor’s stem cells and other cells, which in Talaris studies have showed signs of inducing the patient’s own immune system to stand down instead of attacking the engrafted organ. The donor’s blood-forming cells migrate to the patient’s bone marrow, where they make cells that mix in with the patient’s own blood cells.

To design her treatment, Ildstad focused on what are known as “facilitating cells,” which help shepherd donor stem cells to the patient’s bone marrow and stay there. She found that these facilitating cells help promote immune tolerance and thus, if harnessed, might reduce the risk that the patient’s body rejects the new organ.

The procedure that her company came up with is this: Collect stem cells and facilitating cells from the blood of a living kidney donor via an outpatient procedure done a few weeks before a kidney transplant. Combine them through a manufacturing process that “strips out” potentially damaging components, then freeze the sample and ship it back to the treating physician, Ildstad says. A day after the kidney transplant, give the patient a low-dose chemotherapy step known as “nonmyeloablative conditioning” that prepares the patient’s bone marrow to get the donor cells without destroying the host’s own bone marrow cells. The new cells are then infused into the patient, where they head to the bone marrow to start making white and red blood cells containing the donor’s genes.

If all goes well, the body will view those newly made cells as its own instead of as foreign invaders, and likewise tolerate the donated organ, allowing a patient to be weaned off drugs that would otherwise be needed to keep the patient’s immune system in check. Ildstad believes this protective effect occurs because the facilitating cells don’t just chaperone donor stem cells to the host’s bone marrow, but also switch on certain biological “processes,’’ maybe that “train both immune systems” to tolerate the donated kidney. She acknowledges, though, that the mechanism behind FCR001 isn’t fully understood.  “Immunology is a very complicated field,” she says.

Ildstad spent years trying to advance this work at Regenerex, raising “substantial” funding (she wouldn’t specify how much), not from venture capital firm investments, but grants from the National Institutes of Health and the US Department of Defense. That gave her enough backing to start a Phase 2 study in 2009 to test the procedure in kidney transplant patients.

In 2012, she published results in Science Translational Medicine showing that five of the first eight patients had been weaned off immunosuppressive drugs. The data intrigued Novartis, and the partnership that resulted helped Regenerex immensely, though it was short-lived. The Swiss firm, in 2016, chose to end all cell and gene therapy research not associated with oncology. But Novartis helped build up Regenerex’s manufacturing capabilities and complete the Phase 2 study. That manufacturing site is up and running in Louisville, ready for the next test, Requadt says.

By 2016, seven years after the study began, 37 patients had been treated with FCR001. Regenerex found that 26 of them—many of whom were not perfectly matched to their donors—were surviving without immunosuppressive drugs. Three years later, those numbers have stayed the same. As of today, the patients have been tracked for a median period of five years, and in some cases, as long as 10. The lengthy follow-up is key: As with any gene or cell therapy, a durable effect is critical for FCR001 to prove its worth.

There have been two cases of graft versus host disease in the FCR001 trial; one patient died as a result. Still, without divulging specifics, Requadt says the company has found common characteristics in those two cases that made them more likely to develop the disease; those types of donors and patients will be excluded from the Phase 3 study, he says.

Taken together, the data hooked Requadt, a longtime biotech investor, spurring him to bring in Blackstone and ultimately lead the company, now known as Talaris, which has opened a Boston office. He’s envisioning the technique being used not just for kidney transplants, but also for other organ transplants and even as a possible one-time, long-lasting treatment for autoimmune diseases (he wouldn’t say which ones, though Ildstad, at an investor meeting last year, mentioned scleroderma). Other Phase 2 studies could start this year. “I thought this was such a compelling story that I wanted to become a part of it,” he says.

There are several questions ahead for Talaris. Among them: Will the new cells cause unintended problems, asks Czechowicz? Will the chemotherapy step lead to too much additional risk? Can Talaris’s new clinical trial reproduce what the company has seen in the Phase 2 trial? And if so, how broadly effective will FCR001 be?

“It’s still early to know how this will pan out for many patients,” Czechowicz says. “But their data is promising and reassuring and really addresses a critical need.”

At minimum, however, Ildstad now has a chance to see her work through. She laughs when asked about waiting so long to get that shot. “Everybody is really excited,” she says. “Word is spreading among the patients. We’ve got people on a list ready to enroll.”

https://xconomy.com/boston/2019/04/18/100m-for-talaris-gives-surgeon-a-shot-to-reinvent-organ-transplants/?single_page=true

Intuitive Surgical price target lowered to $610 from $625 at Piper Jaffray

Piper Jaffray analyst JP Kim lowered his price on Intuitive Surgical to $610 after its Q1 earnings miss driven by a “higher mix of operating leases” and R&D costs. The analyst is keeping his Overweight rating however, saying that despite the headline miss, the fundamental growth drivers of the business are still “quite strong”. Kim cites the company’s procedure growth of 18% and install base growth of 13% in the quarter, adding that Q1 contributions from Intuitive Surgical’s long-term growth drivers, such as expansion to China and Japan as well as its Ion product, were muted.

https://thefly.com/landingPageNews.php?id=2894842